Refine
Year of publication
Document Type
- Article (757)
- Doctoral Thesis (282)
- Preprint (32)
- Conference Proceeding (11)
- Part of a Book (2)
- Other (1)
- Working Paper (1)
Language
- English (1086) (remove)
Has Fulltext
- yes (1086)
Is part of the Bibliography
- no (1086)
Keywords
- crystal structure (37)
- hydrogen bonding (11)
- RNA (10)
- NMR spectroscopy (8)
- structural biology (7)
- Biochemistry (6)
- Membranproteine (6)
- NMR (6)
- Optogenetics (6)
- X-ray crystallography (6)
Institute
- Biochemie und Chemie (1086) (remove)
The title compound, C14H20O3, is a synthetic analogue with a long aliphatic side chain of the important food additive and flavoring agent, vanillin. There are two independent molecules in the asymmetric unit, each having an essentially planar conformation (r.m.s. deviations of 0.023 and 0.051Å for all non-H atoms of the two molecules in the asymmetric unit). Key indicators: single-crystal X-ray study; T = 173 K; mean σ(C–C) = 0.002 A°; R factor = 0.049; wR factor = 0.144; data-to-parameter ratio = 15.9.
The title compound, C20H22O2, crystallizes with two independent molecules in the asymmetric unit. In each molecule, all the non-H atoms lie in a common plane (r.m.s. deviations of 0.098 and 0.079 Å). There is a [pi]-[pi] stacking interaction in the crystal structure. The central aromatic rings of the two molecules, which are stacked head-to-tail one above the other, are separated by centroid-to-centroid distances of 3.872 (13) and 3.999 (10) Å. Key indicators: single-crystal X-ray study; T = 173 K; mean σ(C–C) = 0.003 A° ; R factor = 0.044; wR factor = 0.101; data-to-parameter ratio = 14.6.
In the title compound, C11H14O4, an intermediate for the synthesis of a new kind of estrogen receptor modulator, all non-H atoms lie on a common plane (r.m.s. deviation = 0.0472 Å). All C-C bonds in the side chain are in a trans conformation, and the hydroxyl group is also trans to the methylene chain. In the crystal structure, molecules form centrosymmetric dimers showing a head-to-head arrangement which is stabilized by O-H...O hydrogen bonds. A weak C-H...O contact is also present.
9,9-Dimethyl-9-silafluorene
(2009)
The title compound, C14H14Si, crystallizes with two almost identical molecules (r.m.s. deviation = 0.080 Å for all non-H atoms) in the asymmetric unit. All atoms of the silafluorene moiety lie in a common plane (r.m.s. deviations = 0.049 and 0.035 Å for the two molecules in the asymmetric unit). The Si-Cmethyl bonds are significantly shorter [1.865 (4)-1.868 (4) Å] than the Si-Caromatic bonds [1.882 (3)-1.892 (3) Å]. Owing to strain in the five-membered ring, the endocyclic C-Si-C angles are reduced to 91.05 (14) and 91.21 (14)°. Key indicators: single-crystal X-ray study; T = 173 K; mean σ(C–C) = 0.005 A°; R factor = 0.061; wR factor = 0.157; data-to-parameter ratio = 16.3.
The complete molecule of the title compound, C18H24N2O2, is generated by a crystallographic inversion centre. The torsion angles in the hexamethylene chain are consistent with an antiperiplanar conformation, whereas the conformation of the O—CH2—CH2—CH2 unit is gauche. The three-dimensional crystal packing is stabilized by N—H⋯O and N—H⋯N hydrogen bonding.
The Mg centre in the title compound, [MgBr2(C2H7N)3], is pentacoordinated in a trigonal-bipyramidal mode with the two Br atoms in axial positions and the N atoms of the dimethylamine ligands in equatorial positions. The MgII centre is located on a crystallographic twofold rotation axis. The crystal structure is stabilized by N—H⋯Br hydrogen bonds. The N atom and H atoms of one dimethylamine ligand are disordered over two equally occupied positions.
Modelling protein flexibility and plasticity is computationally challenging but important for understanding the function of biological systems. Furthermore, it has great implications for the prediction of (macro) molecular complex formation. Recently, coarse-grained normal mode approaches have emerged as efficient alternatives for investigating large-scale conformational changes for which more accurate methods like MD simulation are limited due to their computational burden. We have developed a Normal Mode based Simulation (NMSim) approach for efficient conformation generation of macromolecules. Combinations of low energy normal modes are used to guide a simulation pathway, whereas an efficient constraints correction approach is applied to generate stereochemically allowed conformations. Non-covalent bonds like hydrogen bonds and hydrophobic tethers and phi-psi favourable regions are also modelled as constraints. Conformations from our approach were compared with a 10 ns MD trajectory of lysozyme. A 2-D RMSD plot shows a good overlap of conformational space, and rms fluctuations of residues show a correlation coefficient of 0.78 between the two sets of conformations. Furthermore, a comparison of NMSim simulations starting from apo structures of different proteins show that ligand-bound conformations can be sampled for those cases where conformational changes are mainly correlated, e.g., domain-like motion in adenylate kinase. Efforts are currently being made to also model localized but functionally important motions for protein binding pockets and protein-protein interfaces using relevant normal mode selection criteria and implicit rotamer basin creation.
A new method to bridge the gap between ligand and receptor-based methods in virtual screening (VS) is presented. We introduce a structure-derived virtual ligand (VL) model as an extension to a previously published pseudo-ligand technique [1]: LIQUID [2] fuzzy pharmacophore virtual screening is combined with grid-based protein binding site predictions of PocketPicker [3]. This approach might help reduce bias introduced by manual selection of binding site residues and introduces pocket shape information to the VL. It allows for a combination of several protein structure models into a single "fuzzy" VL representation, which can be used to scan screening compound collections for ligand structures with a similar potential pharmacophore. PocketPicker employs an elaborate grid-based scanning procedure to determine buried cavities and depressions on the protein's surface. Potential binding sites are represented by clusters of grid probes characterizing the shape and accessibility of a cavity. A rule-based system is then applied to project reverse pharmacophore types onto the grid probes of a selected pocket. The pocket pharmacophore types are assigned depending on the properties and geometry of the protein residues surrounding the pocket with regard to their relative position towards the grid probes. LIQUID is used to cluster representative pocket probes by their pharmacophore types describing a fuzzy VL model. The VL is encoded in a correlation vector, which can then be compared to a database of pre-calculated ligand models. A retrospective screening using the fuzzy VL and several protein structures was evaluated by ten fold cross-validation with ROC-AUC and BEDROC metrics, obtaining a significant enrichment of actives. Future work will be devoted to prospective screening using a novel protein target of Helicobacter pylori and compounds from commercial providers.
Protein kinases are targets for drug development. Dysregulation of kinase activity leads to various diseases, e.g. cancer, inflammation, diabetes. Human polo-like kinase 1 (Plk1), a serine/threonine kinase, is a cancer-relevant gene and a potential drug target which attracts increasing attention in the field of cancer therapy. Plk1 is a key player in mitosis and modulates entry into mitosis and the spindle checkpoint at the meta-/anaphase transition. Plk1 overexpression is observed in various human tumors, and it is a negative prognostic factor for cancer patients. The same catalytical mechanism and the same co-substrate (ATP) lead to the problem of inhibitor selectivity. A strategy to solve this problem is represented by targeting the inactive conformation of kinases. Kinases undergo conformational changes between active and inactive conformation and thus an additional hydrophobic pocket is created in the inactive conformation where the surrounding amino acids are less conserved. A "homology model" of the inactive conformation of Plk1 was constructed, as the crystal structure in its inactive conformation is unknown. A crystal structure of Aurora A kinase served as template structure. With this homology model a receptor-based pharmacophore search was performed using SYBYL7.3 software. The raw hits were filtered using physico-chemical properties. The resulting hits were docked using Gold3.2 software, and 13 candidates for biological testing were manually selected. Three compounds of the 13 tested exhibit anti-proliferative effects in HeLa cancer cells. The most potent inhibitor, SBE13, was further tested in various other cancer cell lines of different origins and displayed EC50 values between 12 microM and 39 microM. Cancer cells incubated with SBE13 showed induction of apoptosis, detected by PARP (Poly-Adenosyl-Ribose-Polymerase) cleavage, caspase 9 activation and DAPI staining of apoptotic nuclei.
For a virtual screening study, we introduce a combination of machine learning techniques, employing a graph kernel, Gaussian process regression and clustered cross-validation. The aim was to find ligands of peroxisome-proliferator activated receptor gamma (PPAR-y). The receptors in the PPAR family belong to the steroid-thyroid-retinoid superfamily of nuclear receptors and act as transcription factors. They play a role in the regulation of lipid and glucose metabolism in vertebrates and are linked to various human processes and diseases. For this study, we used a dataset of 176 PPAR-y agonists published by Ruecker et al. ...
Two methods for the fast, fragment-based combinatorial molecule assembly were developed. The software COLIBREE® (Combinatorial Library Breeding) generates candidate structures from scratch, based on stochastic optimization [1]. Result structures of a COLIBREE design run are based on a fixed scaffold and variable linkers and side-chains. Linkers representing virtual chemical reactions and side-chain building blocks obtained from pseudo-retrosynthetic dissection of large compound databases are exchanged during optimization. The process of molecule design employs a discrete version of Particle Swarm Optimization (PSO) [2]. Assembled compounds are scored according to their similarity to known reference ligands. Distance to reference molecules is computed in the space of the topological pharmacophore descriptor CATS [3]. In a case study, the approach was applied to the de novo design of potential peroxisome proliferator-activated receptor (PPAR gamma) selective agonists. In a second approach, we developed the formal grammar Reaction-MQL [4] for the in silico representation and application of chemical reactions. Chemical transformation schemes are defined by functional groups participating in known organic reactions. The substructures are specified by the linear Molecular Query Language (MQL) [5]. The developed software package contains a parser for Reaction-MQL-expressions and enables users to design, test and virtually apply chemical reactions. The program has already been used to create combinatorial libraries for virtual screening studies. It was also applied in fragmentation studies with different sets of retrosynthetic reactions and various compound libraries.
There is a renewed interest in pseudoreceptor models which enable computational chemists to bridge the gap of ligand- and receptor-based drug design. We developed a pseudoreceptor model for the histamine H4 receptor (H4R) based on five potent antagonists representing different chemotypes. Here we present the selection of potential ligand binding pockets that occur during molecular dynamics (MD) simulations of a homology-based receptor model. We present a method for prioritizing receptor models according to their match with the consensus ligand-binding mode represented by the pseudoreceptor. In this way, ligand information can be transferred to receptor-based modelling. We use Geometric Hashing to match three-dimensional points in Cartesion space. This allows for the rapid translation- and rotation-free comparison of atom coordinates, which also permits partial matching. The only prerequisite is a hash table, which uses distance triplets as hash keys. Each time a distance triplet occurring in the candidate point set which corresponds to an existing key, the match is represented by a vote of the respective key. Finally, the global match of both point sets can be easily extracted by selection of voted distance triplets. The results revealed a preferred ligand-binding pocket in H4R, which would not have been identified using an unrefined homology model of the protein. The key idea was to rely on ligand information by pseudoreceptor modelling.
We developed the Pharmacophore Alignment Search Tool (PhAST), a text-based technique for rapid hit and lead structure searching in large compound databases. For each molecule, a two-dimensional graph of potential pharmacophoric points (PPPs) is created, which has an identical topology as the original molecule with implicit hydrogen atoms. Each vertex is coloured by a symbol representing the corresponding PPP. The vertices of the graph are canonically labelled. The symbols associated with the vertices are combined to a so-called PhAST-Sequence beginning with the vertex with the lowest canonical label. Due to the canonical labelling the created PhAST-Sequence is characteristic for each molecule. For similarity assessment, PhAST-Sequences are compared using the sequence identity in their global pairwise alignment. The alignment score lies between 0 (no similarity) and 1 (identical PhAST-Sequences). In order to use global pairwise sequence alignment, a score matrix for pharmacophoric symbols was developed and gap penalties were optimized. PhAST performed comparably and sometimes superior to other similarity search tools (CATS2D, MOE pharmacophore quadruples) in retrospective virtual screenings using the COBRA collection of drugs and lead structures. Most importantly, the PhAST alignment technique allows for the computation of significance estimates that help prioritize a virtual hit list.
The representation of small molecules as molecular graphs is a common technique in various fields of cheminformatics. This approach employs abstract descriptions of topology and properties for rapid analyses and comparison. Receptor-based methods in contrast mostly depend on more complex representations impeding simplified analysis and limiting the possibilities of property assignment. In this study we demonstrate that ligand-based methods can be applied to receptor-derived binding site analysis. We introduce the new method PocketGraph that translates representations of binding site volumes into linear graphs and enables the application of graph-based methods to the world of protein pockets. The method uses the PocketPicker algorithm for characterization of binding site volumes and employs a Growing Neural Gas procedure to derive graph representations of pocket topologies. Self-organizing map (SOM) projections revealed a limited number of pocket topologies. We argue that there is only a small set of pocket shapes realized in the known ligand-receptor complexes.
SIVsmmPBj-derived lentiviral vectors are capable of efficient primary human monocyte transduction, a capacity which is linked to the viral accessory protein Vpx. To enable novel gene therapy approaches targeting monocytes, in this thesis it was aimed to generate enhanced lentiviral vectors that meet the required standards for clinical applications with respect to gene transfer efficiency and safety. The vectors were tested for their suitability in a relevant therapeutic gene transfer approach. At first, it was investigated whether vectors derived from another Vpx-carrying lentivirus reveal the same capacity for monocyte transduction as SIVsmmPBj-derived vectors. A transduction experiment using HIV-2-derived vectors in comparison to PBj-derived vectors revealed a comparable transduction capacity, thus disproving the assumed uniqueness of the PBj vectors. The further generation and analysis of expression constructs for the vpx genes of HIV-2 and SIVmac demonstrated a similar functionality in monocyte transduction as the Vpx of PBj. As VpxPBj, both Vpx proteins facilitated monocyte transduction of a vpx-deficient PBj-derived vector system. For the generation of enhanced SIVsmmPBj and HIV-2 vector systems, only the transfer vectors were optimized, since the packaging vectors available already meet current standards. At first, several modifications were introduced into an available preliminary PBj-derived transfer vector by conventional cloning. The modifications included insertions of cPPT/CTS and WPRE as well as the deletions of the remaining pol sequence, the second exons of tat end rev, and the U3-region within the 3’LTR to generate a SIN vector. Thus, beside safety enhancement, the vector titers were also increased from 9.1x105 TU/ml achieved after concentration with the initial transfer vector up to 1.1x107 TU/ml with the final transfer vector. The PBj vector retained its capability of monocyte transduction when supplemented with Vpx. This conventional method of vector enhancement is time-consuming and may result in only sub-optimal vectors, since it depends on the presence of restriction sites which may not allow deletion of all needless sequences. Moreover, mutations may accumulate during the high number of cloning and amplification steps. Therefore, a new and easier method for lentiviral transfer vector generation was conceived. Three essential segments of the viral genome (5‘ LTR, RRE, ΔU3-3’ LTR) are amplified on the template of the lentiviral wild-type genome and fused by Fusion-PCR. Further necessary elements namely the cPPT/CTS-element, MCS, and PPT are included into the resulting vector by extension of the nucleotide primers used for the PCRs. The amplified and fused vector-scaffold can easily be integrated into a plasmid backbone, followed by insertion of the expression cassette of choice. By applying this approach, two novel lentiviral transfer vectors, based on the non-human SIVsmmPBj and the human HIV-2, were derived. Vector titers achieved for PBj and HIV-2 vectors supplemented with Vpx reached up to 4.0x108 TU/ml and 5.4x108 TU/ml, respectively. The capacity for monocyte transduction was maintained. Thus, safe and efficient, state of the art HIV-2- and PBj-derived vector systems are now available for future gene therapy strategies. Finally, the new vectors were used to set up an approach for gene correction of gp91phox-deficient monocytes for the treatment of X-linked chronic granulomatous disease (xCGD). The administration of autologous, gene-corrected monocytes to counteract systemic and acute infections could lead to a decreased infection load, dissolve granulomas and therefore improve the survival rate of hematopoietic stem cell transplantation (HSCT) which is the current treatment of choice for this disease. First, methods for analysis of gp91phox function were established. Next, they were employed to demonstrate the capacity of monocytes, obtained from healthy humans or mice, for phagocytosis, oxidative burst, and Staphylococcus aureus killing. The in vivo half-life of murine monocytes in the bloodstream and their distribution to specific tissues was determined. Lastly, HIV-1 vectors were used to transfer the gp91phox gene into monocytes from gp91phox-deficient mice. This resulted in the successful restoration of the oxidative burst ability in the cells. In summary, the general suitability of the new vectors for treatment of CGD by monocyte transduction was demonstrated. The results of the mouse experiments provide the foundation for future challenge experiments to evaluate the capability of gene-corrected monocytes to kill off microbes in vivo.
The CUG-binding protein 1 (CUG-BP1) is a member of the CUG-BP1 and ETR-like factors (CELF) family or the Bruno-like family and is involved in the control of splicing, translation and mRNA degradation. Several target RNA sequences of CUG-BP1 have been predicted, such as the CUG triplet repeat, the GU-rich sequences and the AU-rich element of nuclear pre-mRNAs and/or cytoplasmic mRNA. CUG-BP1 has three RNA-recognition motifs (RRMs), among which the third RRM (RRM3) can bind to the target RNAs on its own. In this study, we solved the solution structure of the CUG-BP1 RRM3 by hetero-nuclear NMR spectroscopy. The CUG-BP1 RRM3 exhibited a noncanonical RRM fold, with the four-stranded b-sheet surface tightly associated with the N-terminal extension. Furthermore, we determined the solution structure of the CUG-BP1 RRM3 in the complex with (UG)3 RNA, and discovered that the UGU trinucleotide is specifically recognized through extensive stacking interactions and hydrogen bonds within the pocket formed by the b-sheet surface and the N-terminal extension. This study revealed the unique mechanism that enables the CUG-BP1 RRM3 to discriminate the short RNA segment from other sequences, thus providing the molecular basis for the comprehension of the role of the RRM3s in the CELF/Bruno-like family.
5-LO is the key enzyme in the biosynthesis of proinflammatory leukotrienes. It catalyses the conversion of arachidonic acid to the hydroperoxy intermediate 5(S)-hydroperoxy-6- trans-8,11,14-cis-eicosatetraenoic acid (5-HpETE). In a second step 5-LO catalyses a dehydration reaction forming the unstable epoxide intermediate 5(S)-trans-5,6-oxido-7,9- trans-11,14-cis-eicosatetraenoic acid (leukotriene A4 , LTA4). The 5-LO gene is subjected to versatile regulation mechanisms. Apart from regulation by DNA-methylation and histone acetylation / deacetylation 5-LO gene expression can be regulated by the differentiation inducers calcitriol (1,25-dihydroxyvitamin D3) and transforming growth factor beta (TGFβ) 5-LO gene expression. In the myeloid cell lines Mono Mac 6 (MM6) and HL-60, differentiation with both agents caused a prominent upregulation of 5-LO mRNA level, of 5-LO protein expression and of 5-LO activity. Treatment with calcitriol alone already has an impact on 5-LO gene expression which is additionally potentiated by TGFβ treatment. Previous nuclear run-off analysis and reporter gene analysis could not associate the 5-LO promoter with the induction of 5-LO mRNA expression mediated by calcitriol and TGFβ. Inclusion of the 5-LO coding sequence (cds) and inclusion of the 5-LO cds plus the last four introns of the gene (J to M) in the 5-LO promoter construct pN10 led to an enhanced reporter gene activity. The inductions were dependent on vitamin D receptor (VDR) and retinoid x receptor (RXR) cotransfection. Therefore the work was concentrated on identifying elements outside the 5-LO promoter region which contribute to the calcitriol / TGFβ effect on 5-LO mRNA expression. Insertion of the LTA4 hydrolase coding sequence – a coding sequence of similar size - instead of the 5-LO cds led to a loss of the calcitriol / TGFβ effect (pN10LTA4Hcds 1-fold induction). Therewith, it was proven that the presence of the 5-LO cds is crucial for the upregulating effect of calcitriol / TGFβ on 5-LO mRNA level. Cloning of the SV40 promoter instead of pN10 upstream of the 5-LO cds still showed inducibility by treatment with the inducers which argues for a promoter unspecific effect. Insertion of the 5-LO cds in a promoterless basic vector (pGL3cds) displayed same inductions by calcitriol / TGFβ treatment as the 5-LO promoter 5-LO cds construct (pN10cds). Thus, the effect of the inducers is not dependent on the 5-LO promoter under the in vitro conditions of the reporter gene assay. Hence, further cloning was done with promoterless constructs. Through 5-LO cds deletion constructs a positive regulating region in exon 10 to 14 was discovered. To adapt the natural gene context the last four introns (J-M) of the 5-LO gene were inserted in a promoterless construct containing exon 10 to 14 (pGL3cdsΔABInJM). 5end deletion constructs of it revealed putative vitamin D responsive elements (VDREs) in exon 12 and intron M. Mutation of the putative VDREs led to a reduced calcitriol effect –more prominent when the putative VDRE in intron M was mutated (reduction of 40%). Moreover another putative VDRE in exon 10 with an adjacent SMAD binding element (SBE) was detected. SMAD proteins are effector proteins of TGFβ signalling. Gelshift experiments demonstrated in vitro binding of the VDR-RXR heterodimer to those three putative VDREs. By chromatin immunoprecipitation (ChIP) assay in vivo binding of VDR and RXR was shown to the VDRE in the region of exon 10, exon 12 and intron M. 8h and 24h incubation with calcitriol / TGFβ resulted in enhanced expression of VDR in each of the examined regions. The VDR is able to bind to the VDRE without its ligand, whereas this goes along with corepressor recruitment and thus the VDR has a repressive effect on transcription. Histone H4 acetylation was increased when MM6 cells were treated for 8h or 24h with calcitriol or the combination of calcitriol / TGFβ. This finding implies that at that point of time corepressors associated with the VDR are replaced by coactivators. It seems convincing that 5-LO transcription is mainly promoted by calcitriol alone which leads to a more accessible chromatin structure. Previous data indicated that calcitriol and TGFβ upregulate 5-LO RNA maturation and 5- LO transcript elongation. Thus several elongation markers were investigated by ChIP analysis: Histone H3 lysine 36 (H3K36) trimethylation and H4K20 monomethylation were detected in the analysed regions in exon 10, exon 12 and intron M. In region exon 10 the H3K36 trimethylation status was enhanced after 24h calcitriol or calcitriol / TGFβ treatment. An increased H4K20 monomethylation status in all regions was observed when MM6 cells were treated for 24h with calcitriol / TGFβ. 24h treatment with both agents also enhanced the recruitment of the elongation form of RNA polymerase II, which is phosphorylated at serine 2 of the carboxyterminal domain, to the investigated regions. These findings prove the positive regulating role for calcitriol and TGFβ on 5-LO transcript elongation. A putative mechanism of the effect of calcitriol and TGFβ on 5-LO RNA maturation might be the elevated phosphorylation of serine 2 of the RNA Polymerase II which is known to be followed by recruiting polyadenylating factors.
Riboswitches are a novel class of genetic control elements that function through the direct interaction of small metabolite molecules with structured RNA elements. The ligand is bound with high specificity and affinity to its RNA target and induces conformational changes of the RNA's secondary and tertiary structure upon binding. To elucidate the molecular basis of the remarkable ligand selectivity and affinity of one of these riboswitches, extensive all-atom molecular dynamics simulations in explicit solvent ({approx}1 µs total simulation length) of the aptamer domain of the guanine sensing riboswitch are performed. The conformational dynamics is studied when the system is bound to its cognate ligand guanine as well as bound to the non-cognate ligand adenine and in its free form. The simulations indicate that residue U51 in the aptamer domain functions as a general docking platform for purine bases, whereas the interactions between C74 and the ligand are crucial for ligand selectivity. These findings either suggest a two-step ligand recognition process, including a general purine binding step and a subsequent selection of the cognate ligand, or hint at different initial interactions of cognate and noncognate ligands with residues of the ligand binding pocket. To explore possible pathways of complex dissociation, various nonequilibrium simulations are performed which account for the first steps of ligand unbinding. The results delineate the minimal set of conformational changes needed for ligand release, suggest two possible pathways for the dissociation reaction, and underline the importance of long-range tertiary contacts for locking the ligand in the complex.
Lentiviral vectors mediate gene transfer into dividing and most non-dividing cells. Thereby, they stably integrate the transgene into the host cell genome. For this reason, lentiviral vectors are a promising tool for gene therapy. However, safety and efficiency of lentiviral mediated gene transfer still needs to be optimised. Ideally, cell entry should be restricted to the cell population relevant for a particular therapeutic application. Furthermore, lentiviral vectors able to transduce quiescent lymphocytes are desirable. Although many approaches were followed to engineer retroviral envelope proteins, an effective and universally applicable system for retargeting of lentiviral cell entry is still not available. Just before the experimental work of this thesis was started, retargeting of measles virus (MV) cell entry was achieved. This virus has two types of envelope glycoproteins, the hemagglutinin (H) protein responsible for receptor recognition and the fusion (F) protein mediating membrane fusion. For retargeting, the H protein was mutated in its interaction sites for the native MV receptors and a ligand or a single-chain antibody (scAb) was fused to its ectodomain. It was hypothesised that the retargeting system of MV can be transferred to lentiviral vectors by pseudotyping human immunodeficiency virus-1 (HIV-1) derived vector particles with the MV glycoproteins. As the unmodified MV glycoproteins did not pseudotype HIV vectors, two F and 15 H protein variants carrying stepwise truncations or amino acid (aa) exchanges in their cytoplasmic tails were screened for their ability to form MV-HIV pseudotypes. The combinations Hcd18/Fcd30, Hcd19/Fcd30 and Hcd24+4A/Fcd30 led to most efficient pseudotype formation with titers above 10exp6 transducing units /ml, using concentrated particles. The F cytoplasmic tail was truncated by 30 aa and the H cytoplasmic tail was truncated by 18, 19 or 24 residues with four added alanines after the start methionine in the latter case. Western blot analysis indicated that particle incorporation of the MV glycoproteins was enhanced upon truncation of their cytoplasmic tails. With the MV-HIV vectors high titers on different cell lines expressing one or both MV receptors were obtained, whereas MV receptor-negative cells remained untransduced. Titers were enhanced using an optimal H to F plasmid ratio (1:7) during vector particle production. Based on the described pseudotyping with the MV glycoprotein variants, HIV vectors retargeted to the epidermal growth factor receptor (EGFR) or the B cell surface marker CD20 were generated. For the production of the retargeted vectors MVaEGFR-HIV and MVaCD20-HIV, Fcd30 together with a native receptor blind Hcd18 protein, displaying at its ectodomain either the ligand EGF or a scAb directed against CD20 were used. With these vectors, gene transfer into target receptor-positive cells was several orders of magnitude more efficient than into control cells. The almost complete absence of background transduction of non-target cells was e.g. demonstrated in mixed cell populations, where the CD20-targeting vector selectively eliminated CD20-positive cells upon suicide gene transfer. Remarkably, transduction of activated primary human CD20-positive B cells was much more efficient with the MVaCD20-HIV vector than with the standard pseudotype vector VSV-G-HIV. Even more surprisingly, MVaCD20-HIV vectors were able to transduce quiescent primary human B cells, which until then had been resistant towards lentiviral gene transfer. The most critical step during the production of MV-HIV pseudotypes was the identification of H cytoplasmic tail mutants that allowed pseudotyping while retaining the fusion helper function. In contrast to previously inefficient targeting strategies, the reason for the success of this novel targeting system must be based on the separation of the receptor recognition and fusion functions onto two different proteins. Furthermore, with the CD20-targeting vector transduction of quiescent B cells was demonstrated for the first time. Own data and literature data suggest that CD20 binding and hyper-cross-linking by the vector particles results in calcium influx and thus activation of quiescent B cells. Alternatively this feature may be based on a residual binding activity of the MV glycoproteins to the native MV receptors that is insufficient for entry but induces cytoskeleton rearrangements dissolving the post-entry block of HIV vectors. Hence, in this thesis efficient retargeting of lentiviral vectors and transduction of quiescent cells was combined. This novel targeting strategy should be easily adaptable to many other target molecules by extending the modified MV H protein with appropriate specific domains or scAbs. It should now be possible to tailor lentiviral vectors for highly selective gene transfer into any desired target cell population with an unprecedented degree of efficiency.
Shape complementarity is a compulsory condition for molecular recognition. In our 3D ligand-based virtual screening approach called SQUIRREL, we combine shape-based rigid body alignment with fuzzy pharmacophore scoring. Retrospective validation studies demonstrate the superiority of methods which combine both shape and pharmacophore information on the family of peroxisome proliferator-activated receptors (PPARs). We demonstrate the real-life applicability of SQUIRREL by a prospective virtual screening study, where a potent PPARalpha agonist with an EC50 of 44 nM and 100-fold selectivity against PPARgamma has been identified...
The light-harvesting complex of photosystem II (LHC-II) is the major antenna complex in plant photosynthesis. It accounts for roughly 30% of the total protein in plant chloroplasts, which makes it arguably the most abundant membrane protein on Earth, and binds about half of plant chlorophyll (Chl). The complex assembles as a trimer in the thylakoid membrane and binds a total of 54 pigment molecules, including 24 Chl a, 18 Chl b, 6 lutein (Lut), 3 neoxanthin (Neo) and 3 violaxanthin (Vio). LHC-II has five key roles in plant photosynthesis. It: (1) harvests sunlight and transmits excitation energy to the reaction centres of photosystems II and I, (2) regulates the amount of excitation energy reaching each of the two photosystems, (3) has a structural role in the architecture of the photosynthetic supercomplexes, (4) contributes to the tight appression of thylakoid membranes in chloroplast grana, and (5) protects the photosynthetic apparatus from photo damage by non photochemical quenching (NPQ). A major fraction of NPQ is accounted for its energy-dependent component qE. Despite being critical for plant survival and having been studied for decades, the exact details of how excess absorbed light energy is dissipated under qE conditions remain enigmatic. Today it is accepted that qE is regulated by the magnitude of the pH gradient (ΔpH) across the thylakoid membrane. It is also well documented that the drop in pH in the thylakoid lumen during high-light conditions activates the enzyme violaxanthin de-epoxidase (VDE), which converts the carotenoid Vio into zeaxanthin (Zea) as part of the xanthophyll cycle. Additionally, studies with Arabidopsis mutants revealed that the photosystem II subunit PsbS is necessary for qE. How these physiological responses switch LHC-II from the active, energy transmitting to the quenched, energy-dissipating state, in which the solar energy is not transmitted to the photosystems but instead dissipated as heat, remains unclear and is the subject of this thesis. From the results obtained during this doctoral work, five main conclusions can be drawn concerning the mechanism of qE: 1. Substitution of Vio by Zea in LHC-II is not sufficient for efficient dissipation of excess excitation energy. 2. Aggregation quenching of LHC-II does not require Vio, Neo nor a specific Chl pair. 3. With one exception, the pigment structure in LHC-II is rigid. 4. The two X-ray structures of LHC-II show the same energy transmitting state of the complex. 5. Crystalline LHC-II resembles the complex in the thylakoid membrane. Models of the aggregation quenching mechanism in vitro and the qE mechanism in vivo are presented as a corollary of this doctoral work. LHC-II aggregation quenching in vitro is attributed to the formation of energy sinks on the periphery of LHC-II through random interaction with other trimers, free pigments or impurities. A similar but unrelated process is proposed to occur in the thylakoid membrane, by which excess excitation energy is dissipated upon specific interaction between LHC-II and a PsbS monomer carrying Zea. At the end of this thesis, an innovative experimental model for the analysis of all key aspects of qE is proposed in order to finally solve the qE enigma, one of the last unresolved problems in photosynthesis research.
The respiratory chain is composed of protein complexes residing in the inner mitochondrial membrane of eukaryotes or in the cytoplasmic membrane of prokaryotes. This cellular energy converter transforms a redox potential stored in low potential substrates into an electrochemical potential across the respective membrane. Typical respiratory chains contain the complexes I, II, III and IV named according to their sequence in the respiratory chain reaction. Electrons of low potential substrates enter at complex I or II and are passed via complex III to complex IV where they are transferred to oxygen. The transport of electrons between the complexes is mediated by small electron shuttles like quinol or cytochrome c. Two different models describe their exchange either by (1) random collision of freely diffusible electron shuttles and membrane protein complexes or (2) arrangement of the complexes in supercomplexes enabling direct channeling of electron shuttles. In the Gram positive bacterium Corynebacterium glutamicum, the complex III to complex IV electron shuttle cytochrome c is not diffusible but a covalently bound part of the diheme cytochrome subunit QcrC of complex III. Therefore, the complexes III and IV have to form a supercomplex for electron transduction. The aim of this thesis was to purify and characterise this obligatory supercomplex III/IV of C. glutamicum. To gain sufficient biomass of C. glutamicum as starting material for purification, a phosphate buffered minimal medium was developed that enabled yield of total 120 g wet cell mass (38 g dry mass) in 12 L (6×2 L) shaking cultures. The determined conversion factor of glucose into biomass was 0.46 g/g indicating an intact respiratory chain. The yield was increased by bioreactor cultivation to ~690 g wet cell mass (~220 g dry mass) in ~10 L culture volume. A previously described homologous expression system was applied that produces the complex IV subunit CtaD with a fused Strep-tag II to facilitate purification. Affinity purifications using the Strep-tag II affinity to Strep-Tactin resin yielded a mixture of complexes and supercomplexes. Two supercomplex III/IV versions named supercomplex A and B and free complex IV were identified in this mixture by size exclusion chromatography, redox difference spectroscopy and two dimensional polyacrylamide gel electrophoresis including blue native polyacrylamide electrophoresis. The here presented downscaled blue native polyacrylamide electrophoresis method with analysis times of ~1 h enabled efficient screening of factors influencing the stability of supercomplex III/IV. The screening resulted that the integrity of supercomplex III/IV is preserved by using neutral detergents at minimal detergent to protein ratios for solubilisation and low detergent concentrations for purification and storage slightly above the required critical micellar concentration. Furthermore, pH <=7.5 is required for stability of supercomplex III/IV. Large biomass yields enabled upscaling of supercomplex III/IV affinity purification. Application of the identified stability conditions resulted in affinity purified samples free of supercomplex B. The major component supercomplex A was efficiently separated from residual free complex IV by preparative size exclusion chromatography. Concentration of purified supercomplex A by ultracentrifugation resulted in integrity of the supercomplex for several days at 4 °C. Purified supercomplex A contains ten different previously described subunits. The heme content of supercomplex A relative to the protein mass is heme A: 6.0 μmol/g, heme B: 6.5 μmol/g, and heme C: 5.8 μmol/g determined by redox difference spectroscopy and biochemical protein quantification. This indicates an equimolar ratio of complex III and complex IV in supercomplex A. Supercomplex A has quinol oxidase activity that is inhibited by stigmatellin or sodium azide. The turnover number of transferred electrons per complex III monomer is 148 s−1 at 25° C. The homogeneity and stability of the prepared supercomplex A enabled the growth of threedimensional crystals of up to 0.1 mm in length. Their composition of supercomplex A was verified by redox difference spectroscopy of intact crystals and blue native polyacrylamide electrophoresis of dissolved crystals. The crystals diffracted X-rays corresponding to a resolution of ~10 Å. Electron microscopy of negative stained samples revealed the uniform shape of purified supercomplex A particles with dimensions of 22 × 9 nm in the view plane. Combined heme quantification, size determination, determined activity, symmetry considerations, and particle shape indicate that supercomplex A has a central dimer of complex III and two monomers of complex IV on opposite sides. This conformation is functionally reasonable because it provides each complex III monomer with one complex IV monomer as electron acceptor. Therefore, the stoichiometry of supercomplex A is most likely III2IV2. The sensitivity of supercomplex A to detergents indicated a role of phospholipids in its stability. Therefore, a method for phospholipid identification and quantification was developed that is suitable for detergent solubilised crude and purified membrane protein samples. The analysis combines separation of phospholipid classes according to their head group by normal phase high performance liquid chromatography with evaporative light scattering detection. Calibration with external standard allows quantification of phospholipid amount in the range of 0.25-12 μg. The method is verified by analysing the phospholipid content of the well characterised complex III of Saccharomyces cerevisiae. The reduction of its phospholipid content during its purification steps is monitored. The complex III sample purified to crystallisation quality contains the phospholipid content that was also observed in previously reported structures determined by X-ray crystallography. Purified stable supercomplex A from C. glutamicum revealed a large content of bound phospholipids. The main differences between intact supercomplex A and a mixture of potentially disintegrated smaller complexes is that intact supercomplex A has a doubled phosphatidic acid content and an increased phosphatidyl glycerol content. The importance of the small anionic phosphatidic acid for mediation of contacts between complexes in a supercomplex is discussed. The total phospholipid content of stable supercomplex A is sufficient for a complete belt surrounding the supercomplex in the membrane plane. This indicates that also all essential internal phospholipid binding positions are occupied and potentially stabilise supercomplex A.
The function of APOBEC3G in the innate immune response against the HIV infection of primary cells
(2008)
In the past few years the regulation of HIV-1 replication by cellular cofactors has been a major topic of ongoing research. These factors potentially represent new targets for antiviral therapy as resistance will be minimized. However this requires a better understanding of the interaction of HIV-1 with these cellular factors and the immune system. The virus infects the cells of the immune system, beginning with macrophages and dendritic cells as primary target cells during transmission. The cellular cofactor, APOBEC3G was found to be an antiviral factor in macrophages, dendritic cells and primary T cells. APOBEC3G is a cytidindeaminase which causes G->A hypermutations in the HIV-Genome. Another protein which has a strong inhibitory effect on the HIV infection is Interferon alpha (IFN-alpha), however the exact reason for this has not yet been elucidated. The bacterial protein, Lipopolysaccharide (LPS) also induces a strong antiviral state in macrophages. In micro-array analysis it was shown that APOBEC3G was upregulated after the stimulation with both IFN-alpha and LPS in macrophages. The goal of this work was to investigate the role of APOBEC3G in the innate immune response to APOBEC3G. For this, the expression of APOBEC3G was examined in HIV-1 target cells after stimulation with IFN-alpha or LPS and the effect of the protein on the viral infection was examined. In the first experiments it could be shown through real time quantitative PCR that APOBEC3G was overexpressed after the stimulation with IFN-alpha or LPS. This result could be shown in monocytes derived macrophages from different blood donors. It was also shown that the overexpression of APOBEC3G correlated directly with the concentration of IFN-alpha. Through mutational analysis it could be then shown that the overexpressed APOBEC3G protein was also functional in the cells. In order to show that this was the result of APOBEC3G, the protein was the regulated through lentiviral vectors. After transduction of cell lines with lentiviral vectors containing APOBEC3G, the infection was inhibited by up to 70%. The infection was restored after the addition of shRNAs against APOBEC3G. For the further experiments, CD34+ stem cells were used. The cells were transduced the day after thawing with lentiviral vectors containing an eGFP marker gene and either APOBEC3G or shRNAs against APOBEC3G. The CD34+ cells were then cultivated and differentiated to macrophages. The cells transduced with Lentiviral vectors containing APOBEC3G had a very high expression of APOBEC3G in the cells, however the cells transduced with shRNA against APOBEC3G did not show a reduction in the protein expression. The infectivity of the transduced CD34+ and CD34 derived macrophages was then examined. It was expected that the cells transduced with APOBEC3G would show a reduced HIV-1 infection, and the cells transduced with shRNA against APOBEC3G would show an increase in infection. After the transduction and differentiation the CD34+ cells from the 3 donors were stimulated and infected with wild type HIV-1 and Vif defective HIV-1 virus. Vif is a viral protein that can bind to APOBEC3G leading it to the proteasome for degradation. The cells from the first donor transduced with APOBEC3G, were very difficult to infect. In general the shRNA against APOBEC3G had little effect on the course of infection; presumably, the shRNA against APOBEC3G was not active in most of these cells. Only the cells from the first donor showed an increase in HIV infection after the transduction with the shRNAs against APOBEC3G, this was most notably the case in the cells stimulated with IFN-alpha, which usually show very little infection. This work showed that APOBEC3G plays an important role in the innate immune response to HIV-1. The effect of APOBEC3G is both cell type as well as donor dependent. Recently, an interesting study also showed that there is a correlation between the expression of APOBEC3G in HIV infected individuals and their progression to AIDS. A better understanding of the role that APOBEC3G plays in the innate immune response would help in the search of new therapeutic possibilities. This could be done by inhibiting the Vif-APOBEC3G interaction in order to increase the amount of active APOBEC3G in the cells or increasing the APOBEC3G concentration in the cells in some manner.
This work presents a contribution to the literature on methods in search of lowdimensional models that yield insight into the equilibrium and kinetic behavior of peptides and small proteins. A deep understanding of various methods for projecting the sampled configurations of molecular dynamics simulations to obtain a low-dimensional free energy landscape is acquired. Furthermore low-dimensional dynamic models for the conformational dynamics of biomolecules in reduced dimensionality are presented. As exemplary systems, mainly short alanine chains are studied. Due to their size they allow for performing long simulations. They are simple, yet nontrivial systems, as due to their flexibility they are rapidly interconverting conformers. Understanding these polypeptide chains in great detail is of considerable interest for getting insight in the process of protein folding. For example, K. Dill et al. conclude in their review [28] about the protein folding problem that "the once intractable Levinthal puzzle now seems to have a very simple answer: a protein can fold quickly and solve its large global optimization puzzle simply through piecewise solutions of smaller component puzzles".
By translocating proteasomal degradation products into the endoplasmic reticulum (ER) for loading of major histocompatibility complex (MHC) class I molecules, the ATP binding cassette (ABC) transporter associated with antigen processing (TAP) plays a pivotal role in the adaptive immunity against infected or malignantly transformed cells. A key question regarding the transport mechanism is how the inter-domain communication and conformational dynamics of the TAP complex are connected during the peptide transport. To identify residues involved in this processes, we evolved a Trojan horse strategy in which a small artificial protease is inserted into antigenic epitopes. After binding, the TAP backbone in contact is cleaved, allowing the peptide sensor site to be mapped by mass spectrometry. Within this study, the peptide sensor and transmission interface have been identified. This region aligns with the cytosolic loop 1 (CL1) of Sav1866 and MsbA. Based on a number of experimental data and the homology to the bacterial ABC exporter Sav1866, we constructed a 3D structural model of the core TAP complex. According to this model, the CL1 and CL2 of TAP1 are extended cytosolic loops connecting the transmembrane helices (TMH) 2 and 3, and TMH4 and 5 respectively, and contact both nucleotide binding domains (NBDs) of the opposite subunit. In contrast to exporters, the cytosolic loop (named L-loop) of BtuCD importer is much shorter, and contacts only one NBD. The data confirm that the CL1 of TAP1 functions as signal transducer in ABC exporters, because it does not interfere with substrate binding but with substrate transport. The peptide contact site identified herein is restructured during the ATP hydrolysis cycle. Importantly, TAP showed a structural change trapped in the ATP hydrolysis transition state, because direct contact between peptide and CL1 is abolished. By cysteine scanning, the most conserved residues within CL1 were identified, which disrupted the tight coupling between peptide binding and transport. Together with Val-288, these residues are essential in sensing the bound peptide and inter-domain signal transmission. To characterize the molecular architecture of CL1, a convenient and minimally perturbing approach was used, which combined cysteine substitution in the CL1 region and determination of accessibility to thiol specific compounds with different properties. These studies revealed that the N-terminal region of CL1 has a good accessibility for hydrophilic (iodoacetamidofluorescein, IAF) and amphiphilic probes (BODIPY maleimide, BM), whereas the C-terminal region is accessible for hydrophobic probe (coumarin maleimide, CM). Kinetic studies of fluorescence labeling suggest that this region displayed a different accessibility to probes when the protein undergoes distinct conformations (e. g. nucleotide free state), thereby reflecting conformational transitions. Fluorescence labeling with BM induces a lost of peptide transport, whereas the peptide binding remains unaffected. These results indicate that covalent modifications of the CL1 residues influenced the inter-domain communication between transmembrane domain (TMD) and NBD. The X-loop is a recently discovered motif in the NBD of ABC exporters, which stays in close contact to the CLs. Moreover, because the X-loop precedes the ABC signature motif, it probably responds to ATP binding and hydrolysis and may transmit conformational changes to the CLs. By substitution of the highly conserved Glu-602 of TAP2 with residues that have different chemical properties, it was shown for the first time that the X-loop is a functional important element, which plays an key role in coupling substrate binding to downstream events in the transport cycle. We further verified domain swapping in the TAP complex by cysteine cross-linking. The TAP complex can be reversibly arrested either in a binding or translocation incompetent state by cross-linking of the X-loop to CL1 or CL2, respectively. These results resolve the structural arrangement of the transmission interface and point to different functions of the cytosolic loops in substrate recognition, signaling and transport.
In the present work, the photo-protection mechanisms in plants and purple bacteria were investigated experimentally at the molecular level. For this purpose, several spectroscopic methods were combined and applied to elucidate the function of carotenoids, pigments of the photosynthetic apparatus, in photo-protection. The experiments were focused on the mechanisms involved in quenching of singlet and triplet states of the electronically excited (bacterio)chlorophylls. This photosynthetic reaction events occur on an ultrafast time-scale. Measuring such short-lived events, and understanding the underlying principles, demand some of the most precise experiments and exact measurement technologies currently available. This implies certain requirements for the light source used: a suitable wavelength within the absorption band of the sample, sufficient power, and, most importantly, a pulse duration short compared to the studied reaction. Nowadays, we can achieve all this requirements using femtosecond-spectroscopic systems, which produce laser pulses shorter than 100 femtoseconds (fs). Transient absorption spectroscopy provides important information on molecular dynamics interrogating electronic transitions. The technique is based on photochemical generation of transient species with femtoseconds pump pulses and measuring transient absorption changes of the sample using a second, time delayed probe pulse which in this case is a spectrally broad white-light pulse.
Presentation of intracellular processed antigens by major histocompatibility (MHC) class I molecules to CD8+ cytotoxic T lymphocytes is mediated by the macromolecular peptide loading complex (PLC). In particular accessory proteins, including the transporter associated with antigen processing (TAP) and tapasin, play a pivotal role in the MHC class I mediated antigen presentation pathway. TAP belongs to the ATP-binding cassette (ABC) superfamily and consists of TAP1 (ABCB2) and TAP2 (ABCB3), each of which possesses a transmembrane and a nucleotide-binding domain (NBD). The ER-resident glycoprotein tapasin promotes the optimal folding and assembly of MHC-peptide complexes, and independently stabilizes the steady state expression level of TAP. In the present thesis recombinant Fv, scFv and Fab antibody fragments to human TAP from a hybridoma cell line expressing the TAP1-specific monoclonal antibody mAb148.3, were generated. The epitope of the mAb148.3 was mapped to the very last five C-terminal amino acid residues of TAP1 on solid-supported peptide arrays. The recombinant antibody fragments were heterologously expressed in E. coli and insect cells, and purified to homogeneity by affinity chromatography. The monoclonal and recombinant antibodies display nanomolar affinity to the last five C-terminal amino acid residues of TAP1 as demonstrated by enzyme linked immunosorbent assay (ELISA) and surface plasmon resonance (SPR). Surprisingly, the recombinant antibody fragments confer thermal stability to the heterodimeric TAP complex in insect cells when incubated at elevated temperature. At the same time, TAP is arrested in a peptide transport incompetent conformation, although ATP and peptide binding to TAP are not affected. Furthermore, the recombinant antibodies were successfully used in the purification of the PLC from a human B-lymphoblastoid cell line and a novel factor, protein disulfide isomerase (PDI), was identified by matrix assisted laser desorption/ionisation-mass spectrometry (MALDI-MS). In the second part of this thesis the tapasin-MHC class I interaction was investigated. It is for this reason, that an in vitro assay had been established for direct measuring tapasin-MHC class I interactions. First, soluble single chain MHC class I molecules were engineered, choosing two MHC class I alleles: HLA-B4402 representing a highly tapasin-dependent allele and with HLA-B4405, a tapasin-independent allele was chosen. Tapasin as well as the two single chain MHC class I constructs, scB4402-b2m and scB4405-b2m, were expressed in insect cells and purified from insect cell supernatants by affinity chromatography. In contrast to the HLA-B4405 allele, which was expressed and secreted at moderate yield, the HLA-B4402 allele was expressed and trapped inside the insect cells instead of secreted into the medium. Peptide-binding and anisotropy measurements with fluorescein-labeled peptides verified the functionality of the scB4405-b2m. For further investigation of the tapasin-MHC class I interaction an in vitro assay was established using surface plasmon resonance spectroscopy. Due to the transient nature of the interaction including the decreased affinity of both interaction partners, kinetic data acquisition was difficult to evaluate. Furthermore, interaction of the scB4405-b2m with the sensor surface itself contributed to the measured interaction. Additionally, to investigate tapasin editing function, tapasin as well as the scB4405-b2m-peptide complex were tethered on fluid chelator lipid bilayers and monitored by reflectance interference (RIf) and total internal reflection fluorescence spectroscopy (TIRFS). Stable immobilization of scB4405-b2m-peptide complex as well as of tapasin was observed, unfortunately no changes in peptide dissociation kinetics monitored in the TIRFS channel were detected. Presumably, the tapasin-independent HLA-B4405 already loaded with a high affinity peptide is not influenced by the peptide-editing function of tapasin. Here, for the first time an in vitro assay was established for direct probing interactions within the various proteins of the PLC.
Hypoxic pulmonary vasoconstriction (HPV) redistributes pulmonary blood flow from areas of low oxygen partial pressure to areas of normal or relativity high oxygen availability, thus optimising the matching of perfusion to ventilation and preventing arterial hypoxemia. Generalised alveolar hypoxia results in a sustained increase in pulmonary artery pressure which in turn leads to structural changes in the walls of the pulmonary vasculature (pulmonary vascular remodelling). Recent findings have indicated a role for cytochrome P450 (CYP) epoxygenase-derived epoxyeicosatrienoic acids (EETs) in hypoxia-induced pulmonary vasoconstriction. Given that the intracellular concentration of EETs is determined by the soluble epoxide hydrolase (sEH), which metabolises EETs to their less active dihydroxyeicosatrienoic acids (DHETs), we assessed the influence of the sEH and EETs on pulmonary artery pressure, acute and chronic HPV, and pulmonary vascular remodelling in the mouse lung. In isolated lungs from wild-type mice, acute HPV was significantly increased by sEH inhibition, an effect abolished by pre-treatment with CYP epoxygenase inhibitors and the EET antagonist 14,15-EEZE. The acute hypoxia-induced vasoconstriction and EET production were greater in lungs from sEH-/- mice than from wild-type mice and sEH inhibition had no further effect on HPV in lungs from the former animals, while MSPPOH (CYP epoxygenase inhibitor) and 14,15-EEZE decreased the response. Exogenous application of 11,12-EET increased pulmonary artery pressure in a concentration-dependent manner and enhanced acute HPV in wild-type lungs, while 14,15-EET and 11,12-DHET were without significant effect on pulmonary artery pressure. 5-HT2A receptor antagonism or Rho kinase inhibition shifted the EET concentration-response curve to the right and abrogated the EET- and sEH inhibition-induced potentiation of acute hypoxic vasoconstriction. In lungs from wild-type and sEH-/- mice, hypoxic preconditioning (hypoxic ventilation for 10 minutes) enhanced the 5-HT response. 1-Adamantyl-3-cyclohexylurea (ACU), a sEH inhibitor, further amplified the hypoxia-induced 5-HT-hypersensitivity in wild-type mice. However, after hypoxic preconditioning, the sEH-/- lungs displayed a striking leftward shift in the 5-HT response. 11,12-EET can activate TRPC6 channels in endothelial cells by eliciting its translocation to the plasma membrane, more specifically to membrane domains enriched with the caveolae marker caveolin-1. This effect was also observed in rat pulmonary artery smooth muscle cells overexpressing the channel. Exposure of the latter cells to acute hypoxia also stimulated the intracellular translocation of TRPC6 to caveolae, an effect that was sensitive to the EET antagonist. The EET-induced translocation of TRPC6 channels was prevented by a 5-HT2A receptor antagonist but not by a Rho kinase inhibitor. Moreover, while acute hypoxia and 11,12-EET increased pulmonary pressure in lungs from TRPC6+/- mice, lungs from TRPC6-/- mice did not respond to either stimuli. These results indicate that the sEH and CYP-derived EETs are involved in acute HPV and that EET-induced pulmonary contraction under normoxic and hypoxic conditions involves a TRPC6 channel, a 5-HT2A receptor-dependent pathway and Rho kinase activation. In the second part of the study the role of the sEH in the development of pulmonary hypertension and vascular remodelling induced in mice by exposure to hypoxia (10% O2) for 21 days was analysed. In wild-type mice, chronic hypoxia decreased the pulmonary expression/activity of the sEH, induced right heart hypertrophy and erythropoiesis, and increased the number of partially and fully muscularised pulmonary resistance arteries (by 3-fold). Moreover, in HEK 293 cells, hypoxia (1% O2 up to 24 h) decreased sEH promoter activity by 50%. In isolated lungs, pre-exposure to chronic hypoxia significantly increased baseline perfusion pressures and potentiated the acute HPV. While an sEH inhibitor, ACU, potentiated acute HPV in lungs from mice maintained in normoxic conditions, it had no effect on HPV in lungs from mice exposed to hypoxia. The EET antagonist, 14,15-EEZE, abolished the sEH inhibitor-dependent increase in acute HPV in normoxic lungs and decreased HPV in chronic hypoxic lungs. Hypoxia-induced right heart hypertrophy and erythropoiesis were more pronounced in sEH-/- than in wild-type mice. Under normoxic and hypoxic conditions the muscularisation of resistance pulmonary arteries was greater in lungs from sEH-/- mice than in lungs from wild-type mice. sEH-/- mice also displayed an enhanced acute HPV, compared to that observed in wild-type mice and chronic exposure to hypoxia did not further potentiate acute HPV. However, in the presence of 14,15-EEZE responses returned to levels observed in normoxic lungs from wild-type animals. Furthermore, immunohistochemistry demonstrated an extensive expression of the sEH in the medial wall of pulmonary arteries from human donor lungs. Whereas sEH expression was not detectable in samples from pulmonary hypertension patients, indicating that the sEH is involved in hypoxia-induced pulmonary vascular remodelling and hypoxic pulmonary vasoconstriction. Taken together, the results presented in this thesis indicate that the expression/activity of the sEH is an important determinant of the magnitude of acute and chronic hypoxia-induced pulmonary vasoconstriction and pulmonary vascular remodelling by inactivating vasoconstrictor CYP-derived EETs. As sEH inhibitors are currently being developed for the treatment of human systemic hypertension, it should be noted that these compounds may even promote the development of pulmonary hypertension.
Three-dimensional structure of the glycine-betaine transporter BetP by cryo electron crystallography
(2008)
The soil bacterium Corynebacterium glutamicum has five secondary transporters for compatible solutes allowing it to cope with osmotic stress. The most abundant of them, the transporter BetP, performs a high affinity uptake of glycine-betain when encountering hyperosmotic stress. BetP belongs to the betaine/carnitine/choline/transporter (BCCT) family, and is predicted to have twelve transmembrane helices with both termini facing the cytoplasm. The goal of this thesis is to facilitate understanding of BetP function by determining a three dimensional (3D) model of its structure. Two-dimensional (2D) crystallization of wild-type (WT) BetP has been successfully performed by reconstitution into a mixture of E. coli lipids and bovine cardiolipin, which resulted in vesicular crystals diffracting to 7.5 Å resolution (Ziegler, Morbach et al. 2004). Diffraction patterns of these crystals however showed unfocused spots, generally due to high mosaicity. Better results were obtained by using the constitutively active mutant BetPdeltaC45 in which the first 45 amino acids of the positively charged C-terminus were removed. BetPdeltaC45 crystals obtained under the same conditions for BetP WT were concluded to be pseudo crystals, based on the inconsistence of symmetry. These crystals had BetPdeltaC45 molecules randomly up/downwards inserted into membrane crystals, and cannot be used for structure determination, even though they diffracted up to 7 Å. The problem of pseudo crystal formation could be solved by changing the lipids used for 2D crystallization to a native lipid extract from C. glutamicum cells. This change of lipids improved the crystals to well-ordered packing with exclusive p121_b symmetry. To understand the role of lipids in crystal packing and order, lipids were extracted at different stages during crystallization, and identified by using multiple precursor ion scanning mass spectrometry. The results show that phosphatidyl glycerol (PG) 16:0-18:1 is the most dominant lipid species in C. glutamicum membranes, and that BetP has a preference for the fatty acid moieties 16:0-18:1. Crystallization with synthetic PG 16:0-18:1 proved that an excess of this lipid prevents pseudo crystal formation, but these crystals did not reach the quality as previously achieved by using the C. glutamicum lipids. Apart from the effect of lipids in crystallinity, the concentration and type of salts influenced crystal growth and morphology. High salt conditions (>400 mM LiCl or KCl) yielded tubular crystals, whereas low salt conditions (<300 mM LiCl, NaCl or KCl) led to formation of up to 10 µm large sheet-like crystals. The intermediate concentration gave a mixture of sheet-like and tubular crystals. In terms of resolution, sheets diffracted better than tubes. The sheet-like crystals used for 3D map reconstruction were obtained from a dialysis buffer containing 200 mM NaCl combined with using C. glutamicum lipids. Electron microscopic images were taken from frozen-hydrated crystals using a helium-cooled JEOL 300 SFF microscope or a liquid nitrogen-cooled FEI Tecnai G2 microscope at 300 kV, which allowed optimal data collection and minimized radiation damage to the sample. More than 1000 images of tilt angles up to 50° were taken and evaluated using optical diffraction of a laser beam. The best 200 images were processed with the MRC image processing software package, and 79 images from different tilt angles were merged to the final data set used for calculation of a 3D map at a planar resolution of 8 Å. The structure shows BetPdeltaC45 as a trimer with each monomer consisting of 12 transmembrane alpha-helices. Protein termini and loop regions could not be determined due to the limited resolution of the map. Six of the twelve helices line a central cavity forming a potential substrate-binding chamber. Each monomer shows a central cavity in different sizes and shapes. Thus, the constitutively active BetPdeltaC45 thus forms an unusual asymmetric homotrimer. BetP most likely reflects three different conformational states of secondary transporters: the cytoplasmically open (C), the occluded (O), and the periplasmically open (P) states. The C and O states are similar to BetP WT projection structure, while the P state is discrepant and highly flexible due to the shape and size of the central cavity as well as the lowest intensity of the density. The observation of the P state corresponds well to the constitutively active property of BetPdeltaC45. For the high resolution structure of the C and O states are available, this work presents the first structural information of the P state of a secondary transporter.
The research presented in this thesis characterizes U2AF homology motifs (UHM) and their interactions with UHM ligand motifs (ULM) in the context of splicing regulation. UHM domains are a subgroup of RNA recognition motifs (RRM) originally discovered in the proteins U2AF65 and U2AF35. Whereas canonical RRMs are usually involved in binding of RNA, UHM domains bind tryptophan containing linear protein motifs (ULM) instead. In the first article, we analyze the complex network of interactions between splicing factors and RNA that initiate the assembly of the spliceosome at the 3´ splice site of an intron. The protein U2AF65 binds a pyrimidine-rich element in introns and recruits U2snRNP by binding its protein component SF3b155. My contribution was to define the binding site of the protein U2AF65 to the intrinsically unstructured N-terminus of the scaffolding protein SF3b155. I could show that the UHM domain of U2AF65 recognizes a ULM in SF3b155, and that this binding site is not overlapping with the binding sites of other splicing factors, like p14, to SF3b155. As the U2AF65-UHM:SF3b155-ULM interaction is mutually exclusive with an interaction between U2AF65-UHM and a ULM in the splicing factor SF1, which was reported to initially recognize the branch point sequence, my results provide the molecular details on how SF3b155 replaces SF1 during spliceosomal reorganizations. In the second article, we show that overexpression of the UHM domain of the splicing factor SPF45 induces exon 6 skipping in the pre-mRNA of Fas (CD95/APO-1). I provide evidence for in vitro binding of SPF45-UHM to ULM sequences in the splicing factors U2AF65, SF1, and SF3b155. I crystallized free and SF3b155-bound SPF45 UHM and solved both structures by X-ray crystallography. The analysis of the complex interface and sequence differences in the ULMs allowed me to design mutations of SPF45-UHM, which selectively inhibit binding to distinct ULMs. After assessing the ULM binding properties in vitro, we could show that the activity of SPF45-UHM in influencing the splicing pattern of Fas relies on interactions with SF3b155 and/or SF1, but that an interaction with U2AF65 is dispensable. A mechanism for the activity of SPF45-UHM could thus be engaging in ULM interactions and thus interfering with the network of interactions that initiate the assembly of the spliceosome at the 3´splice site, as described above. In the third article, we describe an unusual flexible homodimerization mode of the UHM in the splicing factor Puf60, which enables simultaneous interactions with ULM sequences on other splicing factors. I could show that the NMR relaxation properties of Puf60-UHM are inconsistent with a model of a rigid dimer, but rather indicate a dimerization via a flexible linker. I identified a flexible loop in the peptide backbone of Puf60-UHM, and showed that mutiation of acidic residues in this loop impairs the dimerization. To analyze the dimerization interface in further detail, I solved the structure of Puf60-UHM by X-ray crystallography. The acidic residues in the flexible loop of one UHM dimer subunit mediate the dimerization by contacting basic residues on the β-sheet surface of the other dimer subunit. Differences in the four dimer interfaces observed for the eight molecules in the asymmetric unit of the crystal support the model of an undescribed, flexible mode of dimerization, and thus complement the NMR relaxation data. Furthermore, I could show that the Puf60-UHM dimer and U2AF65-UHM contact different ULM sequences on the SF3b155 N-terminus in vitro, thus providing a possible explanation for the mutual cooperative activation of Puf60 and U2AF65 in splicing assays described in the literature. The fourth article is a review about recent research on the recognition of DNA double strand breaks (DSB) by covalent histone modifications. The p53 binding protein 1 (53BP1) is a DSB sensor and a checkpoint protein for mitosis. Recent crystallographic evidence indicates that 53BP1 recognizes DSB sites by binding histone H4 dimetylated at lysine 20 (H4-K20). We provide a comprehensive overview of the atomic resolution structures that revealed how proteins can specifically recognize histone tail modifications, especially methylated lysines, to read the information stored in what is called the histone code.
The focus of this thesis has been to further advance and develop existing NMR techniques for the study of protein folding. In order to do so, experimental as well as theoretical approaches have been pursued. From the theoretical side, a successful attempt to the development of a general theory for the treatment of residual dipolar couplings in the case of unfolded proteins has been undertaken. Information contained in residual dipolar couplings is especially valuable due to its long-range nature. The dynamic character of unfolded states of proteins, which may be composed of distinct subsets of conformations, renders reliable interpretation of data a non-trivial task. Statistical-coil-based approaches have been shown to be powerful in data interpretation. A consistent theory based on fundamental polymer physics, however, had not been presented so far. The herein presented model addresses this problem building on the original work by Annila and co-workers. In this work, several shortcomings have been identified. These shortcomings have been corrected here leading to a general approach for the treatment of residual dipolar couplings of unfolded proteins. More specifically, it is shown that, in the case of fully unfolded proteins aligned by a steric mechanism, basic dependencies of dipolar couplings such as on chain length and location with in the chain can be analysed in simple analytical terms. The main predictions of the model are compared to experimental data showing reasonable agreement. The presented mathematical framework is principally suited for various improvements which could include the treatment of long-range interactions and of the actual geometry of the given aligment medium. From the experimental side, bovine alpha-lactalbumin has been chosen as a model system for the development of improved time-resolved 1D NMR methods aiming at the observation of conformational transitions by kinetic means. The presented results show that high-quality data can now be obtained at protein concentrations as low as 100uM. Rate constants characterising distinct conformational transitions of up to 8/s have been measured. These are the fastest rate constants which have been reported so far for protein folding events. The NMR data supplemented by complementary biophysical data furthermore demonstrate that the folding of bovine alpha-lactalbumin is more complex than has been anticipated. All data are consistent with a triangular folding mechanism involving parallel pathways of folding for formation of the native state of the protein. Interestingly, such a folding mechanism has also been found for the highly structurally homologous protein lysoyzme from hen egg white. Evidence is presented that the guiding role of long-range interactions in the unfolded state of lysoyzme for mediating intersubdomain interactions during folding is replaced in the case of bovine alpha-lactalbumin by the Ca2+ binding site.
Life-threatening fungal infections are becoming increasingly common for immunocompromised patients such as those with AIDS, or those undergoing organ transplantation or chemotheraphy, as well as for other health-vulnerable patients. Excellent targets for antifungal drugs are chitin synthases, which are essential for survival of the fungus and lacking in humans. To design new antifungal drugs, knowledge of the three-dimensional structure and mechanism of action of chitin synthases are crucial. Chitin synthases are members of an important family of enzymes that synthesize structural polysaccharides, such as cellulose, β(1,3)-glucan, β(1,4)-mannan and hyaluronan. Therefore, chitin synthases could be used as a model system to understand these more complex enzymes, which are also of major medical and commercial importance. Chitin synthase 2 from Saccharomyces cerevisiae (ScChS2), the protein under study, is an integral membrane protein that synthesizes the primary septum between mother and daughter cells in budding yeast. It is essential for proper cell separation and expected to be highly regulated. An important aspect is that ScChS2 shows 55% sequence identity and is functionally analogous to chitin synthase 1 from the human opportunistic pathogen Candida albicans, this enzyme is also essential for cell survival (Munro, Winter et al. 2001). ...
The shortage of functional information compared to the abundance of sequence information characterizes today’s situation in functional genomics. For many years the knock-down of a gene’s product has been the most powerful way of analysing its function. In addition to the complete knock-out by homologous recombination, several different techniques have been developed to temporarily knock down gene expression through methods based on specific sequence recognition, such as knockdown by antisense oligonucleotides, ribozymes, aptamers or RNAi.
The ESF workshop on ‘Impact of Nucleic Acid Chemistry on Gene Function Analysis’ brought together researchers who use techniques that are different but highly related. It offered an opportunity for an in-depth discussion of recent progress and common problems. Antisense oligonucleotides aptamers and ribozymes are techniques that have been used successfully for many years to validate targets. However, recent developments, such as increased tightness of binding (e.g. locked nucleic acids) or the combination of different methods (e.g. using aptamers to design ribozymes), have continued to improve the existing techniques. RNA interference (RNAi) is a defence mechanism of the cell against viruses. Since the exact mechanism of action within the cell is still unclear, RNAi was a particularly exciting topic at the workshop and was addressed in the largest number of presentations. Predictability of positional effects (accessibility of RNA) is a problem shared by all techniques using sequence-specific recognition and was the subject of quite controversial debates.
The meeting comprised over 50 people from 14 countries (13 European countries and the USA).
A mild synthetic method for N-formyl-Met-Leu-Phe-OH (1) is described. After Fmoc solid phase peptide synthesis, on-bead formylation and HPLC purification, more than 30 mg of the fully 13C/15N-labelled tripeptide 1 could be isolated in a typical batch. This peptide can be easily crystallised and is therefore well suited as a standard sample for setting up solid-state NMR experiments.
Self-inactivating gammaretroviral vectors for the gene therapy of chronic granulomatous disease
(2008)
Chronic granulomatous disease (CGD) is a rare inherited primary immunodeficiency characterized by defective intracellular oxidative killing of ingested invading microbes by PMN and monocytes. It is caused by mutations in one of the four genes coding for the essential subunits of the NADPH oxidase (gp91phox, p47phox, p67phox and p22phox). Approximately 75% of the CGD cases are due to mutations in the gp91phox gene. If regular care and conventional therapy fail, the recommended therapy is allogeneic bone marrow transplantation (BMT), but only if a matched donor is available. A therapeutic option for patients lacking suitable donors is the genetic modification of autologous hematopoietic stem cells. The gene therapy offers an interesting alternative to BMT since it implies a less invasive treatment and represents a possibly unique curative option for patients with no suitable donor. Gammaretroviral vectors were already used in some gene therapy trials for CGD and other immunodeficiencies showing relevant clinical benefit. However, these trials uncovered an unexpected mutagenic side effect. If the retrovial integration ocurrs near to, or into proto-oncogenes this might lead to clonal dominance or even malignant transformation (Hacein-Bey-Abina et al., 2003a; Ott et al., 2006). Therefore, there was a need to further improve the safety of these vectors and to this end the self-inactivating gammaretroviral vectors were engineered. Non essential sequences for virus infectivity and integration, which might influence the surrounding gene expression, were deleted in these vectors. In the first set of experiments, a series of SIN gamma retroviral vectors was cloned driving the expression of the wild-type gp91phox cDNA under the control of a viral constitutive SFFV promoter. However initial studies with these vectors failed because the titers of the virus produced by transient transfection protocols were extremely low (<5x105 TU/ml). Therefore, a codon optimization of the gp91phox cDNA was considered as an alternative. The codon optimized synthetic gp91phox gene was used to construct a SIN gammaretroviral vector, again under the control of the SFFV promoter (Schambach et al., 2006c). With this vector an increase in titer was observed compared to the native gp91phox sequence, which was due to the improved transcription in 293T transfected cells. The enhancement of the synthetic gp91phox transcription led to a higher internal transcript production and protein expression. An enhanced superoxide production in transduced myelomonocytic X-CGD PLB-985 populations was also detected. All these data indicate that the synthetic gp91phox might represent an excellent alternative to those former constructs expressing the native gp91phox transgene. Since it was postulated that the SFFV promoter could still cause transactivation of neighboring genes due to its strength (Modlich et al., 2006), three different non-viral promoters were tested, one constitutive (the EFs promoter) and two myeloid-specific promoters (the c-fes and MRP8 promoter). The three SIN gammaretroviral vectors were able to generate high titers after transient transfection of 293T packaging cells, to efficiently transduce the X-CGD PLB-985 cell line and to reconstitute the NADPH oxidase activity to a high degree. In mouse transplantation experiments, the EFs promoter showed a high variable transgene expression in the different lineages analyzed, and the c-fes promoter showed also a ubiquitinous expression. In contrast, the MRP8 promoter showed a high myeloid specificity since gp91phox expression in mSca-1+ cells and lymphoid B cells from transplanted mice was extremly low and even absent. However, the lowest levels of transgene expression were observed in the myeloid populations both in bone marrow and peripheral blood with this vector. When the oxidase reconstitution ability of these promoters was tested, the numbers of superoxide producing cells obtained were similar than those observed in the clinical X-CGD trial conducted by the groups of Dr. M. Grez and Prof. R. A. Seger (over 35% in one patient and ~15% in the second), which led to the eradication of therapy refractory infections (Ott et al., 2006). Between the three constructs, the MRP8 promoter was less effective in restoring the NADPH oxidase activity than the EFs and c-fes promoters. The c-fes promoter reached the highest levels of DHR reactive cells in the highest number of mice. Overall, these data showed that between all constructs tested, the c-fes containing construct in combination with the codon optimized gp91phox sequence showed the best performance within the SIN gammaretroviral backbone. It generated the highest titers in combination with a better NADPH oxidase reconstituting ability. One main goal in the development of SIN gammaretroviral vectors is reducing the genotoxic effect due to random vector integration. An improved gene transfer and expression, and a constant performance are also highly desirable. The present study shows that the c-fes SIN vector in combination with the synthetic gp91phox may be considered as an effective gene therapy strategy for the restoration of the NADPH oxidase activity in CGD. It allows the use of a cellular promoter generating adequate physiological levels of the therapeutic protein and reduces the number of vector copies required for a therapeutic effect.
Development of chromium(VI)-free defect etching solutions for application on silicon substrates
(2008)
Determination of the distribution of halocarbons in the tropical upper troposphere and stratosphere
(2008)
The aim of this thesis was to investigate distributions of 32 volatile chlorinated and/or brominated halocarbons that are currently believed to be present in the tropical upper troposphere and stratosphere and to contribute to stratospheric ozone depletion and also to global warming. For this purpose an analytical system was established, which is capable to measure ultra-low concentrated atmospheric trace gases. A quadrupole Mass Spectrometric (MS) Detector was attached to an existing Gas Chromatograph with pre-concentration system and Electron Capture Detector (ECD). The characterisation of the chromatographic system was significantly enhanced by the subsequent identification of 48 additional volatile organic compounds. Furthermore a Gaussian fit algorithm, which was developed in the workgroup, was applied to the chromatographic signals. This algorithm was proven to reflect peaks quantitatively and to enhance the performance of the integration process – especially the reproducibilities for peaks with a low signal to noise ratio. As it is known that the Electron Capture Detector responds nonlinear the new MS detector was checked for such behaviour and found to respond linear. In logical consistency the complete quantification process including e.g. pre-concentration of trace gases and signal integration can be considered as linear responding within the investigated parameter ranges. Moreover, the long term stability of the targeted halocarbons was proven inside the calibration standard containers over a period of 25 months. Many substances were also found to be stable inside the containers used for storage of air samples but a number of substances showed significant concentration changes. These were mainly CH3Cl (methyl chloride), CH3Br (methyl bromide), CH2Cl2 (dichloromethane), CHCl3 (chloroform), CCl4 (tetrachloromethane), C2Cl4 (tetrachloroethene), CH3CCl3 (methyl chloroform), CH2ClCH2Cl (1,2-dichloroethane) und C2H5Cl (chloroethane). But the number of affected substances and also the corresponding concentration changes varied between the individual containers. A systematic investigation of the influence of possible causes (e.g. air sampling methods, container materials) is recommended. Results from both internal detectors were compared and revealed biases and disadvantages of the ECD caused by its lower selectivity and its nonlinear response behaviour. Consequently the MS detector was chosen for the quantification of atmospheric trace gases. The quantification process was performed relative to externally calibrated air standards. To assess the uncertainties connected with different absolute calibration scales cross-comparisons between calibration standards of three different laboratories were carried out. Most substances’ calibrations agreed within the measurement uncertainties but significant differences were observed for CF2ClBr (H1211), CH3Cl (methyl chloride), CH2Cl2 (dichloromethane), CHCl3 (chloroform), CCl4 (tetrachloromethane) and CH3CCl3 (methyl chloroform). As five of these substances were also observed to show concentration changes inside sample containers it is likely, that such changes are responsible for calibration differences. In addition to the detailed assessment of uncertainties connected with the analytical quantification process a set of air samples was available for measurements. These samples mainly originated from the upper troposphere and lower and middle stratosphere in the tropics and the determined halocarbon quantities were used to investigate their distributions in the respective atmospheric regions. In detail, the altitudinal distributions and interrelations of 17 long-lived halocarbons in the tropical stratosphere were determined and compared with those of other stratospheric regions. Tracer-tracer-correlations of these substances in the tropical stratosphere were found to differ from those in mid- and high-latitudes. Characteristic fit functions relative to CF2Cl2 (F12) which are valid for the tropical stratosphere in 2005 were derived as well as time-independent fit functions of fractional release factors (FRFs) relative to the mean age of air. Both sets of correlations could be used for the parameterisation and evaluation of models and also to reassess the Global Warming Potentials (GWPs) of the corresponding halocarbons which might affect future climate predictions. However, the data set on halocarbons in the tropical stratosphere is still insufficient to investigate the variability of tracer-tracer-correlations and FRFs caused by dynamical and photochemical processes. Therefore it is important for future research to perform additional measurements there and – if possible – to extend the measurements to the upper tropical stratosphere in order to characterise the sink of those halocarbons that are still present in these altitudes. In addition, the amount of chlorine and bromine present in the form of organic compounds inside and above the main stratospheric entrance region (the Tropical Tropopause Layer, TTL) was quantified in the frame of a case study. This was possible because of a cooperation with scientists from the University of East Anglia which carried out measurements of six additional halocarbons leading to a total of 28 quantified target substances. Ten of these substances have short atmospheric lifetimes compared with the mean transport times of tropospheric air to the stratosphere (i.e. lifetimes below 0.5 years) and show non-uniform distributions in the upper troposphere. The contribution of these substances to stratospheric ozone depletion is subject of an ongoing scientific debate. In the performed case study a fraction range of short-lived halocarbons of 6 – 8 % (0.98 – 1.25 ppt) relative to the sum of bromine from organic substances and of 1.1 – 1.4 % (36.6 – 47.1 ppt) for the corresponding sum of chlorine was calculated to enter the stratosphere above Brazil in June 2005. Moreover by combining the data with tropospheric reference data and age of air observations the abundances of inorganic chlorine and bromine (Cly and Bry) were derived. At an altitude of 34 km an amount of 3062 ppt of Cly and 17.5 ppt of Bry from organic source gases was calculated. The latter is significantly lower than Bry mixing ratios inferred from quasisimultaneous BrO measurements at 33 km altitude above Brazil (Dorf, 2005, Dorf et al., 2008). But at the University of East Anglia indications for the presence of unknown brominated organic substances in the TTL were found which might cause this difference. Finally, a major result of this thesis adds to the knowledge of the composition of the troposphere as three Chlorofluorocarbons (CFCs) were first observed. Trifluorochloroethene, 3-chloropentafluoropropene and 4,4-dichlorohexafluoro-1-butene were found in air samples collected at the Taunus Observatory near Frankfurt (Main) and the Jungfraujoch High Altitude Research Station in Switzerland (Laube and Engel, 2008). Identification was possible because of an air plume containing high concentrations of these substances. It is suggested that the abundances found on this occasion originated from a local source. The atmospheric lifetimes of these substances are expected to be rather short as they contain a double bond. A quantitative calibration could only be derived for trifluorochloroethene but not for the other species by now. Thus, a relative sensitivity method was derived to get a first indication of the observed atmospheric abundances. All three CFCs could also be detected in air masses representative of background conditions, though with much lower concentrations. These species and some of their degradation products are toxic and could also be relevant for stratospheric and tropospheric ozone depletion. It is important to find out more about their atmospheric distributions, lifetimes, sinks and sources and their ability to reach the stratosphere to assess their possible influence on the global atmosphere. This will be done in the frame of the project "CLEARFOGG – Checking Layers of the Earths AtmospheRe For halogenated Ozone-depleting and Greenhouse Gases". This research project aims to perform a systematic scan of the atmosphere because there are indications for the presence of a number of halogenated organic compounds which are unknown by now. It was recently decided to be funded by the British National Environmental Research Council and will be carried out at the University of East Anglia mainly by the author of this thesis.
Proteorhodopsin (PR) originally isolated from uncultivated γ-Proteobacterium as a result of biodiversity screens, is highly abundant ocean wide. PR, a Type I retinal binding protein with 26% sequence identity, is a bacterial homologue of Bacteriorhodopsin (BR). The members within this family share about 78% of sequence identity and display a 40 nm difference in the absorption spectra. This property of the PR family members provides an excellent model system for understanding the mechanism of spectral tuning. Functionally PR is a photoactive proton pump and is suggested to exhibit a pH dependent vectorality of proton transfer. This raises questions about its potential role as pH dependent regulator. The abundance of PR in huge numbers within the cell, its widespread distribution ocean wide at different depths hints towards the involvement of PR in utilization of solar energy, energy metabolism and carbon recycling in the Sea. Contrary to BR, which is known to be a natural 2D crystal, no such information is available for PR til date. Neither its functional mechanism nor its 3D structure has been resolved so far. This PhD project is an attempt to gain a deeper insight so as to understand structural and functional characterization of PR. The approach combines the potentials of 2D crystallography, Atomic Force Microscopy and Solid State NMR techniques for characterization of this protein. Wide range of crystalline conditions was obtained as a result of 2D crystallization screens. This hints towards dominant protein protein interactions. Considering the high number of PR molecules reported per cell, it is likely that driven by such interactions, the protein has a native dense packing in the environment. The projection map represented low resolution of these crystals but suggested a donut shape oligomeric arrangement of protein in a hexagonal lattice with unit cell size of 87Å*87Å. Preliminary FTIR measurements indicated that the crystalline environment does not obstruct the photocycle of PR and K as well as M intermediate states could be identified. Single molecule force spectroscopy and atomic force microscopy on these 2D crystals was used to probe further information about the oligomeric state and nature of unfolding. The data revealed that protein predominantly exists as hexamers in crystalline as well as densely reconstituted regions but a small percentage of pentamers is also observed. The unfolding mechanism was similar to the other relatively well-characterized members of rhodopsin family. A good correlation of the atomic force microscopy and the electron microscopy data was achieved. Solid State NMR of the isotopically labeled 2D crystalline preparations using uniformly and selectively labeling schemes, allowed to obtain high quality SSNMR spectra with typical 15N line width in the range of 0.6-1.2 ppm. The measured 15N chemical shift value of the Schiff base in the 2D crystalline form was observed to be similar to the Schiff base chemical shift values for the functionally active reconstituted samples. This provides an indirect evidence for the active functionality of the protein and hence the folding. The first 15N assignment has been achieved for the Tryptophan with the help of Rotational Echo Double Resonance experiments. The 2D Cross Polarization Lee Goldberg measurements reflect the dynamic state of the protein inspite of restricted mobility in the crystalline state. The behavior of lipids as measured by 31P from the lipid head group showed that the lipids are not tightly bound to the protein but behave more like the lipid bilayer. The 13C-13C homonulear correlation experiments with optimized mixing time based on build up curve analysis, suggest that it is possible to observe individual resonances as seen in case of glutamic acid. The signal to noise was good enough to record a decent spectrum in a feasible period. The selective unlabeling is an efficient method for reduction in the spectral overlap. However, more efficient labeling schemes are required for further characterization. The present spectral resolution is good for individual amino acid investigation but for uniformly labeled samples, further improvement is required.
Cellular metabolism can be envisaged by fluorescence lifetime imaging of fluorophores sensitive to specific intracellular factors such as [H+], [Ca2+], [O2], membrane potential, temperature, polarity of the probe environment, and alterations in the conformation and interactions of macromolecules. Lifetime measurements of the probes allow the quantitative determination of the intracellular factors. Fluorescence microscopy taking advantage of time-correlated single photon counting is a novel method that outperforms all other techniques with its single photon sensitivity and picoseconds time resolution. In this work, a time- and space-correlated single photon counting system was established to investigate the behavior of 2-(4-(dimethylamino)styryl)-1-methylpyridinium iodide (DASPMI) in living cells. DASPMI is known to selectively stain mitochondria in living cells. The uptake and fluorescence intensity of DASPMI in mitochondria is a dynamic measure of membrane potential. Hence, an endeavour was made to elucidate the mechanism of DASPMI fluorescence by obtaining spectrally-resolved fluorescence decays in different solvents. A bi-exponential decay model was sufficient to globally describe the wavelength dependent fluorescence in ethanol and chloroform. While in glycerol, a three-exponential decay model was necessary for global analysis. In the polar low-viscous solvent water, a mono-exponential decay model fitted the decay data. The sensitivity of DASPMI fluorescence to solvent viscosity was analysed using various proportions of glycerol/ethanol mixtures. The lifetimes were found to increase with increasing solvent viscosity. The negative amplitudes of the short lifetime component found in chloroform and glycerol at the longer wavelengths validated the formation of new excited state species from the initially excited state. Time-resolved emission spectra in chloroform and glycerol showed a biphasic increase of spectral width and emission maxima. The spectral width had an initial fast increase within 150 ps and a near constant thereafter. A two-state model based on solvation of the initially excited state and further formation of TICT state has been proposed to explain the excited state kinetics and has been substantiated by the de-composition of time-resolved spectra. The knowledge of DASPMI photophysics in a variety of solvents now provides the means of deducing complex physiological parameters of mitochondria from its behavior in living cells. Spatially-resolved fluorescence decays from single mitochondria or only very few organelles of XTH2 cells signified distinctive three-exponential decay kinetics of viscous environment. Based on DASPMI photophysics in a variety of solvents, these lifetimes have been attributed to the fluorescence from locally excited state (LE), intramolecular charge transfer state (ICT) and twisted intramolecular charge transfer (TICT) state. A considerable variation in lifetime among mitochondria of different morphology and within single cell was evident corresponding to the high physiological variations within single cells. Considerable shortening of the short lifetime component (τ1) under high membrane potential condition, such as in the presence of ATP and/or substrate, was similar to quenching and dramatic decrease of lifetime in polar solvents. Under these conditions τ2 and τ3 increased with decreasing contribution. Upon treatment with ionophore nigericin, hyperpolarization of mitochondria resulted in remarkable shortening of τ1 from 159 ps to 38 ps. Inhibiting respiration by cyanide resulted in notable increase of mean lifetime and decrease of mitochondrial fluorescence. Increase of DASPMI fluorescence on conditions elevating mitochondrial membrane potential has been attributed to uptake according Nernst distributions, to de-localisation of π electrons, quenching processes of the methyl pyridinium moiety and restricted torsional dynamics at the mitochondrial inner membrane. Accordingly, determination of anisotropy in DASPMI stained mitochondria in living XTH2 cells, revealed dependence of anisotropy on membrane potential. Such changes in anisotropy attributed to restriction of the torsional dynamics about the flexible single bonds neighboring the olefinic double bond revealed the previously known sub-mitochondrial zones with higher membrane potential along its length. Membrane-potential-dependent changes in anisotropy have further been demonstrated in senescent chick embryo fibroblasts. In conclusion, spectroscopic observations of excited-state kinetics of DASPMI in solvents and its behavior in living cells had revealed for the first time its localisation, mechanism of voltage sensitive fluorescence and its membrane-potential-dependent anisotropy in living cells. The simultaneous dependence of DASPMI photophysics on mitochondrial inner membrane viscosity and transmembrane potential has been highlighted.
In a combined NMR/MD study, the temperature-dependent changes in the conformation of two members of the RNA YNMG-tetraloop motif (cUUCGg and uCACGg) have been investigated at temperatures of 298, 317 and 325 K. The two members have considerable different thermal stability and biological functions. In order to address these differences, the combined NMR/MD study was performed. The large temperature range represents a challenge for both, NMR relaxation analysis (consistent choice of effective bond length and CSA parameter) and all-atom MD simulation with explicit solvent (necessity to rescale the temperature). A convincing agreement of experiment and theory is found. Employing a principle component analysis of the MD trajectories, the conformational distribution of both hairpins at various temperatures is investigated. The ground state conformation and dynamics of the two tetraloops are indeed found to be very similar. Furthermore, both systems are initially destabilized by a loss of the stacking interactions between the first and the third nucleobase in the loop region. While the global fold is still preserved, this initiation of unfolding is already observed at 317 K for the uCACGg hairpin but at a significantly higher temperature for the cUUCGg hairpin.
A high-precision pressure probe is described which allows non-invasive online-monitoring of the water relations of intact leaves. Real-time recording of the leaf water status occurred by data transfer to an Internet server. The leaf patch clamp pressure probe measures the attenuated pressure, Pp, of a leaf patch in response to a constant clamp pressure, Pclamp. Pp is sensed by a miniaturized silicone pressure sensor integrated into the device. The magnitude of Pp is dictated by the transfer function of the leaf, Tf, which is a function of leaf patch volume and ultimately of cell turgor pressure, Pc, as shown theoretically. The power function Tf=f(Pc) theoretically derived was experimentally confirmed by concomitant Pp and Pc measurements on intact leaflets of the liana Tetrastigma voinierianum under greenhouse conditions. Simultaneous Pp recordings on leaflets up to 10 m height above ground demonstrated that changes in Tf induced by Pc changes due to changes of microclimate and/or of the irrigation regime were sensitively reflected in corresponding changes of Pp. Analysis of the data show that transpirational water loss during the morning hours was associated with a transient rise in turgor pressure gradients within the leaflets. Subsequent recovery of turgescence during the afternoon was much faster than the preceding transpiration-induced water loss if the plants were well irrigated. Our data show the enormous potential of the leaf patch clamp pressure probe for leaf water studies including unravelling of the hydraulic communication between neighbouring leaves and over long distances within tall plants (trees).
C2-symmetric bisamidines : chiral Brønsted bases catalysing the Diels-Alder reaction of anthrones
(2008)
C2-symmetric bisamidines 8 have been tested as chiral Brønsted bases in the Diels- Alder reaction of anthrones and N-substituted maleimides. High yields of cycloadducts and significant asymmetric inductions up to 76% ee are accessible. The proposed mechanism involves proton transfer between anthrone and bisamidine, association of the resulting ions and finally a cycloaddition step stereoselectively controlled by the chiral ion pair.
Cytotoxic T-lymphocytes play an important role in the protection against viral infections, which they detect through the recognition of virus-derived peptides, presented in the context of MHC class I molecules at the surface of the infected cell. The transporter associated with antigen processing (TAP) plays an essential role in MHC class I–restricted antigen presentation, as TAP imports peptides into the ER, where peptide loading of MHC class I molecules takes place. In this study, the UL49.5 proteins of the varicelloviruses bovine herpesvirus 1 (BHV-1), pseudorabies virus (PRV), and equine herpesvirus 1 and 4 (EHV-1 and EHV-4) are characterized as members of a novel class of viral immune evasion proteins. These UL49.5 proteins interfere with MHC class I antigen presentation by blocking the supply of antigenic peptides through inhibition of TAP. BHV-1, PRV, and EHV-1 recombinant viruses lacking UL49.5 no longer interfere with peptide transport. Combined with the observation that the individually expressed UL49.5 proteins block TAP as well, these data indicate that UL49.5 is the viral factor that is both necessary and sufficient to abolish TAP function during productive infection by these viruses. The mechanisms through which the UL49.5 proteins of BHV-1, PRV, EHV-1, and EHV-4 block TAP exhibit surprising diversity. BHV-1 UL49.5 targets TAP for proteasomal degradation, whereas EHV-1 and EHV-4 UL49.5 interfere with the binding of ATP to TAP. In contrast, TAP stability and ATP recruitment are not affected by PRV UL49.5, although it has the capacity to arrest the peptide transporter in a translocation-incompetent state, a property shared with the BHV-1 and EHV-1 UL49.5. Taken together, these results classify the UL49.5 gene products of BHV-1, PRV, EHV-1, and EHV-4 as members of a novel family of viral immune evasion proteins, inhibiting TAP through a variety of mechanisms.
The degradation of the poly(A) tail is crucial for posttranscriptional gene regulation and for quality control of mRNA. Poly(A)-specific ribonuclease (PARN) is one of the major mammalian 3’ specific exo-ribonucleases involved in the degradation of the mRNA poly(A) tail, and it is also involved in the regulation of translation in early embryonic development. The interaction between PARN and the m7GpppG cap of mRNA plays a key role in stimulating the rate of deadenylation. Here we report the solution structures of the cap-binding domain of mouse PARN with and without the m7GpppG cap analog. The structure of the cap-binding domain adopts the RNA recognition motif (RRM) with a characteristic a-helical extension at its C-terminus, which covers the b-sheet surface (hereafter referred to as PARN RRM). In the complex structure of PARN RRM with the cap analog, the base of the N7-methyl guanosine (m7G) of the cap analog stacks with the solvent-exposed aromatic side chain of the distinctive tryptophan residue 468, located at the C-terminal end of the second b-strand. These unique structural features in PARN RRM reveal a novel cap-binding mode, which is distinct from the nucleotide recognition mode of the canonical RRM domains.
Pulsed electron-electron double resonance (PELDOR) is a well established method concerning nanometer distance measurements involving two nitroxide spin-labels. In this thesis the applicability of this method to count the number of spins is tested. Furthermore, this work explored the limits, up to which PELDOR data obtained on copper(II)-nitroxide complexes can be quantitatively interpreted. Spin counting provides access to oligomerization studies – monitoring the assembly of homo- or hetero-oligomers from singly labeled compounds. The experimental calibration was performed using model systems, which contain one to four nitroxide radicals. The results show that monomers, dimers, trimers, and tetramers can be distinguished within an error of 5% in the number of spins. Moreover, a detailed analysis of the distance distributions in model complexes revealed that more than one distance can be extracted from complexes bearing several spins, as for example three different distances were resolved in a model tetramer – the other three possible distances being symmetry related. Furthermore, systems exhibiting mixtures of oligomeric states complicate the analysis of the data, because the average number of spin centers contributes nonlinearly to the signal and different relaxation behavior of the oligomers has to be treated explicitly. Experiments solving these problems are proposed in the thesis. Thus, for the first time spin counting has been experimentally calibrated using fully characterized test systems bearing up to four spins. Moreover, the behavior of mixtures was quantitatively interpreted. In addition, it has been shown that several spin-spin distances within a molecule can be extracted from a single dataset. In the second part of the thesis PELDOR experiments on a spin-labeled copper(II)-porphyrin have been quantitatively analyzed. Metal-nitroxide distance measurements are a valuable tool for the triangulation of paramagnetic metal ions. Therefore, X-band PELDOR experiments at different frequencies have been performed. The data exhibits only weak orientation selection, but a fast damping of the oscillation. The experimental data has been interpreted based upon quantitative simulations. The influence of orientation selection, conformational flexibility, spin-density distribution, exchange interaction J, as well as anisotropy and strains of the g-tensor has been examined. An estimate of the spin-density delocalization has been obtained by density functional theory calculations. The dipolar interaction tensor was calculated from the point-charge model, the extension of the point-dipole approximation to several spin bearing centers. Even assuming asymmetric spin distributions induced by an ensemble of asymmetrically distorted porphyrins the effect of delocalization on the PELDOR time trace is weak. The observed damping of dipolar oscillations has been only reproduced by simulations, if a small distribution in J was assumed. It has been shown that the experimental damping of dipolar modulations is not solely due to conformational heterogeneity. In conclusion the quantitative interpretation of PELDOR data is extended to copper-nitroxide- and multi-spin-systems. The influence of the mean distance, of the number of coupled spins, of the conformational flexibility, of spin-density distribution and of the electronic structure of the spin centers has been analyzed using model systems. The insights on model compounds mimicking spin-labeled biomacromolecules – in oligomeric or metal bound states – calibrate the method with respect to the information that can be deduced from the experimental data. The resulting in-depth understanding allows correlating experimental results (from for example biological systems) with models of structure and dynamics. It also opens new fields for PELDOR as for example triangulation of metal centers and oligomerization studies. In general, this thesis has demonstrated that modern pulsed electron paramagnetic resonance techniques in combination with quantitative data analysis can contribute to a detailed insight into molecular structure and dynamics.
Antibiotic resistance of pathogenic bacteria is a major worldwide problem. Bacteria can resist antibiotics by active efflux due to multidrug efflux pumps. The focus of this study has been the mycobacterial multidrug transporter TBsmr because it belongs to the small multidrug resistance (SMR) family whose members are a paradigm to study multidrug efflux due to their small size. SMR proteins are typically 11-12 kDa in size and have a four-transmembrane helix topology. They bind cationic, lipophilic antibiotics such as ethidium bromide (EtBr) and TPP+, and transport them across the membrane in exchange for protons. To understand the molecular mechanism of multidrug resistance, we have to gain information about the structure and function of these proteins. The research described in this thesis aimed to deduce details about the topology, transport cycle and key residues of TBsmr using biophysical techniques. Solid-state NMR (ssNMR) can provide detailed insight into structural organization and dynamical properties of these systems. However, a major bottleneck is the preparation of mg amounts of isotope labeled protein. In case of proteoliposomes, the problem is compounded by the presence of lipids which have to fit into the small active volume of the ssNMR rotor. In Chapter 3, an enhanced protein preparation is described which yields large amounts of TBsmr reconstituted in a native lipid environment suitable for further functional and structual studies. The achieved high protein-to-lipid ratios made a further characterization by ssNMR feasible. The transport activity and oligomeric state of the reconstituted protein in different types of lipid was studied as shown in Chapter 4. The exact oligomeric state of native SMR proteins is still uncertain but a number of biochemical and biophysical studies in detergent suggest that the minimal functional unit capable of binding substrate is a dimer. However, binding assays are not ideal since a protein may bind substrate without completing the transport cycle which can only be shown for reconstituted protein in transport assays.By combining functional data of a TPP+ transport assay with information about theoligomeric state of reconstituted TBsmr obtained by freeze-fracture electron microscopy, it could be shown that lipids affect the function and the oligomeric state of the protein, and that the TBsmr dimer is the minimal functional unit necessary for transport. The transport cycle must involve various conformational states of the protein needed for substrate binding, translocation and release. A fluorescent substrate will therefore experience a significant change of environment while being transported, which influences its fluorescence properties. Thus the substrate itself can report intermediate states that form during the transport cycle. In Chapter 5, the existence of such a substrate-transporter complex for the TBsmr and its substrate EtBr could be shown. The pH gradient needed for antiport has been generated by co-reconstituting TBsmr with bacteriorhodopsin. The measurements have shown the formation of a pH-dependant, transient substrate-protein complex between binding and release of EtBr. This state was further characterized by determining the Kd, by inhibiting EtBr transport through titration with non-fluorescent substrate and by fluorescence anisotropy measurements. The findings support a model with a single occluded intermediate state in which the substrate is highly immobile. Liquid-state NMR is a useful tool to monitor protein-ligand interactions by chemical shift mapping and thus identify and characterize important residues in the protein which are involved in substrate binding. In agreement with previous studies (Krueger-Koplin et al., 2004), the detergent LPPG was found to be highly suitable for liquid-state NMR studies of the membrane protein TBsmr and 42% of the residues could be assigned, as reported in Chapter 6. However, no specific interactions with EtBr were found. This observation was confirmed by LILBID mass spectrometry which showed that TBsmr was predominantly in the non-functional monomeric state. Functional protein was prepared in proteoliposomes which can be investigated by solidstate NMR (Chapter 7). Besides the essential E13, the aromatic residues W63, Y40, and Y60 have been shown to be directly involved in drug binding and transport. Different isotope labeling strategies were evaluated to improve the quality of the NMR spectra to identify and characterize these key residues. In a single tryptophan mutant of reconstituted TBsmr W30A, the binding of ethidium bromide could be detected by 13C solid-state NMR. The measurements have revealed two populations of the conserved W63 residue with distinct backbone structures in the presence of substrate. There is a controversy about the parallel or anti-parallel arrangement of the protomers in the EmrE dimer (Schuldiner, 2007) but this structural asymmetry is consistent with both a parallel and anti-parallel topology.
Poster presentation In pharmaceutical research and drug development, machine learning methods play an important role in virtual screening and ADME/Tox prediction. For the application of such methods, a formal measure of similarity between molecules is essential. Such a measure, in turn, depends on the underlying molecular representation. Input samples have traditionally been modeled as vectors. Consequently, molecules are represented to machine learning algorithms in a vectorized form using molecular descriptors. While this approach is straightforward, it has its shortcomings. Amongst others, the interpretation of the learned model can be difficult, e.g. when using fingerprints or hashing. Structured representations of the input constitute an alternative to vector based representations, a trend in machine learning over the last years. For molecules, there is a rich choice of such representations. Popular examples include the molecular graph, molecular shape and the electrostatic field. We have developed a molecular similarity measure defined directly on the (annotated) molecular graph, a long-standing established topological model for molecules. It is based on the concepts of optimal atom assignments and iterative graph similarity. In the latter, two atoms are considered similar if their neighbors are similar. This recursive definition leads to a non-linear system of equations. We show how to iteratively solve these equations and give bounds on the computational complexity of the procedure. Advantages of our similarity measure include interpretability (atoms of two molecules are assigned to each other, each pair with a score expressing local similarity; this can be visualized to show similar regions of two molecules and the degree of their similarity) and the possibility to introduce knowledge about the target where available. We retrospectively tested our similarity measure using support vector machines for virtual screening on several pharmaceutical and toxicological datasets, with encouraging results. Prospective studies are under way.
Colorectal cancer is one of the most cause of cancer and death in Western societies. Recently, histone deacetylase inhibitors (HDIs), which regulate transcription through modification of chromatin structure, received considerable interest on the ground of they ability to stop the growth and induce cell death in colon cancer tumours, representing a promising transcriptional cancer therapy. This kind of cancer initiates with an activating mutation in the Wnt cascade, allowing the nuclear import of ß-catenin binding to LEF/TCF. This induces the overexpression of growthpromoting oncogenes affecting the cell cycle arrest, lineage-specific cell differentiation and apoptosis processes. In addition, ß-catenin also participates in cell-cell adhesion via interactions with E-cadherin, which can be repressed by families of transcription factors Snail and ZEB. This, and gain of vimentin has been closely correlated with local invasion and metastasis since they avoid the induction of apoptosis through the loss of cell anchorage, a phenomenon called anoikis. In this process the inactivation of the kinases Src an FAK provoking disruption of focal adhesion complexes through is involved. LAQ824 is a HDAC inhibitor derivative of hydroxamic acid, which present antitumor effect in colon and other cancer cells. The aim of this study is to analyse the effect of LAQ824 in cell proliferation, apoptosis, motility and tumour invasion in a colon carcinoma model based on the adenoma-carcinoma sequence descrying trough which pathways LAQ824 is able to cause these effects. Here I demonstrate for the first time that a HDAC inhibitor, LAQ824, induces detachmentinduced cell death of colon cancer cell lines HCT116 and HT-29, a phenomenon called anoikis, in a caspase-dependent and p53-independent manner. In this process the component of the Wnt signalling pathway ß-catenin is involved. Furthermore LAQ824 upregulates the adhesion molecule E-cadherin expression in these cell lines independently of its repressor Snail, but probably mediated by the repressor ZEB. In addition LAQ824-induced anoikis is caused by disruption of focal adhesion complexes through inhibition of the activity of the kinases FAK and Src inhibiting cell motility indicating a strong antimetastatic potential for LAQ824.