Biochemie und Chemie
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The effect of NNMG on the template activities of different polynucleotides (polyuridylic acid, polycytidylic acid, polyadenylic acid and copolymer of adenylic and guanylic acid 5,5:1) and t-RNS was studied. The maximum inhibition of the messenger activity was found for poly-C, followed by poly-Α and poly-U. The acceptor activity of t-RNA was found to be inhibited by NNMG: maximum for proline, followed by serine, leucine, phenylalanine and lysine. The mechanism of these inhibitions was studied using NNMG radioactively labelled on the methyl group. Different amounts of radioactivity were found in the various polynucleotides and t-RNS.
The P300/CBP-associated factor plays a central role in retroviral infection and cancer development, and the C-terminal bromodomain provides an opportunity for selective targeting. Here, we report several new classes of acetyl-lysine mimetic ligands ranging from mM to low micromolar affinity that were identified using fragment screening approaches. The binding modes of the most attractive fragments were determined using high resolution crystal structures providing chemical starting points and structural models for the development of potent and selective PCAF inhibitors.
Structural determinants for substrate specificity of the promiscuous multidrug efflux pump AcrB
(2013)
Opportunistic Gram-negative pathogens such as Escherichia coli, Klebsiella pneumoniae, Acinetobacter Baumanii and Pseudomonas aeruginosa are becoming more and more multiresistant against many commonly available antibiotics [39, 40]. An important resistance mechanism of Gram-negative bacteria is the efflux of noxious compounds by tripartite systems [39, 41-44]. The best studied and most clinically relevant tripartite system is the AcrA-AcrB-TolC system of Escherichia coli, where substrate recognition and energy transduction takes place in the inner membrane protein AcrB. AcrB has a remarkably huge substrate spectrum and can recognize structurally diverse molecules, such as hexan in contrast to erythromycin, as its substrates [45]. Therefore, overproduction of the tripartite system can render a Gram-negative pathogen resistant against multiple antibiotics at once. The mechanisms of how AcrB is able to recognize such an enormous spectrum of molecules as substrates, without compromising its specificity (e.g. by neglecting essential compounds like lipids or gluclose as its susbtates), remained puzzling. Structural insight into substrate specificity was so far limited to two co-crystal structures of AcrB, where minocycline and doxorubicin, respectively, were identified bound to an internal binding pocket of AcrB. This binding pocket is particularly deeply buried into internal parts of the T monomer of AcrB and was, therefore, denoted deep binding pocket (DBP). Analysis of several AcrB co-crystal structures with substrate molecules bound to the DBP [4, 23, 25] indicated that the substrate promiscuity involved multisite binding modes within the DBP. Multisite binding modes, where different substrate molecules can bind to slightly different positions and orientations to the same binding pocket, is a common feature of multidrug recognizing proteins such as QacR or BmrR [27-29]. Nevertheless, AcrB's substrate spectrum is much broader than substrate spectra of most other multidrug recognizing proteins. Therefore, it is likely that additional mechanisms are involved in mediating the observed high substrate promiscuity of AcrB. In our recently published high-resolution AcrB/doxorubicin co-crystal structure (pdb entry: 4DX7 [23]) we were able to identify two additional substrate binding pockets in the L monomer of AcrB: i) the access pocket (AP), with an opening towards the periplasm, and ii) a putative binding site in a groove between transmembrane helices 8 and 9 (TM8/TM9 groove), accessible from the lipid layer of the inner membrane. Both binding pockets are likely to be access sites for substrates towards AcrB. Furthermore, each of the binding pockets are possibly specialized to recognize a specific subset of the entire substrate spectrum of AcrB, i.e. highly hydrophobic substrates (e.g. n-dodecyl-ß-d-maltoside or sodium dodecylsulfate) might access AcrB towards the TM8/TM9 groove and water soluble substrates (e.g. berberine) might access AcrB towards the AP. Since substrates will accumulate in the membrane or the periplasm according to their hydrophilic or hydrophobic nature, substrates will be "pre-selected" by the medium, rather than by the protein itself, and guided to their appropriate access site. This process is proposed to be called "medium- mediated pre-selection". The AcrB/doxorubicin co-crystal structure (pdb entry: 4DX7 [23]) furthermore revealed that the AP and DBP are in next neighborhood to each other and are separated by a switch loop. This switch loop adopts distinct conformations in the L, T and O monomers. Specific switch loop conformations are strongly involved in coordinating the selective occupation of both binding pockets, the AP and the DBP. The conformation of the switch loop in the L monomer (L-switch loop) opens the AP and closes the DBP, whereas the conformation of the switch loop in the T monomer (T-switch Loop) opens the DBP and closes the AP. An analysis of all asymmetric AcrB structures indicated that the L-switch loop is able to adopt multiple distinct conformations, whereas the conformation of T-switch loop remained largely congruent in all crystal structures. Moreover, each distinct switch loop conformation, observed in co-crystal structures of AcrB with occupied AP [4, 23], was perfectly adapted to the bound substrate molecule. Therefore, the putatively flexible switch loop is likely to act as an adaptive module and mediates a high binding pocket plasticity without altering the global protein structure. This binding mode is called adaptor-mediated binding mechanism, where an flexible adaptive module (like the switch loop) is able to adapt the surface shape of an binding pocket to different substrate molecules. Furthermore, structural and biochemical analyses of an AcrB G616N variant, revealed the involvement of specific switch loop conformations in the substrate specificity of AcrB. A substitution of G616, located on the switch loop, to N616 was able to alter the conformation of the switch loop exclusively in the L monomers of AcrB, whereas the switch loop conformations in T and O monomers remained congruent to the conformations observed in crystal structures of wildtype AcrB. Moreover, cells producing the AcrB G616N and MexB, both bearing the G616N amino acid substitution, exhibited a reduced resistance against certain substrates, whereas the resistance against most other substrates remained on the level of wildtype AcrB. Correlations of the phenotypes with minimal projection areas, a novel 2-spatiodimensional parameter which approximates the size of a substrate molecule, revealed that AcrB variants with a G616N substitution have a reduced efflux activity for exclusively large substrate molecules. The rejection of large substrates is most likely connected with altered L-switch loop conformations....
During the last decade of the 20th century, the field of mass spectrometry has seen a revolutionary change in its application and scope. The introduction of soft ionization methods for the analysis of biological molecules has expanded the area of mass spectrometry from its early roots in the analysis of inorganic and organic species into the fields of biology and medicine.
Today, the use of the mass spectrometry is extended to a wide range of applications in biotechnology and pharmaceutical industry, in geological, environmental and clinical research. In biochemistry, the principles of mass spectrometry are, however, broadly applicable in accurate molecular weight determination, reaction monitoring, amino acid sequencing, oligonucleotide sequencing and protein structure.
In order to carry out their biological activities, proteins interact most often to each other and form transient or stable complexes. In addition, some proteins specifically interact also with other proteins or with non-protein molecules, such as DNA, RNA or metabolites, these interactions being critical for their function. Hence, defining the composition of protein complexes, as well as understanding how protein complexes are assembled and regulated yield invaluable insights into protein function. Coupled with an isolation technique to purify a specific protein complex of interest, mass spectrometry can rapidly and reliably identify the components of complexes. In addition, quantitative MS techniques offer the possibility of studying dynamically regulated interactions....
In dieser Arbeit sollte die Bindung von Tetrahydromethanopterinderivaten an zwei Enzyme des methanogenen, CO2-reduzierenden Energiestoffwechselweges strukturell charakterisiert werden. In jenem Stoffwechselweg verläuft die schrittweise Reduktion von CO2 über die Bindung an den C1-Carrier Tetrahydromethanopterin (H4MPT), ein Tetrahydrofolat-Analogon, welches unter anderem in methanogenen Archaeen zu finden ist. Die thermophilen bzw. hyperthermophilen Ursprungsorganismen der untersuchten Enzyme, Methanothermobacter marburgensis, Methanocaldococcus jannaschii und Methanopyrus kandleri, sind aufgrund ihrer Anpassung an extreme Habitate durch spezielle genomische, strukturelle und enzymatische Eigenschaften von strukturbiologischem Interesse. Beim ersten in dieser Arbeit untersuchten Enzym handelte es sich um den aus acht Untereinheiten bestehenden membrangebundenen N5-Methyl-H4MPT:Coenzym M-Methyltransferasekomplex (MtrA-H). Dieser katalysiert in einem zweistufigen Mechanismus den Methyltransfer von H4MPT zum Co(I) der prosthetischen Gruppe 5’-Hydroxybenzimidazolylcobamid (Vitamin B12a), um die Methylgruppe dann auf Coenzym M zu übertragen. Gleichzeitig findet ein der Energiekonservierung dienender vektorieller Natriumtransport über die Membran statt. Für den Mtr-Komplex aus M. marburgensis (670 kDa) lag bereits ein Protokoll zur Reinigung unter anaeroben Bedingungen vor. Dieses wurde im Rahmen dieser Arbeit verbessert, für die Isolierung und Reinigung unter aeroben Bedingungen vereinfacht und für die Erfordernisse der zur Strukturbestimmung verwendeten elektronenmikroskopischen Einzelpartikelmessung optimiert. Neben der Präparation des kompletten Komplexes MtrA-H wurde als Alternative die Präparation des Enzymkomplexes MtrA-G unter möglichst vollständiger Abtrennung der hydrophilsten Untereinheit MtrH gewählt. Mit der zu diesem Zweck entwickelten Methode konnte das Abdissoziieren von MtrH besser als im etablierten Protokoll kontrolliert und somit die Homogenität der Probe deutlich verbessert werden. Dies schafft zum einen die Vorraussetzungen für eine Kristallisation zur Röntgenstrukturanalyse, zum anderen war auch in bei der elektronenmikroskopischen Einzelpartikelmessung erkennbar, dass mit dem Mtr-Komplex ohne MtrH bessere Ergebnisse zu erzielen sind. Parallel zu den Untersuchungen am Gesamtkomplex sollten die den Cobamid-Cofaktor bindende Untereinheit MtrA sowie die H4MPT-bindende Untereinheit MtrH in für die Kristallisation und röntgenkristallographische Untersuchung ausreichender Menge und Qualität gereinigt werden. Hierfür wurden MtrA und MtrH aus oben genannten Organismen für die heterologe Expression in E. coli kloniert, die Expressionsbedingungen optimiert und Reinigungsprotokolle etabliert. Anschließend wurden die Untereinheiten umfangreichen Kristallisationsversuchen unterzogen. Die Untereinheit MtrA aus M. jannaschii konnte ohne die C-terminale Transmembranhelix als lösliches Protein in E. coli produziert und als Holoprotein bis zur Homogenität gereinigt werden. Bei M. kandleri MtrA gelang die Herstellung von geringen Mengen teilweise löslichen StrepII-Fusionsproteins ohne C-terminale Transmembranhelix in E. coli. Eine Produktion der Untereinheit MtrH in E. coli als lösliches Protein war bei keiner der in dieser Arbeit getesteten Varianten möglich. Mit dem in Einschlusskörperchen exprimierten Protein aus M. marburgensis wurde eine Reinigung und Rückfaltung versucht. Auch eine Co-Expression der Untereinheiten MtrA und MtrH, durch welche eine bessere Faltung und Löslichkeit erreicht werden sollte, war nur in Einschlusskörperchen möglich. Das zweite in dieser Arbeit untersuchte Enzym, die F420 abhängige N5,N10 Methylen-H4MPT-Dehydrogenase (Mtd), katalysiert den reversiblen, stereospezifischen Hydrid-Transfer zwischen reduziertem F420 (F420H2) und Methenyl-H4MPT+, welches hierbei zu Methylen-H4MPT reduziert wird. Die Reaktion verläuft über einen ternären Komplex bestehend aus Protein, Substrat (Methylen-H4MPT) und Cosubstrat (F420), welcher strukturell charakterisiert werden sollte. Das gereinigte, rekombinante Enzym aus M. kandleri wurde mit verschiedenen H4MPT- und F420-Derivaten co-kristallisiert, die Struktur des ternären Komplexes röntgenkristallographisch bestimmt und die Bindung von H4MPT und F420 analysiert. Methenyl-H4MPT+ und F420H2 sind in der in dieser Arbeit gelösten Kristallstruktur in katalytisch aktiver Konformation gebunden, jedoch kann bei einer Auflösung von 1,8 Å nicht beurteilt werden, ob Methylen-H4MPT und F420 oder Methenyl-H4MPT+ und F420H2 vorlagen. Ein Vergleich mit der Struktur von M. kandleri-Mtd (KMtd) ohne Substrat und Cosubstrat ergab nur äußerst geringe Abweichungen in der Proteinkonformation, sodass sich KMtd überraschenderweise als Beispiel für ein Enzym mit ungewöhnlich starrer, vorgegebener Bindetasche erwies.
HER2 belongs to the ErbB sub-family of receptor tyrosine kinases and regulates cellular proliferation and growth. Different from other ErbB receptors, HER2 has no known ligand. Activation occurs through heterodimerization with other ErbB receptors and their cognate ligands. This suggests several possible activation paths of HER2 with ligand-specific, differential response, which so far remained unexplored. Using single-molecule tracking and the diffusion profile of HER2 as a proxy for activity, we measured the activation strength and temporal profile in live cells. We found that HER2 is strongly activated by EGFR-targeting ligands EGF and TGFα, yet with a distinguishable temporal fingerprint. The HER4-targeting ligands EREG and NRGβ1 showed weaker activation of HER2, a preference for EREG, and a delayed response to NRGβ1. Our results indicate a selective ligand response of HER2 that may serve as a regulatory element. Our experimental approach is easily transferable to other membrane receptors targeted by multiple ligands.
HER2 belongs to the ErbB sub-family of receptor tyrosine kinases and regulates cellular proliferation and growth. Different from other ErbB receptors, HER2 has no known ligand. Activation occurs through heterodimerization with other ErbB receptors and their cognate ligands. This suggests several possible activation paths of HER2 with ligand-specific, differential response, which has so far remained unexplored. Using single-molecule tracking and the diffusion profile of HER2 as a proxy for activity, we measured the activation strength and temporal profile in live cells. We found that HER2 is strongly activated by EGFR-targeting ligands EGF and TGFα, yet with a distinguishable temporal fingerprint. The HER4-targeting ligands EREG and NRGβ1 showed weaker activation of HER2, a preference for EREG, and a delayed response to NRGβ1. Our results indicate a selective ligand response of HER2 that may serve as a regulatory element. Our experimental approach is easily transferable to other membrane receptors targeted by multiple ligands.
HER2 belongs to the ErbB sub-family of receptor tyrosine kinases and regulates cellular proliferation and growth. Different from other ErbB receptors, HER2 has no known ligand. Activation occurs through heterodimerization with other ErbB receptors and their cognate ligands. This suggests several possible activation paths of HER2 with ligand-specific, differential response, which so far remained unexplored. Using single-molecule tracking and the diffusion profile of HER2 as a proxy for activity, we measured the activation strength and temporal profile in live cells. We found that HER2 is strongly activated by EGFR-targeting ligands EGF and TGFα, yet with a distinguishable temporal fingerprint. The HER4-targeting ligands EREG and NRGβ1 showed weaker activation of HER2, a preference for EREG and a delayed response to NRGβ1. Our results indicate a selective ligand response of HER2 that may serve as a regulatory element. Our experimental approach is easily transferable to other membrane receptors targeted by multiple ligands.
Highlights
HER2 exhibits heterogeneous motion in the plasma membrane
The fraction of immobile HER2 correlates with phosphorylation levels
Diffusion properties serve as proxies for HER2 activation
HER2 exhibits ligand-specific activation strength and temporal profiles
We previously proposed that the dimeric cytochrome bc(1) complex exhibits half-of-the-sites reactivity for ubiquinol oxidation and rapid electron transfer between bc(1) monomers (Covian, R., Kleinschroth, T., Ludwig, B., and Trumpower, B. L. (2007) J. Biol. Chem. 282, 22289-22297). Here, we demonstrate the previously proposed half-of-the-sites reactivity and intermonomeric electron transfer by characterizing the kinetics of ubiquinol oxidation in the dimeric bc(1) complex from Paracoccus denitrificans that contains an inactivating Y147S mutation in one or both cytochrome b subunits. The enzyme with a Y147S mutation in one cytochrome b subunit was catalytically fully active, whereas the activity of the enzyme with a Y147S mutation in both cytochrome b subunits was only 10-16% of that of the enzyme with fully wild-type or heterodimeric cytochrome b subunits. Enzyme with one inactive cytochrome b subunit was also indistinguishable from the dimer with two wild-type cytochrome b subunits in rate and extent of reduction of cytochromes b and c(1) by ubiquinol under pre-steady-state conditions in the presence of antimycin. However, the enzyme with only one mutated cytochrome b subunit did not show the stimulation in the steady-state rate that was observed in the wild-type dimeric enzyme at low concentrations of antimycin, confirming that the half-of-the-sites reactivity for ubiquinol oxidation can be regulated in the wild-type dimer by binding of inhibitor to one ubiquinone reduction site.
The ubiquinol:cytochrome c oxidoreductase is a key component of several aerobic respiratory chains in different organisms. It is an integral membrane protein complex, made up of three catalytic subunits (cytochrome b, cytochrome c1 and Rieske iron sulphur protein) and up to eight additional subunits in mitochondria. The complex oxidizes one quinol molecules and reduces two cytochrome c during the Q cycle, originally described by Peter Mitchell. Electrons are split between the low and the high potential chain and protons are released on the positive side of the membrane, increasing the protonmotive force needed by the ATP-synthase for energy transduction. The cytochrome bc1 complex from P. denitrificans is a perfect model for structural and functional studies. Bacteria are easy to grow and the genetic material is readily accessible for genetic manipulation. Moreover, the P. denitrificans aerobic respiratory chain is very close to the mitochondrial one: the complexes involved in electron transfer resemble the ones found in mitochondria, but lack most of the additional subunits. As a unique feature, P. denitrificans has a strongly acidic domain at the N-terminal region of the cytochrome c1, a sequence of 150 aminoacids which does not correlate with any known protein. An analogous composition can be found in the eukaryotic cytochrome bc1 complex as a part of an accessory subunit, proposed to be involved in facilitating electron transfer between the complex and the electron acceptor cytochrome c. In order to study the function of this domain in the P. denitrificans cytochrome bc1 complex, a deletion mutant has been previously cloned and modified with an affinity tag as a C-terminal extension of cytochrome b. The complex is purified by affinity chromatography and characterized by steady-state kinetics using not only horse heart cytochrome c but also the endogenous electron acceptor, the membrane bound cytochrome c552, employed here as a soluble fragment. Steady–state kinetics indicate that the deletion of the long acidic domain had effects neither on the turnover rate nor on the apparent affinity for the substrate. To understand wether the deletion affects the reaction between the cytochrome bc1 complex and the substrate, laser flash photolysis experiments are performed, showing that the interaction observed was not changed in the complex missing the acidic domain. The results presented in this work confirm the ones previously obtained by Julia Janzon using soluble fragments of the same interaction partners. The deletion, however, affected the oligomerization state of the complex, as shown by LILBID (Laser Induced Liquid Bead Ion Desorption) analysis. The wild type complex has a tetrameric structure, better described as a “dimer of dimers”. The deletion of the acidic domain on the cytochrome c1 results in the separation of the two dimers, yielding the canonical dimer. Therefore, the complex deleted in the acidic domain is used for cloning and expression of a heterodimeric complex, containing an inactivating mutation in the quinol oxidation site in only one monomer, thus allowing a selective switch-off for half the complex. Such a complex is needed for the verification of an internal regulation mechanism, the half-of-the-sites reactivity. According to it, the dimeric structure of the cytochrome bc1 complex has functional implications, since the two monomers can communicate and work in a coordinated manner. This approach confirms that substrate oxidation does effectively take place only in one of the two monomers constituting the dimer, and that the binding of substrate at the Qo and Qi site regulates the switch between active and inactive monomer. Moreover, this mechanism works also as an effective protection against the reaction of quinone intermediates with oxygen and the formation of reactive oxygen species (ROS), responsable for cellular aging. The motion of the ISP head domain is also addressed in this work; in particular the mechanism which regulates the movements towards the cytochrome c1 and the electron bifurcation at the quinol oxidation site. Laser flash kinetics in presence of several inhibitors and the substrate allow studying the response of the ISP to the binding of different species at the quinol oxidation site. The binding of ligand at the Qo site in the complex triggers the conformational switch in the ISP head domain, supporting the mechanism proposed in the literature according to which the Qo site is able to “sense” the presence of substrate and transfer the information to the ISP, regulating its mobility. The internal electron pathway between the ISP and the cytochrome c1 has been analyzed also by stopped-flow kinetics, in presence and absence of inhibitors. The results indicate that two kinetic phases describe the reduction of cytochrome c1 by the ISP, and a model for the simulation of the data is proposed.