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Despite a high clinical need for the treatment of colorectal carcinoma (CRC) as the second leading cause of cancer-related deaths, targeted therapies are still limited. The multifunctional enzyme Transglutaminase 2 (TGM2), which harbors transamidation and GTPase activity, has been implicated in the development and progression of different types of human cancers. However, the mechanism and role of TGM2 in colorectal cancer are poorly understood. Here, we present TGM2 as a promising drug target.
In primary patient material of CRC patients, we detected an increased expression and enzymatic activity of TGM2 in colon cancer tissue in comparison to matched normal colon mucosa cells. The genetic ablation of TGM2 in CRC cell lines using shRNAs or CRISPR/Cas9 inhibited cell expansion and tumorsphere formation. In vivo, tumor initiation and growth were reduced upon genetic knockdown of TGM2 in xenotransplantations. TGM2 ablation led to the induction of Caspase-3-driven apoptosis in CRC cells. Functional rescue experiments with TGM2 variants revealed that the transamidation activity is critical for the pro-survival function of TGM2. Transcriptomic and protein–protein interaction analyses applying various methods including super-resolution and time-lapse microscopy showed that TGM2 directly binds to the tumor suppressor p53, leading to its inactivation and escape of apoptosis induction.
We demonstrate here that TGM2 is an essential survival factor in CRC, highlighting the therapeutic potential of TGM2 inhibitors in CRC patients with high TGM2 expression. The inactivation of p53 by TGM2 binding indicates a general anti-apoptotic function, which may be relevant in cancers beyond CRC.
Fluorescently labeled nanoparticles are widely used for evaluating their distribution in the biological environment. However, dye leakage can lead to misinterpretations of the nanoparticles’ biodistribution. To better understand the interactions of dyes and nanoparticles and their biological environment, we explored PLGA nanoparticles labeled with four widely used dyes encapsulated (coumarin 6, rhodamine 123, DiI) or bound covalently to the polymer (Cy5.5.). The DiI label was stable in both aqueous and lipophilic environments, whereas the quick release of coumarin 6 was observed in model media containing albumin (42%) or liposomes (62%), which could be explained by the different affinity of these dyes to the polymer and lipophilic structures and which we also confirmed by computational modeling (log PDPPC/PLGA: DiI—2.3, Cou6—0.7). The importance of these factors was demonstrated by in vivo neuroimaging (ICON) of the rat retina using double-labeled Cy5.5/Cou6-nanoparticles: encapsulated Cou6 quickly leaked into the tissue, whereas the stably bound Cy.5.5 label remained associated with the vessels. This observation is a good example of the possible misinterpretation of imaging results because the coumarin 6 distribution creates the impression that nanoparticles effectively crossed the blood–retina barrier, whereas in fact no signal from the core material was found beyond the blood vessels.
The ribosomal S1 protein (rS1) is indispensable for translation initiation in Gram-negative bacteria. rS1 is a multidomain protein that acts as an RNA chaperone and ensures that mRNAs can bind the ribosome in a single-stranded conformation, which could be related to fast recognition. Although many ribosome structures were solved in recent years, a high-resolution structure of a two-domain mRNA-binding competent rS1 construct is not yet available. Here, we present the NMR solution structure of the minimal mRNA-binding fragment of Vibrio Vulnificus rS1 containing the domains D3 and D4. Both domains are homologues and adapt an oligonucleotide-binding fold (OB fold) motif. NMR titration experiments reveal that recognition of miscellaneous mRNAs occurs via a continuous interaction surface to one side of these structurally linked domains. Using a novel paramagnetic relaxation enhancement (PRE) approach and exploring different spin-labeling positions within RNA, we were able to track the location and determine the orientation of the RNA in the rS1–D34 bound form. Our investigations show that paramagnetically labeled RNAs, spiked into unmodified RNA, can be used as a molecular ruler to provide structural information on protein-RNA complexes. The dynamic interaction occurs on a defined binding groove spanning both domains with identical β2-β3-β5 interfaces. Evidently, the 3′-ends of the cis-acting RNAs are positioned in the direction of the N-terminus of the rS1 protein, thus towards the 30S binding site and adopt a conformation required for translation initiation.
Copper perchlorophthalocyanine (CuPcCl16, CuC32N8Cl16, Pigment Green 7) is one of the commercially most important green pigments. The compound is a nanocrystalline fully insoluble powder. Its crystal structure was first addressed by electron diffraction in 1972 [Uyeda et al. (1972). J. Appl. Phys. 43, 5181–5189]. Despite the commercial importance of the compound, the crystal structure remained undetermined until now. Using a special vacuum sublimation technique, micron-sized crystals could be obtained. Three-dimensional electron diffraction (3D ED) data were collected in two ways: (i) in static geometry using a combined stage-tilt/beam-tilt collection scheme and (ii) in continuous rotation mode. Both types of data allowed the crystal structure to be solved by direct methods. The structure was refined kinematically with anisotropic displacement parameters for all atoms. Due to the pronounced crystal mosaicity, a dynamic refinement was not feasible. The unit-cell parameters were verified by Rietveld refinement from powder X-ray diffraction data. The crystal structure was validated by many-body dispersion density functional theory (DFT) calculations. CuPcCl16 crystallizes in the space group C2/m (Z = 2), with the molecules arranged in layers. The structure agrees with that proposed in 1972.
Xenocoumacin (Xcn) 1 and 2 are the major antibiotics produced by the insect-pathogenic bacterium Xenorhabdus nematophila. Although the antimicrobial activity of Xcns has been explored, research regarding their action on mammalian cells is lacking. We aimed to investigate the action of Xcns in the context of inflammation and angiogenesis. We found that Xcns do not impair the viability of primary endothelial cells (ECs). Particularly Xcn2, but not Xcn1, inhibited the pro-inflammatory activation of ECs: Xcn2 diminished the interaction between ECs and leukocytes by downregulating cell adhesion molecule expression and blocked critical steps of the NF-κB activation pathway including the nuclear translocation of NF-κB p65 as well as the activation of inhibitor of κBα (IκBα) and IκB kinase β (IKKβ). Furthermore, the synthesis of pro-inflammatory mediators and enzymes, nitric oxide (NO) production and prostaglandin E2 (PGE2), inducible NO synthase (iNOS), and cyclooxygenase-2 (COX-2), was evaluated in leukocytes. The results showed that Xcns reduced viability, NO release, and iNOS expression in activated macrophages. Beyond these anti-inflammatory properties, Xcn2 effectively hindered pro-angiogenic processes in HUVECs, such as proliferation, undirected and chemotactic migration, sprouting, and network formation. Most importantly, we revealed that Xcn2 inhibits de novo protein synthesis in ECs. Consequently, protein levels of receptors that mediate the inflammatory and angiogenic signaling processes and that have a short half-live are reduced by Xcn2 treatment, thus explaining the observed pharmacological activities. Overall, our research highlights that Xcn2 exhibits significant pharmacological in vitro activity regarding inflammation and angiogenesis, which is worth to be further investigated preclinically.
Acute myeloid leukemia (AML) is one of the most frequently occurring and fatal types of leukemia. Initiated by genetic alterations in hematopoietic stem and progenitor cells, rapidly proliferating cancer cells (leukemic blasts) infiltrate the bone marrow and damage healthy hematopoiesis. Subgroups of AML are defined by underlying molecular and cytogenetic abnormalities, which are decisive for treatment and prognosis. For AML patients that can be intensively treated, the first line treatment remains a combination of cytarabine and anthracycline, which was developed in the 1970s. While this treatment regimen clears the disease and reinstates normal hematopoiesis (complete remission, CR) in 60% to 80% of patients below the age of 60, CR rates in patients above the age of 60 are only 40% to 50%. Relapse and refractory disease are the major cause of death of AML patients, despite large efforts to improve risk-adjusted post-remission therapy with further chemotherapy cycles and, if possible, allogeneic bone marrow transplantation. Elderly patients are particularly difficult to treat because of age-related comorbidities and because their disease tends to relapse more often than the disease of younger patients. Thus, the cure rates of AML vary with age, with 5-year survival rates of about 50% in young patients, and less than 20% in patients above the age of 65 years. With the median age of AML patients being 68 years, the need for novel therapeutic options is immense. The recent approval of eight new agents (venetoclax, midostaurin, gilteritinib, glasdegib, ivosidenib, enasidenib, gemtuzumab ozogamicin and CPX-351 (liposomal cytarabine and daunorubicin)) has added considerably to the therapeutic armamentarium of AML and has increased cure rates in specific subgroups of AML. However, the high heterogeneity among patients, clonal evolution and commonly occurring drug resistance, which cause the high relapse rates, remain a substantial problem in the treatment of AML. Therefore, a better understanding of currently used therapeutics and further development of novel therapeutics is urgently needed.
In recent years, attention has increasingly focused on therapeutic strategies to interfere with the metabolic requirements of cancer cells. The last three decades have provided extensive insights into the diversity and flexibility of AML metabolism. AML cells use different sources of nutrients compared to normal hematopoietic progenitor cells and reprogram their metabolic pathways to fulfill their exquisite anabolic and energetic needs. As a result, they develop high metabolic plasticity that enables them to thrive in the bone marrow microenvironment, where oxygen and nutrient availability are subject to constant change.
Cancer cells, specifically AML cells, have a strong dependency for the amino acid glutamine. Glutamine serves in energy production, redox control, cell signaling as well as an important nitrogen source. The only enzyme capable of de novo glutamine synthesis is glutamine synthetase (GS). GS catalyzes glutamine production from glutamate and ammonium. In AML, the metabolic role and dependency of GS is poorly understood. Here, we investigated the effects of GS deletion on AML growth, and its functional relevance in AML metabolism. Genetic deletion of GS resulted in a significant decrease of cell growth in vitro, and impaired leukemia progression in vivo in a xenotransplantation mouse model. Interestingly, the dependency of AML cell growth on GS was shown to be independent of its functional role in glutamine synthesis. Glutamine starvation did not increase the dependency of the AML cells on GS, nor did increased glutamine availability rescue the GS-knockout-associated growth disadvantage. Instead, functional studies revealed the role of GS in the detoxification of ammonium. GS-deficient cells showed elevated ammonium secretion as well as a higher sensitivity towards the toxic metabolite. Exogenous provision of 15N-labeled ammonium was detoxified by GS-driven incorporation into glutamine. Studies on cells that had gained resistance to GS-knockout-mediated growth inhibition indicated enzymes involved in the urea cycle and the arginine biogenesis pathway to compensate for a loss of GS. Together, these findings unveiled GS as an important ammonium scavenger in AML.
Clinical studies on AML patients revealed increased ammonium concentrations in the blast-infiltrated bone marrow compared to peripheral blood. In line with this finding, proteome and transcriptome analysis of AML blasts showed a significant upregulation of GS in AML compared to healthy progenitors, further indicating its importance in ammonium detoxification.
Analyzing pathways that contribute to ammonium production revealed protein uptake followed by amino acid catabolism as a yet not identified mechanism supporting AML growth. Protein endocytosis and subsequent proteolytic degradation were shown to rescue AML cells from otherwise growth-inhibiting glucose or amino acid depletion. Furthermore, protein metabolization led to the reactivation of the mammalian target of rapamycin (mTOR) signaling pathway, which was deactivated upon leucine and glutamine depletion, revealing protein consumption as an important alternative source of amino acids in AML.
...
The DNA damage response (DDR) is a vast network of molecules that preserves genome integrity and allow the faithful transmission of genetic information in human cells. While the usual response to the detection of DNA lesions in cells involves the control of cell-cycle checkpoints, repair proteins or apoptosis, alterations of the repair processes can lead to cellular dysfunction, diseases, or cancer. Besides, cancer patients with DDR alterations often show poor survival and chemoresistance. Despite the progress made in recent years in identifying genes and proteins involved in DDR and their roles in cellular physiology and pathology, the question of the involvement of DDR in metabolism remains unclear. It remains to study the metabolites associated with specific repair pathways or alterations and to investigate whether differences exist depending on cellular origin. The identification of DDR-related metabolic pathways and of the pathways that cause metabolic reprogramming in DDR-deficient cells may produce new targets for the development of new therapies.
In this thesis, nuclear magnetic resonance spectroscopy (NMR) was used to assess the metabolic consequence of the loss of two central DNA repair proteins with importance in diseases context, ATM and RNase H2, in haematological cells. An increase in intracellular taurine was found in RNase H2- and ATM-deficient cells compared to wild-type cells for these genes and in cells after exposition to a source of DNA damage. The rise in taurine does not appear to result from an increase in its biosynthesis from cysteine, but more likely from other cellular processes such as degradation pathways.
Overall, evidence for metabolic reprogramming in haematological cells with faults in DNA repair resulting from ATM or RNase H2 deficiencies or upon exposition to a source of DNA damage is presented in this study.
Famotidine inhibits toll-like receptor 3-mediated inflammatory signaling in SARS-CoV-2 infection
(2021)
Apart from prevention using vaccinations, the management options for COVID-19 remain limited. In retrospective cohort studies, use of famotidine, a specific oral H2 receptor antagonist (antihistamine), has been associated with reduced risk of intubation and death in patients hospitalized with COVID-19. In a case series, nonhospitalized patients with COVID-19 experienced rapid symptom resolution after taking famotidine, but the molecular basis of these observations remains elusive. Here we show using biochemical, cellular, and functional assays that famotidine has no effect on viral replication or viral protease activity. However, famotidine can affect histamine-induced signaling processes in infected Caco2 cells. Specifically, famotidine treatment inhibits histamine-induced expression of Toll-like receptor 3 (TLR3) in SARS-CoV-2 infected cells and can reduce TLR3-dependent signaling processes that culminate in activation of IRF3 and the NF-κB pathway, subsequently controlling antiviral and inflammatory responses. SARS-CoV-2-infected cells treated with famotidine demonstrate reduced expression levels of the inflammatory mediators CCL-2 and IL6, drivers of the cytokine release syndrome that precipitates poor outcome for patients with COVID-19. Given that pharmacokinetic studies indicate that famotidine can reach concentrations in blood that suffice to antagonize histamine H2 receptors expressed in mast cells, neutrophils, and eosinophils, these observations explain how famotidine may contribute to the reduced histamine-induced inflammation and cytokine release, thereby improving the outcome for patients with COVID-19.
Chronic inflammation is characterized by persisting leukocyte infiltration of the affected tissue, which is enabled by activated endothelial cells (ECs). Chronic inflammatory diseases remain a major pharmacotherapeutic challenge, and thus the search for novel drugs and drug targets is an ongoing demand. We have identified the natural product vioprolide A (vioA) to exert anti-inflammatory actions in vivo and in ECs in vitro through inhibition of its cellular target nucleolar protein 14 (NOP14). VioA attenuated the infiltration of microglia and macrophages during laser-induced murine choroidal neovascularization and the leukocyte trafficking through the vascular endothelium in the murine cremaster muscle. Mechanistic studies revealed that vioA downregulates EC adhesion molecules and the tumor necrosis factor receptor (TNFR) 1 by decreasing the de novo protein synthesis in ECs. Most importantly, we found that inhibition of importin-dependent NF-ĸB p65 nuclear translocation is a crucial part of the action of vioA leading to reduced NF-ĸB promotor activity and inflammatory gene expression. Knockdown experiments revealed a causal link between the cellular target NOP14 and the anti-inflammatory action of vioA, classifying the natural product as unique drug lead for anti-inflammatory therapeutics.
Serine-ubiquitination regulates Golgi morphology and the secretory pathway upon Legionella infection
(2021)
SidE family of Legionella effectors catalyze non-canonical phosphoribosyl-linked ubiquitination (PR-ubiquitination) of host proteins during bacterial infection. SdeA localizes predominantly to ER and partially to the Golgi apparatus, and mediates serine ubiquitination of multiple ER and Golgi proteins. Here we show that SdeA causes disruption of Golgi integrity due to its ubiquitin ligase activity. The Golgi linking proteins GRASP55 and GRASP65 are PR-ubiquitinated on multiple serine residues, thus preventing their ability to cluster and form oligomeric structures. In addition, we found that the functional consequence of Golgi disruption is not linked to the recruitment of Golgi membranes to the growing Legionella-containing vacuoles. Instead, it affects the host secretory pathway. Taken together, our study sheds light on the Golgi manipulation strategy by which Legionella hijacks the secretory pathway and promotes bacterial infection.
The vascular endothelium is a monolayer of endothelial cells that builds the inner lining of the blood vessels and constitutes a regulatory organ within the physiological system to sustain homeostasis. Endothelial cells participate in physiological processes including inflammation and angiogenesis. Dysregulation of these processes, however, can evoke or maintain pathological disorders, including cardiovascular and chronic inflammatory diseases or cancer. Although pathological inflammation and angiogenesis represent treatable conditions, current pharmacotherapeutic approaches are frequently not satisfying since their long-term application can evoke therapy resistance and thus reduced clinical efficacy. Consequently, there is an ongoing demand for the discovery of new therapeutic targets and drug leads. Considering that endothelial cells play a critical role in both angiogenesis and inflammation, the vascular endothelium represents a promising target for the treatment of diseases.
Vioprolide A is a secondary metabolite isolated from the myxobacterium Cystobacter violaceus Cb. vi35. Recently, vioprolide A was identified to interact with NOP14, a nucleolar protein involved in ribosome biogenesis. Ribosome biogenesis is an indispensable cellular event that ensures adequate homeostasis. Abnormal alterations in the ribosome biogenesis, referred to as ribosomopathies, however, can lead to an overall increase in the risk of developing cancer. Accordingly, several studies have outlined the involvement of NOP14 in cancer progression and metastasis, and vioprolide A has been demonstrated to exert anti-cancer effects in vitro. However, the impact of vioprolide A and NOP14 on the endothelium has been neglected so far, although endothelial cells are crucially involved in inflammation and angiogenesis under both physiological and pathological conditions.
In the present study, the effect of vioprolide A on inflammatory and angiogenic actions was analysed. In vivo, the laser-induced choroidal neovascularization (CNV) assay outlined a strong inhibitory effect of vioprolide A on both inflammation and angiogenesis. Furthermore, intravital microscopy of the cremaster muscle in mice revealed that vioprolide A strongly impaired the TNF-induced leukocyte-endothelial cell interaction in vivo.
In further experiments, the specific effect of vioprolide A on activation processes of primary human umbilical vein endothelial cells (HUVECs) was examined. According to the in vivo results, vioprolide A decreased the leukocyte-endothelial cell interaction in vitro through downregulating the cell surface expression and total protein expression of ICAM-1, VCAM-1 and E-selectin. Vioprolide A evoked its anti-inflammatory actions via a dual mechanism: On the one hand, the expression of pro-inflammatory proteins, including TNFR1 and cell adhesion molecules, was lowered through a general downregulation of de novo protein synthesis. The inhibition of de novo protein synthesis is most likely linked to the interaction with and inhibition of NOP14 by vioprolide A in HUVECs. On the other hand, the natural product prevented the nuclear translocation and promotor activity of the pro-inflammatory transcription factor NF-ĸB. Interestingly, most anti-inflammatory compounds that interfere with the NF-ĸB signaling pathway prevent NF-ĸB nuclear translocation through recovering or stabilizing the inhibitory IĸB proteins. Vioprolide A, however, decreased rather than stabilized the IĸB proteins and prevented NF-ĸB nuclear translocation through interfering with its importin-dependent nuclear import. By performing siRNA-mediated knockdown experiments, we evaluated the role of NOP14 in inflammatory processes in HUVECs and could establish a causal link between the anti-inflammatory actions of vioprolide A and the deletion of NOP14.
Besides exerting anti-inflammatory actions, we found that vioprolide A potently decreased the angiogenic key features proliferation, migration and sprouting of endothelial cells. Mechanistically, the natural product interfered with pro-angiogenic signaling pathways. Vioprolide A reduced the protein level of growth factor receptors, including VEGFR2, which is the most prominent receptor responsible for angiogenic signaling in endothelial cells. This effect was based on the general inhibition of de novo protein synthesis by the natural product. Downregulation of growth factor receptors impaired the activation of downstream signaling intermediates, including the MAPKs ERK, JNK and p38. To our surprise, however, activation of Akt, another downstream effector of VEGFR2, was increased rather than decreased. Furthermore, vioprolide A lowered the nuclear translocation of the transcriptional coactivator TAZ, which is regulated by the evolutionary conserved Hippo signaling pathway. Interestingly, however, and in contrast to NF-ĸB, TAZ nuclear translocation in mammalian cells seems to be independent of importins. In this context, we found that vioprolide A reduced both the protein level and nuclear localization of MAML1, which is needed to retain TAZ in the nucleus after its successful translocation.
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The SARS-CoV-2 genome encodes for approximately 30 proteins. Within the international project COVID19-NMR, we distribute the spectroscopic analysis of the viral proteins and RNA. Here, we report NMR chemical shift assignments for the protein Nsp3b, a domain of Nsp3. The 217-kDa large Nsp3 protein contains multiple structurally independent, yet functionally related domains including the viral papain-like protease and Nsp3b, a macrodomain (MD). In general, the MDs of SARS-CoV and MERS-CoV were suggested to play a key role in viral replication by modulating the immune response of the host. The MDs are structurally conserved. They most likely remove ADP-ribose, a common posttranslational modification, from protein side chains. This de-ADP ribosylating function has potentially evolved to protect the virus from the anti-viral ADP-ribosylation catalyzed by poly-ADP-ribose polymerases (PARPs), which in turn are triggered by pathogen-associated sensing of the host immune system. This renders the SARS-CoV-2 Nsp3b a highly relevant drug target in the viral replication process. We here report the near-complete NMR backbone resonance assignment (1H, 13C, 15N) of the putative Nsp3b MD in its apo form and in complex with ADP-ribose. Furthermore, we derive the secondary structure of Nsp3b in solution. In addition, 15N-relaxation data suggest an ordered, rigid core of the MD structure. These data will provide a basis for NMR investigations targeted at obtaining small-molecule inhibitors interfering with the catalytic activity of Nsp3b.
Gram-negative bacteria maintain an intrinsic resistance mechanism against entry of noxious compounds by utilizing highly efficient efflux pumps. The E. coli AcrAB-TolC drug efflux pump contains the inner membrane H+/drug antiporter AcrB comprising three functionally interdependent protomers, cycling consecutively through the loose (L), tight (T) and open (O) state during cooperative catalysis. Here, we present 13 X-ray structures of AcrB in intermediate states of the transport cycle. Structure-based mutational analysis combined with drug susceptibility assays indicate that drugs are guided through dedicated transport channels toward the drug binding pockets. A co-structure obtained in the combined presence of erythromycin, linezolid, oxacillin and fusidic acid shows binding of fusidic acid deeply inside the T protomer transmembrane domain. Thiol cross-link substrate protection assays indicate that this transmembrane domain-binding site can also accommodate oxacillin or novobiocin but not erythromycin or linezolid. AcrB-mediated drug transport is suggested to be allosterically modulated in presence of multiple drugs.
Standard cancer therapy research targets tumor cells while not considering the damage on the tumor microenvironment (TME) and its associated implications in impairing therapy response. Employing patients-derived organoids (PDOs) and matched stroma cells or a novel murine preclinical rectal cancer model of local radiotherapy, it was demonstrated that tumor cells-derived IL-1α polarizes cancer-associated fibroblasts towards an inflammatory (iCAFs) phenotype. While numerous studies in different tumor entities highlighted the molecular heterogeneity of CAFs, so far there are no clear findings on their functional heterogeneity and relevance in therapy resistance and response. The present study molecularly characterized iCAFs subpopulation among RCA patients as well as the preclinical mouse model and importantly unraveled the detailed molecular mechanism underlying their contribution to impair therapy response. Mechanistically, iCAFs were demonstrated to be characterized by an upregulation of nitric oxide synthase (iNOS) which triggered accumulation of reactive nitrogen species (RNS) and subsequently an oxidative DNA damage response (DDR). Such a baseline IL-1α-driven DNA damage further sensitized iCAFs to a p53-mediated therapy induced senescence (TIS) causing extensive extracellular matrix (ECM) changes and induction of senescence associated secretory phenotype (SASP) that favored tumor progression and hindered tumor cell death. Moreover, iCAFs reversibility and repolarization into more quiescent like phenotype was demonstrated upon IL-1 signaling inhibition by anakinra, a recombinant IL-1 receptor antagonist (IL1RA). Accordingly, treating mice with anakinra or specific deletion of Il1r1 in CAFs sensitized stroma-rich resistant tumors to chemoradiotherapy (CRT). Similarly, targeting CAFs senescence by senotherapy (venetoclax chemical) or employing Trp53 deficient mice reverted therapy resistance among non-responsive tumors in vivo by reducing ECM deposition and consequently favoring CD8+ T cells intratumoral infiltration posttherapy. Importantly, rectal cancer patients that do not completely respond to neoadjuvant therapy displayed an iCAFs senescence program post-CRT. Moreover, these patients presented a baseline increased CAFs content, a dominant iCAFs signature that correlated with poorer disease-free survival (DFS) and a significantly reduced circulating IL1RA serum levels. While reduced pretherapeutic IL1RN gene expression predicted poor prognosis among RCA patients, IL1RA serum levels were associated with rs4251961 (T/C) single nucleotide polymorphism (SNP) in the IL1RN gene. Finally, functional validation assays revealed that conditioned media of PDOs drove inflammatory polarization of fibroblasts and consequently rendered them sensitive to RNS-mediated DNA damage and TIS. Collectively, the study highlighted a crucial and novel role of a CAFs subset, iCAFs, in therapy resistance among RCA patients, shedding light on their functional relevance by identifying IL-1 signaling as an appealing target for their repolarization and successful targeting. Therefore, it makes sense to combine the newly demonstrated and thoroughly proven therapeutic approach of targeting IL-1 signaling in combination with conventional CRT and possibly immunotherapy. This might have a major impact on RCA therapy and be of immense relevance for other stroma-rich tumors.
Sphingosin 1 Phosphat (S1P) ist ein wichtiger Lipidmediator, der über G Protein gekoppelte Rezeptoren und intrazelluläre Wirkungen vielfältige Wirkungen auslöst und eine Rolle bei der Lymphozytenzirkulation, der Erhaltung der endothelialen Barriere, bei Entzündungsprozessen und Tumorwachstum spielt. Die S1P Lyase (Sgpl1) katalysiert den irreversiblen Abbau von S1P und damit den letzten Schritt des Sphingolipidkatabolismus‘. Ein Fehlen der Sgpl1 bewirkt eine Akkumulation von S1P und anderen Sphingolipiden im Blut und Gewebe, was multiple Organschäden zur Folge hat. Menschen mit S1P Lyase Insuffizienz Syndrom (SPLIS) leiden insbesondere unter steroidresistentem nephrotischem Syndrom, Nebennierenrinden-insuffizienz und neurologischen Störungen. Weitere mögliche Symptome sind Lymphopenie, Hautveränderungen und Dyslipidämien. S1P Lyase defiziente Mäuse weisen sehr ähnliche Organschädigungen auf.
An Sgpl1 Knockoutmäusen war zuerst die massive Akkumulation nicht nur von Sphingolipiden, sondern auch von Cholesterin und Triglyceriden in Blut und Leber aufgefallen. Auch bei SPLIS Patienten wurde eine Hypercholesterinämie beobachtet. Um die Kreuzregulation des Sphingolipid- und Cholesterinmetabolismus besser zu verstehen, sollte die Rolle der Sgpl1 in der Leber, dem Hauptort des Lipidmetabolismus, untersucht werden. Hierzu sollte ein Mausmodell mit einem hepatozytenspezifischen Sgpl1 Knockout (Sgpl1HepKO) etabliert und charakterisiert werden. Dies wurde durch Kreuzen von Sgpl1fl/fl-Mäusen mit Mäusen, welche die Cre-Rekombinase unter dem Albuminpromoter exprimierten, erreicht. Die basale Charakterisierung zeigte, dass diese Mäuse im Gegensatz zu globalen Sgpl1 Knockoutmäusen sowohl im Alter von acht Wochen, als auch im Alter von acht Monaten einen unauffälligen Phänotyp aufwiesen. Das äußere Erscheinungsbild inklusive Leber und Körpergewicht, das Blutbild, die Leberenzyme sowie die Histologie der Leber waren unverändert. Die Analyse der Leberlipide mit Hilfe von Hochleistungsflüssigkeits-chromatographie gekoppelt mit einer Tandem Massenspektrometrie zeigte eine signifikante Akkumulation (≈1,5 2 fach) von S1P, Sphingosin und Ceramiden, aber nicht von Glucosylceramiden und Sphingomyelin in der Leber. Messungen im Plasma zeigten eine Erhöhung mehrerer Ceramide, während der S1P Spiegel normal war. Ferner zeigten Untersuchungen der Galle signifikant erhöhte Konzentrationen an S1P, Dihydro S1P und Glucosylceramiden, jedoch unveränderte Ceramide. Die Ergebnisse legen folgende Schlussfolgerungen nahe: 1. In der Leber kann mit Hilfe von Ceramidsynthasen akkumulierendes Sphingosin in Ceramide umgewandelt werden, welche anschließend ins Blut sezerniert und letztendlich vermutlich von anderen Zellen verstoffwechselt werden. Außerdem ist nicht ausgeschlossen, dass S1P ebenfalls ins Blut sezerniert und dort effektiv abgebaut wird, so dass die S1P Konzentration im Plasma unverändert bleibt. 2. S1P sowie Glucosylceramide werden an die Galle abgegeben und ausgeschieden. 3. Die Sgpl1 in der Leber ist nicht essentiell für die Regulation des Plasma S1Ps, was zuvor vermutet worden war
Eine Analyse der Sterole zeigte in Sgpl1HepKO Mäusen erhöhte Spiegel an Cholesterin und Desmosterol in der Leber. In Übereinstimmung mit der erhöhten Proteinexpression des low density lipoprotein (LDL ) Rezeptors und erniedrigten Konzentrationen des LDL Cholesterins im Plasma, deuten diese Daten auf eine erhöhte Aufnahme von LDL Cholesterin durch die Leber hin. Untersuchungen in der Leber sowie mit primären Hepatozyten zeigten im Gegensatz zu globalen Sgpl1 Knockoutmäusen keine Veränderungen der Peroxisomen-Proliferator-aktiviertem Rezeptor γ Expression. Weitere Gene mit zentraler Rolle wie der Liver X receptor oder die Fettsäuresynthase, waren ebenfalls nicht reguliert. Dieser im Vergleich zu globalen Sgpl1-Knockoutmäusen milde Phänotyp lässt sich durch die deutlich geringere Akkumulation von Sphingolipiden aufgrund der oben beschriebenen Kompensations-mechanismen in Sgpl1HepKO Mäusen erklären.
In weiteren Untersuchungen sollten die Auswirkungen einer Sgpl1-Defizienz an Fibroblasten untersucht werden. Hierzu standen embryonale Fibroblasten aus Sgpl1 Knockoutmäusen zur Verfügung (Sgpl1-/- MEFs). In einer Kooperation mit Dr. Janecke von der Universität Innsbruck standen außerdem humane Fibroblasten eines SPLIS Patienten zur Verfügung.
An Sgpl1-/- MEFs war zuvor eine gestörte Calciumhomöostase festgestellt worden, welche sich durch eine erhöhte zytosolische Calciumkonzentration und vermehrte Calciumspeicherung im Endoplasmatischen Retikulum und in Lysosomen auszeichnete. Die Plasmamembran-Calcium ATPase (PMCA) trägt an Fibroblasten entscheidend zur Regulation der zytosolischen Calciumkonzentration bei. Ihre Expression auf Proteinebene war jedoch in Sgpl1-/- MEFs nicht verändert. Im Rahmen dieser Arbeit wurde durch eine Immunfärbung erstmals festgestellt, dass die PMCA in Sgpl1-/- MEFs nicht vollständig an der Plasmamembran lokalisiert war. Dies könnte der Grund für die erhöhte zytosolische Calciumkonzentration in den Zellen sein. ...
Kurz zusammengefasst waren die Ziele dieser Arbeit, die in vivo Untersuchung einer Hyperhomocysteinämie und spezifischer diätetischer Mikronährstoffe im Kontext der Alzheimer-Erkrankung. Zu diesem Zweck wurden zwei Krankheitsmodelle in den Mäusen induziert. Zum einen wurde eine Alzheimer-ähnliche Pathologie genetisch simuliert durch den Einsatz des neuen AppNL-G-F knock-in Modells, das im Zuge dieser Arbeit auch weiter charakterisiert wurde. Zum anderen wurde eine chronische Hyperhomocysteinämie in den Tieren induziert via Langzeit-Fütterung einer Spezialdiät, die defizient an den Vitaminen B6, B12 und Folat war, was sich durch erhöhte Werte der Aminosäuren Homocystein und Homocysteinsäure in verschiedenen biologischen Matrices der Mäuse wie Serum, Urin und Hirngewebe, bemerkbar machte. Durch die Kombination der Krankheitsmodelle wurden sowohl Aspekte einer familiären Alzheimer-Erkrankung (verstärkter Amyloid-β-Anabolismus im knock-in Modell) als auch ein potentielles Charakteristikum der sporadischen Form der Krankheit (erhöhte Homocystein-Spiegel) simuliert. Auswirkungen des AppNL-G-F Genotyps, einer zusätzlichen Hyperhomocysteinämie und potentiell vorteilhafter, oder gar präventiv wirksamer Mikronährstoffe wurden dabei mit Hilfe von diversen Verhaltensversuchen und ergänzenden ex vivo Analysen bewertet.
Trotz massiver cerebraler Amyloidose war lediglich ein milder Einfluss auf die kognitive Leistungsfähigkeit der AppNL-G-F Tiere im Vergleich zur gleichaltrigen Wildtyp-Kontrolle detektierbar. Dies weist zum einen auf die Subtilität des Mausmodells hin und zum anderen befeuert es die kontroverse, häufig geführte Diskussion um die zentrale Bedeutung der „Amyloid-Hypothese“ im Rahmen der komplexen Alzheimer-Pathologie. Die kognitiven Fähigkeiten der entsprechenden Mäuse verschlechterten sich auch nicht bei gleichzeitig signifikant erhöhten Homocystein- und Homocysteinsäurespiegeln, d.h. die Hyperhomocysteinämie hat in diesem Modell für familiären Alzheimer nicht kausal zur Verschlimmerung der induzierten Pathologie beigetragen sowohl hinsichtlich der kognitiven Leistung in diversen Verhaltensversuchen als auch hinsichtlich dem Schweregrad der cerebralen Amyloidose.
Zur Hyperhomocysteinämie, vor allem aber auch zur Rolle bestimmter diätetischer Interventionen in dem Kontext, findet man eine heterogene, teilweise konträre Literatur vor, insbesondere im klinischen Kontext. Die untersuchten diätetischen Ansätze in dieser Arbeit, bestehend aus hochdosierten B-Vitaminen, mehrfach ungesättigten Fettsäuren, Betain und einer komplexeren Mikronährstoffkombination, zeigten ebenfalls keinen konsistenten Effekt auf Phänotyp und Amyloid-β-Menge in den Hirnen der Tiere. Die Ergebnisse der durchgeführten Studien legen daher, zumindest in diesem Krankheitsmodell, keinen Wert als potentiell präventiven Ansatz der kognitiven Verschlechterung bei Alzheimer nahe.
Da die dieser Arbeit zugrundeliegenden in vivo Studien keine per se erhöhten, AppNL-G-F-assoziierten Homocysteinspiegel offenbarten, zeigte sich Homocystein nicht als Biomarker, zumindest für die in diesem Mausmodell simulierten Aspekte der komplexen Alzheimer-Pathologie. Neben den zuvor beschriebenen fehlenden Effekten der Hyperhomocysteinämie, konnten in dieser Arbeit jedoch auch statistisch signifikante Einflüsse sichtbar gemacht werden. Wie in der durchgeführten Kinetikstudie gezeigt, resultierte die Alzheimer-ähnliche Pathologie in einem signifikant höheren Schweregrad der ausgebildeten Hyperhomocysteinämie in den AppNL-G-F Tieren im Vergleich zur gleichaltrigen Wildtyp-Kontrolle. Folglich übte der gestörte Amyloid-β-Metabolismus, neben der B-vitamindefizienten Diät, einen zusätzlich verstärkenden Effekt auf den hyperhomocysteinämischen Status aus. Sowohl für knock-in-, als auch Wildtyp-Tiere konnte gezeigt werden, dass bei Beendigung der Karenz an Vitamin B6, B12 und Folat, die erhöhten Homocystein- und Homocysteinsäurespiegel innerhalb kurzer Zeit wieder auf Baseline-Niveau normalisiert werden können.
Weitere signifikante Effekte wurden detektiert bezüglich Erythrozyten-bezogener Parameter wie den Hämoglobingehalt im Blut der hyperhomocysteinämischen Tiere. Ein reduzierter Sauerstofftransport und die damit einhergehende verringerte Versorgung der Neuronen mit Sauerstoff in den entsprechenden experimentellen Gruppen deuten auf eine vornehmlich vaskuläre Wirkung hin im Hinblick auf Homocystein-bezogene Pathomechanismen, die potentiell zu einer Demenz beitragen. Solche Effekte können zusätzlich verstärkt worden sein durch die, in der durchgeführten Proteomanalyse gezeigte, Herunterregulierung angiogener Marker im Serum und in der Cerebrospinalflüssigkeit dieser Tiere. Eine Verringerung der kapillären Dichte im Hirn und ein verringerter cerebraler Blutfluss haben ein zusätzlich reduziertes Angebot an Sauerstoff und Glucose zur Folge und stellen einen Link zu eingeschränkter kognitiver Leistungsfähigkeit in Älteren und Alzheimer-Patienten dar. Translational relevant ist eine vaskuläre Wirkung von Homocystein auch dadurch, dass vaskuläre Demenz und Alzheimer in etwa 40% der Fälle koinzident sind und Homocystein in früheren Humanuntersuchungen eine größere Bedeutung bei der vaskulären Demenz im Vergleich zur Alzheimer-Erkrankung nahelegte.
Auch wenn in Summe die beschriebenen Effekte der Hyperhomocysteinämie nicht groß genug waren, um sich in phänotypischen Einschränkungen in den Tieren auszudrücken, so konnten in der hier vorliegenden Arbeit dennoch Details zur Rolle erhöhter Homocysteinspiegel für verschiedene biologische Prozesse aufgeklärt werden. Insbesondere die Funde der explorativen Proteomanalyse in Serum und CSF könnten Ansatzpunkte für weitergehende Untersuchungen darstellen und sollten in anderen präklinischen Krankheitsmodellen und/oder einer Humanstudie validiert werden.
Additive manufacturing or 3D printing as an umbrella term for various materials processing methods has distinct advantages over many other processing methods, including the ability to generate highly complex shapes and designs. However, the performance of any produced part not only depends on the material used and its shape, but is also critically dependent on its surface properties. Important features, such as wetting or fouling, critically depend mainly on the immediate surface energy. To gain control over the surface chemistry post-processing modifications are generally necessary, since it′s not a feature of additive manufacturing. Here, we report on the use of initiator and catalyst-free photografting and photopolymerization for the hydrophilic modification of microfiber scaffolds obtained from hydrophobic medical-grade poly(ε-caprolactone) via melt-electrowriting. Contact angle measurements and Raman spectroscopy confirms the formation of a more hydrophilic coating of poly(2-hydroxyethyl methacrylate). Apart from surface modification, we also observe bulk polymerization, which is expected for this method, and currently limits the controllability of this procedure.
The stress-dependent dynamics of Saccharomyces cerevisiae tRNA and rRNA modification profiles
(2021)
RNAs are key players in the cell, and to fulfil their functions, they are enzymatically modified. These modifications have been found to be dynamic and dependent on internal and external factors, such as stress. In this study we used nucleic acid isotope labeling coupled mass spectrometry (NAIL-MS) to address the question of which mechanisms allow the dynamic adaptation of RNA modifications during stress in the model organism S. cerevisiae. We found that both tRNA and rRNA transcription is stalled in yeast exposed to stressors such as H2O2, NaAsO2 or methyl methanesulfonate (MMS). From the absence of new transcripts, we concluded that most RNA modification profile changes observed to date are linked to changes happening on the pre-existing RNAs. We confirmed these changes, and we followed the fate of the pre-existing tRNAs and rRNAs during stress recovery. For MMS, we found previously described damage products in tRNA, and in addition, we found evidence for direct base methylation damage of 2′O-ribose methylated nucleosides in rRNA. While we found no evidence for increased RNA degradation after MMS exposure, we observed rapid loss of all methylation damages in all studied RNAs. With NAIL-MS we further established the modification speed in new tRNA and 18S and 25S rRNA from unstressed S. cerevisiae. During stress exposure, the placement of modifications was delayed overall. Only the tRNA modifications 1-methyladenosine and pseudouridine were incorporated as fast in stressed cells as in control cells. Similarly, 2′-O-methyladenosine in both 18S and 25S rRNA was unaffected by the stressor, but all other rRNA modifications were incorporated after a delay. In summary, we present mechanistic insights into stress-dependent RNA modification profiling in S. cerevisiae tRNA and rRNA.
The prevalence and specificity of local protein synthesis during neuronal synaptic plasticity
(2021)
To supply proteins to their vast volume, neurons localize mRNAs and ribosomes in dendrites and axons. While local protein synthesis is required for synaptic plasticity, the abundance and distribution of ribosomes and nascent proteins near synapses remain elusive. Here, we quantified the occurrence of local translation and visualized the range of synapses supplied by nascent proteins during basal and plastic conditions. We detected dendritic ribosomes and nascent proteins at single-molecule resolution using DNA-PAINT and metabolic labeling. Both ribosomes and nascent proteins positively correlated with synapse density. Ribosomes were detected at ~85% of synapses with ~2 translational sites per synapse; ~50% of the nascent protein was detected near synapses. The amount of locally synthesized protein detected at a synapse correlated with its spontaneous Ca2+ activity. A multifold increase in synaptic nascent protein was evident following both local and global plasticity at respective scales, albeit with substantial heterogeneity between neighboring synapses.
Bezüglich der Arzneimittelforschung galt für sehr lange Zeit das Paradigma "ein Gen, ein Medikament, eine Krankheit". In jüngerer Zeit ändert sich dieses Paradigma jedoch auf Grund von redundanten Funktionen und alternativen sich kompensierenden Signalmustern, die insbesondere bei Krebserkrankungen vorherrschend sind. Daher kann die logische Konsequenz nur sein, Multi-Target-Strategien gegenüber Single-Target-Ansätzen in Betracht zu ziehen. Auf Grund der Schwierigkeit, mit einer Kombination von zwei Einzelwirkstoffen, in diesem Fall BET- und HDAC-Inhibitoren eine konsistente Biodistribution und Pharmakokinetik zu erreichen, wurde nach Einzelmolekülen gesucht, die mehrere inhibitorische Aktivitäten aufweisen. Dies wurde hier zunächst durch die einfache Konjugation von zwei unterschiedlichen Pharmakophoren erreicht.
Insgesamt wurden vier verschiedene Liganden dieses Typs synthetisiert und einer von ihnen, Verbindung 14, zeigte sehr vielversprechende Ergebnisse. 14 vereint den BET Inhibitor JQ1- mit dem HDAC Inhibitor CI994 und hat eine hemmende Wirkung sowohl gegen BRD4- als auch HDAC-Proteine wie durch DSF- und nanoBRET-Assay gezeigt werden konnte. Außerdem zeigten in vitro Assays in PDAC-Zellen, dass 14 ein noch potenterer dualer BET/HDAC-Inhibitor ist als die Kombination aus JQ1 und CI994. Während die Effekte von 14 auf das BETi-Antwortgen MYC denen von JQ1 ziemlich ähnlich sind, sind insbesondere die HDAC-inhibitorischen Effekte nachhaltiger und verstärkt, wahrscheinlich aufgrund einer längeren Verweildauer von 14 auf HDAC als dies bei CI994 der Fall ist. Dies ist durch das hohe Niveau der acetylierten Lysine von Histon H3 im Western Blot erkennbar. Dieses veränderte Expressionsverhalten hatte einen großen Einfluss auf das Zellwachstum und überleben in allen getesteten PDAC-Zelllinien. Hier wurde die Überlegenheit von 14 gegenüber der gleichzeitigen Behandlung der Zellen mit JQ1 und CI994 sehr deutlich. Wurden PDAC-Zellen mit dem dualen Inhibitor 14 behandelt, hatte dies ein geringeres Wachstum und Überleben der Krebszellen zur Folge als mit beiden ursprünglichen Molekülen, unabhängig davon, ob diese einzeln oder simultan verabreicht wurden. Außerdem wurde 14 mit Gemcitabin, einem gut verträglichen Chemotherapeutikum, kombiniert, dass bei PDAC allein nur eine begrenzte Aktivität aufweist. Es stellte sich heraus, dass die Reihenfolge, in der die Medikamente verabreicht werden, einen großen Einfluss auf die Effektivität hatte. Der durch 14 induzierte Stopp des Zellzyklus verhindert den Einbau von Gemcitabin in die DNA, wenn 14 vor oder gleichzeitig mit Gemcitabin verabreicht wird. Wenn jedoch die Behandlung mit 14 nach der Verabreichung von Gemcitabin folgt, wird der durch Gemcitabin induzierte S-Phasen-Arrest und Replikationsstress aufrechterhalten. Im Vergleich zu den meisten früheren Studien, die sich mit dualen BET/HDAC-Inhibitoren beschäftigten, ist dies eine große Verbesserung, da es bisher keinen signifikanten Unterschied zwischen der Verwendung eines dualen BET/HDAC-Inhibitors und der Kombination von zwei Einzelinhibitoren gab.
Als Proof of Concept unterstützten die Daten weitere Bemühungen zur Entwicklung zusätzlicher dualer BET/HDAC-Inhibitoren. Daher wurden zwei weitere Generationen dualer BET/HDAC Inhibitoren entwickelt, die jedoch bisher nicht an die Eigenschaften von 14 anknüpfen konnten. Vor allem die 3. Generation bietet jedoch Raum für Optimierungen, so dass hier möglicherweise noch ein potenter dualer Inhibitor zu finden ist. Sollte es in Zukunft einen zugelassenen dualen BET/HDAC-Inhibitor geben, ist es jedoch nicht unwahrscheinlich, dass keine der hier verwendet BET inhibierenden Strukturen verwendet werden, aber Struktur des HDAC inhibierenden Teils immer noch vergleichbar ist. Der Grund dafür ist, dass die HDAC Inhibitoren größtenteils relativ einfach aufgebaut. So lange das wichtigste, die zinkbindende Gruppe vorhanden ist, scheint der Linker sowie die Capping-Gruppe zweitranging zu sein. Die größere Herausforderung wird vermutlich die Suche nach dem passenden BET Inhibitor sein und die Wahlmöglichkeiten sind schon jetzt vielfältig.
Generell lässt sich sagen, dass die Idee der dualen BET/HDAC-Inhibitoren äußerst vielversprechend und es wert ist, weiter verfolgt zu werden. Dies liegt vor allem an den guten Testergebnissen, die mit Verbindung 14 erzielt wurden. Mit Hilfe dieser Art von Inhibitoren könnte es in Zukunft möglich sein, die Überlebensrate von PDAC-Patienten zu erhöhen, wenn nicht als alleiniges Medikament, so vielleicht als Zusatz zur Chemotherapie. Darüber hinaus scheint der Einsatz von dualen BET/HDAC-Inhibitoren nicht nur auf die Behandlung von PDAC beschränkt zu sein und kann auch bei anderen Krebsarten angewendet werden. NMC zum Beispiel ist ein ebenso seltener wie tödlicher Subtyp des schlecht differenzierten Plattenepithelkarzinoms und zeichnet sich durch eine Fusion des NUT-Gens mit BRD4 aus, wodurch es potenziell anfällig für eine BET-Inhibition ist. Tatsächlich zeigte 14 auch hier einen größeren positiven Effekt auf die getesteten NMC-Zellen als JQ1 oder CI994 und veranlasste die Zellen unter anderem zur Differenzierung. ...
Standard biorelevant media reflect the average gastrointestinal (GI) physiology in healthy volunteers. The use of biorelevant media in in vitro experiments has become an important strategy to predict drug behaviour in vivo and is often combined with in silico tools in order to simulate drug plasma profiles over time. In addition to the healthy population, the effects of disease state or co-administration of other drugs on plasma profiles must be considered to assure drug efficacy and safety. Thus, there is a need for a more accurate representation of the human GI physiology when it is altered by disease or co-administered drugs in in vitro dissolution experiments.
This thesis focused on the development of biorelevant media and dissolution tests reflecting GI physiology in circumstances where the gastric pH is elevated. Diseases linked to an elevated gastric pH are hypochlorhydria and achlorhydria, but these days treatment with acid-reducing agents (ARAs) is the single greatest cause of elevation in gastric pH. pH-dependent drug-drug interactions (DDIs) with ARAs are frequent, as the ARAs are used in a number of diseases using a variety of drugs. As the drugs currently on the market are often poorly soluble and ionisable, their dissolution is highly dependent on the pH of the GI tract, especially the gastric pH.
The thesis research consisted of several steps. In the first step, physiological changes in the human GI tract during the therapy with ARAs were identified. Parameters of the standard biorelevant gastric medium FaSSGF were adjusted to the identified changes to reflect the impact of ARA co-administration on the gastric physiology. The media aim to assess the potential extent of the ARA impact on gastric physiology by introducing biorelevant media pairs, ARA pH 4 and pH 6 media, of which one reflects a lesser, and the other a stronger impact of ARAs.
In the second step these ARA media were implemented in in vitro dissolution set-ups.
The dissolution of poorly soluble ionisable drugs was assessed using one-stage, two-stage and transfer model set-ups, as well as using a more evolved in vitro system TIM-1. Comparison of results from dissolution set-ups using the standard, low pH, gastric biorelevant medium FaSSGF (pH 1.6 or 2), and the same set-ups using ARA pH 4 and pH 6 media, shows a decrease in dissolution rate and extent for weakly basic compounds PSWB 001 and dipyridamole, and an increase in rate and extent of dissolution for the weakly acidic compound raltegravir potassium, when the gastric pH is elevated. Due to different physicochemical properties, the extent of the impact of physiological changes during ARA therapy (when either ARA pH 4 or pH 6 medium is selected) on dissolution varied among the model drugs. Thus, the bracketing approach, which considers a range of the possible ARA co-administration impact on drug dissolution, was confirmed to be best practice in assessing the impact of ARAs.
In the third step, dissolution data from in vitro experiments with ARA media was implemented into in silico models. The predictions using various in silico model approaches in Simcyp™ Simulator (minimal and full PBPK model, dissolution input using DRM and DLM) successfully bracketed in vivo data on drug administration during ARA therapy and correctly predicted an overall decrease in plasma concentration for the two model weakly basic compounds and an increase in plasma concertation for the model weakly acidic compound.
In all assessed scenarios, the ARA methods proved to be an essential part of evaluating and predicting the impact of ARAs on drug pharmacokinetics, and appropriately predicted the extent of a possible impact of ARAs on the drug plasma profiles. Thus, the ARA biorelevant media and dissolution tests were demonstrated to be valuable tools reflecting administration of drugs when the gastric pH is elevated and able to predict the impact of ARA therapy on drug administration.
The ability to evaluate the impact of human (patho) physioloy on drug behaviour in the gastrointestinal tract is of great importance, as the GI conditions play a significant role in drug release and absorption. Thus, there is great interest on the part of the pharmaceutical industry and regulatory agencies to develop best practices in this field, especially for pH-dependent DDIs. The media and dissolution tests developed in this thesis are biorelevant methods appropriate for evaluation of the impact of elevated gastric pH on drug efficacy and safety. Such methods, used as a risk assessment tool, in connection with evaluation of the efficacy window and potential toxicity, may help to increase confidence about decisions as to whether a pH-effect will occur and whether it is relevant or not, prior to conducting clinical studies. They may also enable changes in inclusion/exclusion criteria during recruiting for large-scale efficacy trials. In fact, the biopharmaceutic approach to drug development is becoming standard practice on a number of fronts, including metabolic DDIs, renal and hepatic insufficiency, powering decision-making process and possibly even waiving certain types of clinical studies.
...
Bacteria are true artists of survival, which rapidly adapt to environmental changes like pH shifts, temperature changes and different salinities. Upon osmotic shock, bacteria are able to counteract the loss of water by the uptake of potassium ions. In many bacteria, this is accomplished by the major K+ uptake system KtrAB. The system consists of the K+-translocating channel subunit KtrB, which forms a dimer in the membrane, and the cytoplasmic regulatory RCK subunit KtrA, which binds non-covalently to KtrB as an octameric ring. This unique architecture differs strongly from other RCK-gated K+ channels like MthK or GsuK, in which covalently tethered cytoplasmic RCK domains regulate a single tetrameric pore. As a consequence, an adapted gating mechanism is required: The activation of KtrAB depends on the binding of ATP and Mg2+ to KtrA, while ADP binding at the same site results in inactivation, mediated by conformational rearrangements. However, it is still poorly understood how the nucleotides are exchanged and how the resulting conformational changes in KtrA control gating in KtrB is still poorly understood.
Here,I present a 2.5-Å cryo-EM structure of ADP-bound, inactive KtrAB, which for the first time resolves the N termini of both KtrBs. They are located at the interface of KtrA and KtrB, forming a strong interaction network with both subunits. In combination with functional and EPR data we show that the N termini, surrounded by a lipidic environment, play a crucial role in the activation of the KtrAB system. We are proposing an allosteric network, in which an interaction of the N termini with the membrane facilitates MgATP-triggered conformational changes, leading to the active, conductive state.
The phospholipid bilayers are the primary constituents of the membrane in living cells in which lipids are hold together in bilayer leaflets through a combination of different forces into the liquid crystalline (Lα) phase. Despite their thin fragile formations, the phospholipid bilayers are responsible for performing a variety of important tasks in the cells, some of which are carried out directly by the lipid bilayers and some by various integral proteins embedded within the bilayers. There have been continues efforts over the past decades to replicate the compound biophysical properties of living cell membranes in model lipid bilayers.
An important question remains unanswered: is it possible to replicate physical properties under “non-equilibrium” conditions as found in cell membranes in model lipid bilayers? In almost all previous studies, the model lipid bilayers were under static conditions – for instance, at zero lateral pressure. However, in living organisms, the cell membranes are involved in continuous (nonequilibrium) exchange and (or) transport of lipid species with the surrounding environment which consequently leads them to experience continuous lateral pressure variations. One suitable in vitro approach is to spatiotemporally control the model lipid bilayers over a time period during which they can be spatially stimulated at a level compatible to that found under in vivo conditions. This can be achieved with high spatiotemporal resolution by making lipids light-dependent through implementation of azobenzene photoswitch in their structures.
In this study, a specific azobenzene containing photolipid (AzoPC) is integrated into POPE:POPG bilayers (POPE: 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine, POPG: 1-palmitoyl-2-oleoyl-sn-glycero-3-phospho-(1'-rac-glycerol)) at ~14 mol% to construct a photo responsive model bilayers entitled as photoliposomes. Magic angle spinning solid-state NMR spectroscopy (MAS-NMR) at high field (850 MHz) is the measurement technique of choice by which it is possible to pursue the dynamics (fluidity) of the bulk lipids within the photoliposomes at atomistic resolution. It is shown that the AzoPCs undergo an efficient trans-to-cis isomerization (~85%) within the photoliposomes as the result of UV light absorption, and thermally relax back to the trans state during a period of ~65 h under the MAS measurement conditions. The order parameter measurements based on the C−H dipolar couplings reveal that the non-equilibrium cis-to-trans thermal isomerization impact of AzoPC on the fluidity of the bulk lipid is highly localized – the fluidity perturbations originate from specific order parameter changes in the middle section of the bulk lipid acyl chains. Further 1H NOESY measurements confirm the hypothesis that the azoswitch topologies in either cis and trans conformer of the photolipid is the key parameter in localized alteration of the C−H order parameters along the bulk lipid acyl chains.
Diacylglycerol kinase (DgkA) from E. coli is an enzyme responsible for the phosphorylation of diacylglycerol to phosphatidic acid, at the expense of adenosine triphosphate. Structurally, DgkA is a homo oligomer composed of three symmetric 14 kDa protomers, each of which has three transmembrane helices and one surface helix. Upon embedding within the photoliposomes, it is shown that DgkA enhances the AzoPC localization impact on the fluidity of the bulk lipids. In this regard, the results of a series of statistical simulations of lipid lateral diffusions along the bilayer leaflets in presence and absence of embedded proteins are accompanied with those of experimentally measured based upon which it is justified that membrane proteins markedly limit lipid lateral diffusions in the bilayers. In case of the DgkA proteo-liposomes with lipid-to-protein ratio of 50, it is estimated that the diffusion coefficient of lipids is above 2-fold lower compared to that of the protein free liposomes.
The cis-to-trans AzoPC isomerization and its following consequence in localized alteration of the bulk lipid fluidity is further investigated on the structural dynamics and enzymatic functionality of the embedded DgkA within the proteo-photoliposomes. It is revealed that DgkA structural dynamics are perturbated in a multi-scale, complex manner. The dynamics of residues located in different regions of DgkA changes with the light-induced AzoPC isomerization, but their time courses differ from residue to residue. For example, 29Ala, a residue on the hinge between the surface helix and membrane helix-1, exhibits the steepest time-dependent cross peak intensity changes in time-resolved NCA spectra. The impact of the lasting membrane fluidity perturbation on the enzymatic functionality of the embedded DgkA is subsequently measured which demonstrates a significant variation under cis- and trans-AzoPC conformations within the proteo-photoliposomes.
The knob-associated histidine-rich protein (KAHRP) plays a pivotal role in the pathophysiology of Plasmodium falciparum malaria by forming membrane protrusions in infected erythrocytes, which anchor parasite-encoded adhesins to the membrane skeleton. The resulting sequestration of parasitized erythrocytes in the microvasculature leads to severe disease. Despite KAHRP being an important virulence factor, its physical location within the membrane skeleton is still debated, as is its function in knob formation. Here, we show by super-resolution microscopy that KAHRP initially associates with various skeletal components, including ankyrin bridges, but eventually colocalizes with remnant actin junctions. We further present a 35 Å map of the spiral scaffold underlying knobs and show that a KAHRP-targeting nanoprobe binds close to the spiral scaffold. Single-molecule localization microscopy detected ~60 KAHRP molecules/knob. We propose a dynamic model of KAHRP organization and a function of KAHRP in attaching other factors to the spiral scaffold.
Chlorsilane stellen Schlüsselsubstanzen zur Herstellung von elementarem Silicium dar. Zum Beispiel ist HSiCl3 ein wichtiger Ausgangsstoff im Siemensprozess[1, 2]. Chlorsilane werden unter anderem zur Herstellung von Silikonen im Müller-Rochow-Prozess[3-5] verwendet. Bei beiden Prozessen werden Silylene[6-10] als Schlüsselmediate in den Reaktionen angenommen. So auch bei der Bildung von höheren Perchlorsilanen (Reaktion b), die nur in Form komplexer Polymergemischen erhalten werden. In der vorliegenden Dissertation wurde die Plausibilität eines auf Silylen basierenden Reaktionsmechanismus zur Bildung und Reaktivität von Chlorsilanen quantenchemisch untersucht.Mit den Berechnungen aus dieser Arbeit konnten diese molekularen Prozesse aufgeklärt werden[33-35].
Die quantenchemischen Rechnungen aus dieser Arbeit umfassen Kalibrierungsrechnungen an Chlorsilanen, um die Leistungsfähigkeit der quantenchemischen Methoden zu beurteilen.
Hierbei wurden berechnete Strukturen mit den experimentellen verglichen. Zusätzlich wurden Standardbildungsenthalpien berechnet, um diese auch mit den experimentellen Daten zu vergleichen. Nach Prüfung der Validität der Referenzmethoden wurde die Tragfähigkeit der rechengünstigeren Methoden der Dichtefunktionaltheorie evaluiert.
In Vereinbarung von Rechenaufwand und Genauigkeit einer Rechenmethode wurden thermochemische Stabilitäten, Reaktionsenergien zur Bildung von Chlorsilanen aus Schema 1 berechnet. Die Betrachtung der Reaktionsmechanismen erfolgte sowohl in der Gasphase als auch in Lösung. Dabei wurden die Bildung von cyclo-Chlorsilanen, kettenförmigen und verzweigten Chlorsilanen betrachtet. Unterstützend konnten alle Intermediate und Produkte unter Verwendung der ausgewählten quantenchemischen Methode mit 29Si-NMR-Rechnungen begleitet werden. Hierbei wurden auch Vergleichsdaten von nicht literaturbekannten 29Si-NMR Verschiebungen erstellt.
In the recent years, myxobacteria have emerged as a novel source of natural compounds with structural diversity and biological activity for drug discovery. In this work, the two myxobacterial compounds archazolid and vioprolide were characterized for their potential pharmacological effects in vascular endothelial cells. Archazolid is a wellestablished v-ATPase inhibitor found in Archangium gephyra and Cystobacter spec. As the v-ATPase represents a promising target in cancer treatment, the effects of archazolid have been intensively studied in cancer cells, but rarely in endothelial cells. Vioprolide is an antifungal and cytotoxic metabolite obtained from Cystobacter violaceus. There are only few studies on vioprolide, most of them focusing on its biosynthesis. Preliminary studies revealed that it inhibited TNF-induced expression of ICAM-1, indicating possible anti-inflammatory properties. As the endothelium plays an important role in cancer and inflammation, it represents an attractive drug target. Therefore, the archazolid and vioprolide were investigated regarding their effects on endothelial cells.
V-ATPase inhibition by archazolid resulted in anti-tumor and anti-metastatic effects in vitro and in vivo. Archazolid was used to study the consequences of v-ATPase inhibition in endothelial cells that might contribute to the anti-metastatic activities observed in vivo. To analyze the impact of archazolid on the interaction endothelial and cancer cells, in vitro cell adhesion and transmigration assays were performed using primary HUVEC or immortalized HMEC-1 and different cancer cell types (MDA-MB-231, PC-3 and Jurkat cells). For these experiments, only the endothelial cells were treated with archazolid. VATPase inhibition by archazolid led to an increased adhesion of the metastatic breast cancer cell line MDA-MB-231 and prostate cancer cell line PC-3 onto endothelial cells whereas the adhesion of Jurkat cells was unaffected. Interestingly, archazolid treatment of HUVECs decreased the transendothelial migration of MDA-MB-231 cells. Endothelial ICAM-1, VCAM-1, E-selectin and N-cadherin are potential ligands of interacting cancer cells. Therefore, the mRNA and surface protein levels of these cell adhesion molecules were measured via qRT-PCR and flow cytometry, respectively. These adhesion molecules were not responsible for the archazolid-induced cancer cell adhesion, as archazolid treatment of HUVECs did not upregulate their mRNA or surface expression. Instead, cell adhesion assays using a monoclonal antibody against integrin subunit β1 showed that β1-integrins expressed on MDA-MB-231 and PC-3 cells mediated the archazolid-induced cancer cell adhesion. Cell adhesion assays onto plastic coated with ECM components which are the major ligands of β1-integrins, revealed that MDA-MB231 and PC-3 cells preferably interact with collagen. So next, we investigated the influence of archazolid on surface collagen levels in HUVECs by immunostaining, which demonstrated an increase of nearly 50 % upon archazolid treatment. We confirmed the hypothesis that the expression and activity of cathepsin B, a lysosomal enzyme that degrades extracellular matrix components including collagen, was inhibited by archazolid in endothelial cells. Finally, overexpression of cathepsin B reduced the cancer cell adhesion on archazolid-treated HUVECs, but also in control cells, indicating a negative correlation between cathepsin B expression and cancer cell adhesion.
The influence of vioprolide on the interaction of endothelial cells with leukocytes was analyzed by in vitro cell adhesion assays using HUVECs and primary monocytes, THP-1 or Jurkat cells. Vioprolide inhibited the adhesion of these cells onto TNF-activated HUVECs. In addition, the endothelial-leukocyte interaction was observed in vivo by intravital microscopy in the mouse cremaster muscle. Vioprolide prevented the TNFinduced firm adhesion and transmigration of leukocytes, while leukocyte rolling was not affected. ICAM-1, VCAM-1 and E-selectin are cell adhesion molecules, which are upregulated by TNF and mediate leukocyte adhesion onto endothelial cells. Therefore, flow cytometric analysis was performed to measure their surface expression. Vioprolide significantly decreased TNF-induced expression of surface ICAM-1, VCAM-1 and E-selectin, which was in line with the in vitro results. In vivo, vioprolide may act in a different way on E-selectin expression, so that leukocyte rolling, which is governed by E-selectin, remained unaffected. qRT-PCR experiments revealed that the mRNA expression of ICAM-1 and VCAM-1 were also reduced by vioprolide, indicating a regulation on transcriptional level. In contrast, the mRNA expression of E-selectin was not decreased at the timepoint when surface protein expression was diminished. The induction of these cell adhesion molecules is mainly mediated by the transcription factor NFκB. A Dual-Luciferase® reporter assay was used to study the impact of vioprolide on the TNF-induced NFκB promotor activity. Vioprolide blocked the TNF-induced NFκB promotor activity while the TNF-induced IκBα degradation and nuclear translocation of the NFκB subunit p65 was not altered by vioprolide. Western blot analysis revealed that vioprolide had no effect on the activation of MAPK (p38, JNK) and AKT by TNF, which could interfere with the NFκB-dependent gene expression.
Taken together, archazolid and vioprolide are interesting myxobacterial compounds with different modes of actions. The study suggests that the v-ATPase inhibitor archazolid impairs the expression and activity of cathepsin B in endothelial cells, which leads to a higher amount of collagen on the endothelial surface. As a result, the adhesion of β1-integrin expressing metastatic cancer cells onto archazolid-treated endothelial cells increased while transendothelial migration was reduced. Further, archazolid represents a promising tool to elucidate the role of v-ATPase in endothelial cells. Vioprolide was able to prevent TNF-induced endothelial-leukocyte interaction in vitro and in vivo by interfering with NFκB-dependent gene expression. Further research is required to enlighten the underlying mechanism and the direct target of vioprolide.
The overall survival for patients with acute lymphoblastic leukemia (ALL) often is the function of age, in particular in 2019 analysis revealed that 5-year overall survival for patients older than 20 years remains below 35% (American Cancer Society, Cancer Facts &Figures 2019). Importantly, one of the major issues in ALL therapy is the ability of tumor cells to escape the treatment via the establishment of an immunosuppressive environment. The tumor microenvironment has gained tremendous importance in the past decade. This is largely based on the reasoning that, in order to devise better therapeutic strategies for patients, we need to gain better understanding into how malignant cells transform their microenvironment to promote growth, escape immune control and gain therapeutic resistance.
TAM receptors (TAMRs) are engaged in innate immune cells as a feed-back mechanism to terminate the immune response and promote the return to homeostasis (Rothlin et al. 2007). In the context of cancers, aberrant TAMR signaling was mainly explored concerning its pro-oncogenic function (Paolino and Penninger 2016). There are only limited data available suggesting the modulation of cancer immune response via TAMR signaling in highly immunogenic solid tumor models (Paolino et al. 2014; Ubil et al. 2018). So far, however, little is known about their potential indirect immune-modulatory function in hematological malignancies. Taking into account the pronounced importance of TAMR signaling in immune cells combined with the leukemic immune tolerance, the current study focused on the function of TAMR and their ligands in anti-leukemic immunity.
This work uncovers the mechanism of dampening anti-leukemic immune response via TAMR signaling on macrophages using the syngeneic BCR-ABL1 B-ALL mouse model. Using genetic depletion of GAS6 in the host environment or ablation of AXL and/or MERTK receptors in macrophages the bone marrow microenvironment could be rewired in order to achieve an efficient anti-leukemic immune response. In particular, the GAS6/AXL blockade triggers an effective NKand T- cell-dependent anti-leukemic response that results in prolonged survival. This finding specifically tackles the obstacle of inefficient bridging between innate and adaptive immune response typical for hematological malignancies in contrast to solid tumors (E. K. Curran, Godfrey, and Kline 2017).
Besides establishing the vital function of TAMR signaling in anti-leukemic immunity using murine models, the analysis of human blood plasma revealed that age-related immune dysregulation was manifested by significant GAS6 decrease and PROS1 upregulation among elderly donors (>60 y.o.) compared to controls (<25 y.o.). These data are indicative that TAMR signaling likely favors the age-dependent immune system decline, which in turn is associated with a poor survival rate of elderly patients diagnosed with leukemia.
In conclusion, using a preclinical ALL model here it was identified in vivo, that Axl significantly increases upon B-ALL challenge in Mph and NK cells. Therefore, AXL targeting, using the orally bioavailable selective inhibitor Bemcentinib, could serve as a powerful approach to revert early immunosuppression created by leukemia.
Taken together these data propose the AXL receptor as a novel immune checkpoint and attractive candidate for the development of a new therapeutic approach via unleashing the patient’s own immune system to combat leukemic cells.
T-cell development is a highly dynamic and stepwise process comprimising T lineage commitment, T-cell receptor (TCR) gene rearrangements and subsequent selection. From a quantitative point of view, only a few hundred progenitor cells migrate from the bone marrow into the thymus. Developing thymocytes (termed double negative (DN), CD4-CD8-) can be further divided into DN1-4 cells based on the expression of CD25 and CD44. These developmental events are interspersed by proliferative bursts which ultimately lead to the generation of millions of double positive (DP, CD4+CD8+) thymocytes that then undergo selection. As a consequence, a proportion of naïve T-cells evolves to ensure adaptive, but not autoreactive immunity.
Previous studies of our lab focused on the quantification of thymus colonization and identified thymus entry to be dependent on expression of the chemokine receptors CCR7 and CCR9 (Krueger et al., 2010; Ziętara et al., 2015). CCR7/9 double knockout (DKO) mice are almost completely devoid of the most immature thymocyte populations (DN1 and DN2), but show near normal DN3 cellularity. Interestingly, a similar defect during early development but a virtually complete recovery of later stages and total thymocyte numbers was also observed in thymi of miR-17~92 deficient mice. Here, a failure of prethymic IL-7 signaling dampens early T-cell development (Regelin et al., 2015). For this reason, we hypothesized a tight regulation of thymocyte population size through alterations in the underlying cell cycle kinetics.
In this thesis, we employed in vivo single- and dual-nucleoside pulse labeling combined with determination of DNA replication over time in different WT thymocyte subsets at steady-state. Based on this, we assessed alterations in cell cycle kinetics of CCR7/9 and miR-17~92 defcicient mice and identified compensatory mechanisms of thymocytes on the level of cell cycle phase distribution and cell cycle speed. In addition, single-cell RNA sequencing helped to obtain information on cell cycle dynamics of early thymocyte subsets, exemplarily shown for WT and CCR7/9 DKO mice. Lastly, we performed cell cycle analyses in a model of endogenous thymic repair upon sublethal total body irradiation which provided insight into intrathymic cell cycle regulation as an adjustable system to re-establish normal thymus cellularity.
In the second part of the thesis, we addressed the role of miR-21 in the thymus. In various studies, we and others identified miRNAs as key posttranscriptional regulators of the immune system and especially for T-cell development (Regelin et al. 2015; Mildner et al. 2017; Li et al. 2007; Ebert et al. 2009; Ziętara et al. 2013; Schaffert et al. 2015). The dynamic expression of miR-21 during T-cell development (Neilson et al. 2007; Kirigin et al. 2012; Kuchen et al. 2010) prompted us to hypothesize that miR-21 has a regulatory function in the thymus. A miR 21-knockout mouse model allowed us to study the role of this miRNA for the development of T-cells in the thymus and the maintenance of T-cells in the periphery. In addition, we performed competitive bone marrow chimera experiments in the context of miR-21 deficiency and overexpression. Further insights were provided by exploring the function of miR-21 in negative selection in vivo as well as in T-cell differentiation in coculture experiments in vitro. To unravel implications of miR-21 to regulate cellular stress responses, we assessed the contribution of miR-21 in a model of endogenous regeneration of the thymus after sublethal irradiation. We could not provide evidence for a prominent role for miR-21 during T-cell development. Together, our experiments revealed that miR-21 is largely dispensable for physiologic T-cell development despite high and dynamic expression in the thymus (Kunze Schumacher et al., 2018). The apparent discrepancy between dynamic expression but lack of a regulatory function in the thymus led us to conclude that miR-21 is rather fine tuning T-cell responses than controlling a developmental event.
Identifizierung potenzieller Taspase1 Inhibitoren für die Behandlung von t(4,11) akuter Leukämie
(2022)
Leukämie ist die häufigste bösartige Krebserkrankung im Kindes- und Jugendalter. Bei einem Kind von 1120 Kindern wird Leukämie diagnostiziert, dabei trifft diese Diagnose Jungen 30 % häufiger als Mädchen. Die Krankheitssymptome treten bei den Kindern noch vor dem Schulalter auf und am häufigsten haben die Kinder mit der akuten Form zu kämpfen. Bei einer Diagnose mit einer akuten lymphatischen Leukämie (ALL) haben die Kinder meist eine gute Prognose, während bei der akuten myeloischen Leukämie (AML) eine deutlich schlechtere.1
Die t(4;11)(q21;q23) Translokation ist aufgrund ihres häufigen Auftretens und der damit schlechten verbundenen Prognose eines der bekanntesten strukturellen Chromosomen-anomalien bei akuten Leukämien. Diese Translokation wurde das erste Mal 1977 von Oshimura et al. beschrieben.2 Bei einer t(4;11)-Translokation ist das Chromosom 4 und das Chromosom 11 involviert. Auf Chromosom 4 ist das AF4-Gen lokalisiert (AFF1) und auf dem Chromosom 11 liegt das MLL-Gen (ALL-1, HRX, hTRX, KMT2A).
Taspase1 wurde als ein proteolytisch prozessierendes Enzym identifiziert, das sich in Wirbellosen und Vertebraten zusammen mit Mitgliedern der Trithorax/MLL/KMT2A-Protein¬familie koevolviert hat. Taspase1 prozessiert nicht nur das MLL und MLL2, deren Fusions¬proteine AF4-MLL, sondern auch den Transkriptionsfaktor IIA (TFIIA) sowohl in vitro als auch in vivo.3
Die Dimerisierung von Taspase1 löst eine intrinsische Serinproteasefunktion aus, die zum katalytischen Rest Thr234 führt, der die Konsensussequenz Q-3X-2D-1•G1X2D3D4 katalysiert, die in Mitgliedern der MLL-Familie sowie im Transkriptionsfaktor TFIIA vorhanden ist. Taspase1 ist kein klassisches Enzym, da es seine Zielproteine stöchiometrisch hydrolysiert. Diese Eigenschaft macht es nahezu unmöglich, in einem klassischen Screening-Setup nach potenziellen Inhibitoren zu screenen.
In dieser Arbeit wurde ein Homogeneous time-resolved fluorescence HTRF-Reporter-Assays etabliert. Das etablierte Testsystem ermöglicht erstmalig die Untersuchung von Substanzen zusammen mit Taspase1 Monomere, die in einem zellfreien System (cfs) hergestellt wurden. Durch die Expression non monomeren Taspase1 Proteinen sollten Inhibitoren durch das etablierte Screening-Verfahren gefunden werden, die sowohl (1) Dimerisierung, (2) Autoaktivierung oder (3) Substratbindung selektiv blockieren können. Die durchgeführten Experimente führten zur Identifikation eines ersten Taspase1-Inhibitors, Closantel sodium. Closantel sodium ist ein U.S. Food and Drug Administration (FDA) zugelassenes Medikament, das Taspase1 auf nicht-kovalente Weise bindet. Die erzielten Daten zeigen, dass Closantel sodium den Dimerisierungsschritt und/oder die intrinsische Serinproteasefunktion blockiert. Closantel sodium hemmte die Spaltung des eingesetzten CS2-Substratproteins mit einem IC50 zwischen 1,6 und 3,9 µM, je nachdem, welches Taspase1-Präparat in dem HTRF Screening Assay ver¬wendeten (cfs- oder E.coli-produziert). Die Daten weisen darauf hin, dass Closantel sodium als allosterischer Inhibitor gegen die Taspase1 fungiert. Taspase1 wird zur Aktivierung der AF4-MLL-Onkofusionsproteine benötigt und wird auch in mehreren soliden Tumoren überexprimiert. Daher könnte dieser neue Inhibitor für die weitere Validierung von Taspase1 als Ziel für die Krebstherapie und für das Design potenterer Liganden für zukünftige klinische Anwendungen nützlich sein.
The specific and precise arrangement of proteins and biomolecules in 3D is an important prerequisite for the study of cell migration, cellular signal transduction and the production of artificial tissue. In a variety of research approaches, proteins have been immobilized on rigid surfaces such as glass or gold to observe protein-protein or protein-cell interactions. While these commonly used analytical platforms offer advantages such as rapid washing steps and easy use, due to their rigidity and two-dimensionality, they cannot replicate the extracellular matrix (ECM) the native environment of cells. This severe deviation from the natural environment results in significant changes in cell structure and cellular processes such as the polarization of the cell, its morphology, and signal transduction. In order to maintain the functionality of the immobilized proteins, it is also enormously important that the proteins are oriented and anchored in the material under mild conditions.
An immobilization strategy that makes this possible is bioaffinity. For this, the specific interaction of a biomolecule with an interaction partner anchored on a surface is used to immobilize the biomolecule. Such an interaction is for example the nitrilotriacetic acid (NTA)/His-tag binding. NTA is a chelator molecule that, when bound to divalent metal ions such as Ni(II), forms an octahedral complex with oligohistidines. The oligo histidine-tag can be competed out of the complex by free histidine or imidazole due to structural similarity. This is exploited in immobilized metal affinity chromatography (IMAC). The binding of a monoNTA/His-tag complex (KD=10 µM) is not stable enough to be used for immobilizations. Therefore, multivalent variants of the chelator were developed, like trisNTA which has a high affinity for His6 tagged proteins (KD= 10 nM). The PA-trisNTA developed in a preliminary work was the first light-activatable system based on the trisNTA chelator head.
The aim of this work was to synthesize a new two-photon (2P) activatable trisNTA (TPA trisNTA) interaction molecule, to analyze its photophysical characteristics and to apply it for two- and three dimensional (2D/3D) biomolecule patterning. The final goal was to use TPA trisNTA for cellular applications in order to manipulate membrane protein organization. Therefore, TPA trisNTA was designed to maintain a stable autoinhibition enabling the immobilization of proteins under physiological conditions with high precision in the x/y, as well as z dimension only upon light activation. 2P activation brings some outstanding advantages: i) the use of near-infrared (NIR) light is less harmful to cells compared to ultraviolet (UV) light, ii) the longer wavelength allows the radiation to penetrate deeper into tissues, iii) the precision of focal irradiation is more accurate because only a focal volume (about 1 fL) is excited and, unlike UV light, scattered light does not lead to activation.
Several backbones for TPA-trisNTA were considered as 2P cleavable groups due to their 2P absorption ability and small size: 3 nitrodibenzofuran (NDBF), 6 bromo 7 hydroxycoumarin (Bhc), and 7 diethylaminocoumarin (DEAC). Initially, suitable synthetic routes were developed for the respective carbaldehydes, since these represented an important intermediate for both the construction of amino acid (aa) derivatives as well as ß hydroxy acids. ß Hydroxy acids were important intermediates because their photocleavage differs from aa derivatives. To establish the conversion from carbaldehydes to hydroxy acids via Reformatsky reaction, commercially available carbaldehydes of the nitroveratral (NV) or nitropiperonal (NP) group were used in addition. The conversion of NDBF, NV, NP proved to be difficult, whereas the ß-hydroxy acid was successfully synthesized from Bhc as well as from DEAC.
Starting from DEAC ß hydroxy acid, a Fmoc protected amino acid derivative was synthesized. To ensure high cleavage efficiency, the DEAC ß hydroxy acid was linked to monoFmoc ethylenediamine through a carbamate linker. Subsequently, the photocleavable group was successfully incorporated into the linker of TPA-trisNTA by solid-phase peptide synthesis (SPPS).
The functional principle of TPA-trisNTA, similar to PA-trisNTA, is based on the autoinhibition of the multivalent chelator head trisNTA, which is linked to an intramolecular oligohistidine sequence by a peptide linker. In presence of Ni(II) ions, trisNTA forms a metal ion-mediated complex with histidine, causing TPA-trisNTA to self-inactivate. The cleavage site is the DEAC based photocleavable amino acid. In contrast to PA-trisNTA, the incorporation of two photocleavable amino acids was omitted. Instead, only one photocleavable DEAC was incorporated in front of the His tag. To avoid a second DEAC group within the His tag, a His5 tag was used instead of an His6 tag. It is known from preliminary work that a His5 tag is sufficient to maintain autoinhibition in the presence of His6-tagged proteins of interest (POIs), but can be displaced from the complex after light-driven cleavage of the peptide backbone. Placement of a cysteine in the peptide linker between the trisNTA and the DEAC group allowed for permanent surface anchoring after photocleavage of the linker.
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Treatment of hexachloropropene (Cl2C[double bond, length as m-dash]C(Cl)–CCl3) with Si2Cl6 and [nBu4N]Cl (1 : 4 : 1) in CH2Cl2 results in a quantitative conversion to the trisilylated, dichlorinated allyl anion salt [nBu4N][Cl2C[double bond, length as m-dash]C(SiCl3)–C(SiCl3)2] ([nBu4N][1]). Tetrachloroallene Cl2C[double bond, length as m-dash]C[double bond, length as m-dash]CCl2 was identified as the first intermediate of the reaction cascade. In the solid state, [1]− adopts approximate Cs symmetry with a dihedral angle between the planes running through the olefinic and carbanionic fragments of [1]− of C[double bond, length as m-dash]C–Si//Si–C–Si = 78.3(1)°. One-electron oxidation of [nBu4N][1] with SbCl5 furnishes the distillable blue radical 1˙. The neutral propene Cl2C[double bond, length as m-dash]C(SiCl3)–C(SiCl3)2H (2) was obtained by (i) protonation of [1]− with HOSO2CF3 (HOTf) or (ii) H-atom transfer to 1˙ from 1,4-cyclohexadiene. Quantitative transformation of all three SiCl3 substituents in 2 to Si(OMe)3 (2OMe) or SiMe3 (2Me) substituents was achieved by using MeOH/NMe2Et or MeMgBr in CH2Cl2 or THF, respectively. Upon addition of 2 equiv. of tBuLi, 2Me underwent deprotonation with subsequent LiCl elimination, 1,2-SiMe3 migration and Cl/Li exchange to afford the allenyl lithium compound Me3Si(Li)C[double bond, length as m-dash]C[double bond, length as m-dash]C(SiMe3)2 (Li[4]), which is an efficient building block for the introduction of Me, SiMe3, or SnMe3 (5) groups. The trisilylated, monochlorinated allene Cl3Si(Cl)C[double bond, length as m-dash]C[double bond, length as m-dash]C(SiCl3)2 (6), was obtained from [nBu4N][1] through Cl−-ion abstraction with AlCl3 and rearrangement in CH2Cl2 (1˙ forms as a minor side product, likely because the system AlCl3/CH2Cl2 can also act as a one-electron oxidant).
Photoacids attract increasing scientific attention, as they are valuable tools to spatiotemporally control proton-release reactions and pH values of solutions. We present the first time-resolved spectroscopic study of the excited state and proton-release dynamics of prominent merocyanine representatives. Femtosecond transient absorption measurements of a pyridine merocyanine with two distinct protonation sites revealed dissimilar proton-release mechanisms: one site acts as a photoacid generator as its pKa value is modulated in the ground state after photoisomerization, while the other functions as an excited state photoacid which releases its proton within 1.1 ps. With a pKa drop of 8.7 units to −5.5 upon excitation, the latter phenolic site is regarded a super-photoacid. The 6-nitro derivative exhibits only a phenolic site with similar, yet slightly less photoacidic characteristics and both compounds transfer their proton to methanol and ethanol. In contrast, for the related 6,8-dinitro compound an intramolecular proton transfer to the ortho-nitro group is suggested that is involved in a rapid relaxation into the ground state.
The knob-associated histidine-rich protein (KAHRP) plays a pivotal role in the pathophysiology of Plasmodium falciparum malaria by forming membrane protrusions in infected erythrocytes, which anchor parasite-encoded adhesins to the membrane skeleton. The resulting sequestration of parasitized erythrocytes in the microvasculature leads to severe disease. Despite KAHRP being an important virulence factor, its physical location within the membrane skeleton is still debated, as is its function in knob formation. Here, we show by super-resolution microscopy that KAHRP initially associates with various skeletal components, including ankyrin bridges, but eventually colocalizes with remnant actin junctions. We further present a 35 Å map of the spiral scaffold underlying knobs and show that a KAHRP-targeting nanoprobe binds close to the spiral scaffold. Single-molecule localization microscopy detected ~60 KAHRP molecules/knob. We propose a dynamic model of KAHRP organization and a function of KAHRP in attaching other factors to the spiral scaffold.
Komplexe biologische Phänotypen resultieren aus einem koordinierten Zusammenspiel von einer Vielzahl von Genen. Um zu verstehen, wie Krankheiten durch genetische Dysfunktionen
entstehen können, ist es unabdingbar die genetischen Interaktionsnetzwerke in menschlichen Zellen zu entschlüsseln. Eine Identifizierung von Kontext-abhängigen genetischen Interaktionen kann bedeutende Erkenntnisse über die Beziehung von Phänotyp und Genotyp liefern und erklären, wie synergistische Gen-Funktionen die Entstehung von komplexen Krankheiten bedingen.
Gepoolte, kombinatorische CRISPR (kurz für: clustered regularly interspaced short palindromic repeats) Screens stellen eine wirkungsvolle Methode zur simultanen Untersuchung potentieller Interaktionen von einer großen Anzahl von Genen dar. Mit sogenannten multiplex CRISPR
gRNA Bibliotheken werden im Rahmen großangelegter Screens vielzählige kombinatorische Gen-Knockouts in Zellen generiert. Diese multiplex CRISPR gRNA Bibliotheken können aus bis zu hunderttausenden Plasmiden bestehen, die jeweils für eine andere gRNA-Kombination kodieren und auf ein spezifisches Gen-Paar abzielen. Im Gegensatz zu CRISPR Screens für Einzel-Knockouts gehen multiplex CRISPR Screens zur Identifizierung von genetischen Interaktionen mit zusätzlichen Herausforderungen einher: Zum einen wächst der verbundene Arbeitsaufwand für die Konstruktion der multiplex CRISPR gRNA Bibliotheken proportional mit der Anzahl der gewünschten Ziel-Gene, welche die Diversität der Bibliothek bestimmt. In einer idealen gRNA-Bibliothek wären alle gRNA-Sequenzen gleich häufig vorhanden. Jedoch weisen
gRNA-Bibliotheken aufgrund von technischen Beschränkungen gRNA-Sequenzen mit höherer, beziehungsweise niedriger Abundanz auf. Konventionelle Methoden zur Herstellung von
gRNA-Bibliotheken basieren beispielsweise auf iterativen, gepoolten Klonierungsschritten mit PCR-amplifizierten Oligonucleotiden, welche zu einer Ungleichverteilung oder zum Verlust von gRNA-Sequenzen führen können. Daher bieten Methoden zur gRNA-Bibliotheken-Generierung Optimierungspotenzial. Da die Reproduzierbarkeit der Screen-Ergebnisse durch die sogenannte Screening Coverage sichergestellt werden muss, erfordert eine Erhöhung der
Bibliotheks-Diversität gleichzeitig auch eine Vergrößerung des Versuchsmaßstabs und ist mit umfangreichem Zellkultur-Arbeitsaufwand verbunden. Die Screening Coverage gibt die
durchschnittliche Abundanz der einzelnen gRNA-Sequenzen in der Zellpopulation während des Screens an. Aktuelle Richtlinien empfehlen eine Screening Coverage, die zwischen dem 200- bis 1000-fachen Wert der Bibliotheks-Diversität liegt, allerdings fehlen bisher genaue Angaben die auf die verwendete gRNA Bibliothek abgestimmt sind. Deshalb stellt die benötigte Screening Coverage bisher einen limitierenden Faktor dar, der die Anzahl der möglichen Ziel-Gene-Kombinationen in einem Screen beschränkt.
In der vorliegenden Arbeit stellen wir eine neue Methode zur Generierung von multiplex gRNA Bibliotheken mit hohen Diversitäten vor. Die Methode, genannt 3Cs (covalently-closed circular-synthesized) Multiplexing, umgeht iterative, gepoolte Klonierugsschritte mit Restriktionsenzymen und PCR-Amplifikation von gRNA-kodierenden Oligonucleotiden. Wir
zeigen, dass 3Cs Multiplexing auf robuste Weise zur Herstellung von gleichmäßig verteilten multiplex gRNA Bibliotheken verwendet werden kann. Der Verteilungs-Skew, auch Skew-Ratio oder Bibliotheksbreite genannt, ist ein Maß zur Ermittlung der Gleichverteilung der gRNA-Sequenzen in der Bibliothek. Wir zeigen, dass 3Cs multiplex Bibliotheken typischerweise einen Verteilungs-Skew von 2.5 aufweisen, was unter den üblichen Werten von Einzel-gRNA Bibliotheken liegt.
Wir nahmen an, dass die gRNA-Bibliotheksverteilung die Robustheit von gepoolten CRISPR Screens beeinflussen könne und deshalb bei der Auswahl einer geeigneten Screening
Coverage berücksichtigt werden müsse. Um den Einfluss der gRNA-Bibliotheksverteilung auf die Screen-Qualität in Abhängigkeit von der verwendeten Screening Coverage zu untersuchen, generierten wir zwei künstlich fehlverteilte multiplex gRNA-Bibliotheken. Diese wurden, zusätzlich zu einer nahezu gleichverteilten multiplex gRNA-Bibliothek, jeweils mit einer 20- und 200-fachen Screening Coverage in einem kombinatorischen Proliferationsscreen angewandt.
Dadurch konnten wir die gRNA-Bibliotheksverteilung als den bestimmenden Parameter für die benötigte Screening Coverage identifizieren. Zusätzlich konnten wir zeigen, dass 3Cs multiplex gRNA-Bibliotheken auf Grund ihrer gleichmäßigen Verteilung mit minimierter Screening Coverage eingesetzt werden können, was zu einer 10-fachen Reduktion des assoziierten Arbeitsaufwands führt. Während bisherige Richtlinien für gepoolte CRISPR Screens die initiale
gRNA-Bibliotheksverteilung nicht berücksichtigen, empfehlen wir die Screening Coverage an dieser auszurichten.
Autophagie ist ein streng regulierter zellulärer Prozess, der den Lysosomen Abbau von intrazellulärem Material steuert und im Zusammenhang mit zahlreichen menschlichen Erkrankungen steht. Da Autophagie in eine Vielzahl von Signalwegen integriert ist, bietet es außerdem therapeutische Ansatzpunkte zur Behandlung von Krankheiten. Die Identifizierung von synergistischen Funktionen zwischen Autophagie-Genen könnte unser Verständnis über die molekularen Mechanismen, die der Regulation der Autophagie zu Grunde liegen, erweitern und dadurch neuartige Behandlungen ermöglichen.
Um genetische Interaktionen von Autophagie-Genen zu untersuchen haben wir eine 3Cs multiplex gRNA Bibliothek generiert, die auf menschliche Autophagie-Genkombinationen
abzielt. In dieser Arbeit demonstrieren wir die Funktionalität der 3Cs Autophagie multiplex gRNA Bibliothek unter Anwendung minimierter Screening Coverage in zwei verschiedenen Screen-Ausführungen: In einem Proliferationsscreen konnten wir Geninteraktionen
identifizieren, deren Verlust zu einer gesteigerten oder verringerten Zellproliferation führt. Unter diesen resultierte der Knockout von WDR45B-PIK3R4 zur stärksten Suppression der Proliferation, während die Depletion von ATG7-KEAP1 zu extrem verstärkter Proliferation beitrug. Unter Einsatz eines Autophagie-Reporters konnten wir in einem Autophagie Screen genetische Interaktionen aufdecken, die essentiell für Autophagie sind, darunter die
Interaktionen zwischen ATG2A-ATG2B , GABARAPL2-WIPI2 und ULK4-SQSTM1.
Wir glauben, dass 3Cs Multiplexing in Zukunft breite Anwendung in verschiedenen biologisch relevanten Feldern finden kann und die Entschlüsselung von kontext-abhängigen genetischen Interaktionen voranbringen und so das Verständnis für die Entstehung von komplexen pathologischen Phänotypen erweitern wird.
In vivo inducible reverse genetics in patients' tumors to identify individual therapeutic targets
(2021)
High-throughput sequencing describes multiple alterations in individual tumors, but their functional relevance is often unclear. Clinic-close, individualized molecular model systems are required for functional validation and to identify therapeutic targets of high significance for each patient. Here, we establish a Cre-ERT2-loxP (causes recombination, estrogen receptor mutant T2, locus of X-over P1) based inducible RNAi- (ribonucleic acid interference) mediated gene silencing system in patient-derived xenograft (PDX) models of acute leukemias in vivo. Mimicking anti-cancer therapy in patients, gene inhibition is initiated in mice harboring orthotopic tumors. In fluorochrome guided, competitive in vivo trials, silencing of the apoptosis regulator MCL1 (myeloid cell leukemia sequence 1) correlates to pharmacological MCL1 inhibition in patients´ tumors, demonstrating the ability of the method to detect therapeutic vulnerabilities. The technique identifies a major tumor-maintaining potency of the MLL-AF4 (mixed lineage leukemia, ALL1-fused gene from chromosome 4) fusion, restricted to samples carrying the translocation. DUX4 (double homeobox 4) plays an essential role in patients’ leukemias carrying the recently described DUX4-IGH (immunoglobulin heavy chain) translocation, while the downstream mediator DDIT4L (DNA-damage-inducible transcript 4 like) is identified as therapeutic vulnerability. By individualizing functional genomics in established tumors in vivo, our technique decisively complements the value chain of precision oncology. Being broadly applicable to tumors of all kinds, it will considerably reinforce personalizing anti-cancer treatment in the future.
A highly diastereoselective one-pot synthesis of the 1,3-diamino-2-alcohol unit bearing three continuous stereocenters is described. This method utilizes 2-oxyenamides as a novel type of building block for the rapid assembly of the 1,3-diamine scaffold containing an additional stereogenic oxygen functionality at the C2 position. A stereoselective preparation of the required (Z)-oxyenamides is reported as well.
Designed polypharmacology presents as an attractive strategy to increase therapeutic efficacy in multi-factorial diseases by a directed modulation of multiple involved targets with a single molecule. Such an approach appears particularly suitable in non-alcoholic steatohepatitis (NASH) which involves hepatic steatosis, inflammation and fibrosis as pathological hallmarks. Among various potential pharmacodynamic mechanisms, activation of the farnesoid X receptor (FXRa) and inhibition of leukotriene A4 hydrolase (LTA4Hi) hold promise to counteract NASH according to preclinical and clinical observations. We have developed dual FXR/LTA4H modulators as pharmacological tools, enabling evaluation of this polypharmacology concept to treat NASH and related pathologies. The optimized FXRa/LTA4Hi exhibits well-balanced dual activity on the intended targets with sub-micromolar potency and is highly selective over related nuclear receptors and enzymes rendering it suitable as tool to probe synergies of dual FXR/LTA4H targeting.
The desensitized channelrhodopsin-2 photointermediate contains 13 -cis, 15 -syn retinal Schiff base
(2021)
Channelrhodopsin-2 (ChR2) is a light-gated cation channel and was used to lay the foundations of optogenetics. Its dark state X-ray structure has been determined in 2017 for the wild-type, which is the prototype for all other ChR variants. However, the mechanistic understanding of the channel function is still incomplete in terms of structural changes after photon absorption by the retinal chromophore and in the framework of functional models. Hence, detailed information needs to be collected on the dark state as well as on the different photointermediates. For ChR2 detailed knowledge on the chromophore configuration in the different states is still missing and a consensus has not been achieved. Using DNP-enhanced solid-state MAS NMR spectroscopy on proteoliposome samples, we unambiguously determined the chromophore configuration in the desensitized state, and we show that this state occurs towards the end of the photocycle.
Polymorphic G-quadruplex (G4) secondary DNA structures have received increasing attention in medicinal chemistry owing to their key involvement in the regulation of the maintenance of genomic stability, telomere length homeostasis and transcription of important proto-oncogenes. Different classes of G4 ligands have been developed for the potential treatment of several human diseases. Among them, the carbazole scaffold with appropriate side chain appendages has attracted much interest for designing G4 ligands. Because of its large and rigid π-conjugation system and ease of functionalization at three different positions, a variety of carbazole derivatives have been synthesized from various natural or synthetic sources for potential applications in G4-based therapeutics and biosensors. Herein, we provide an updated close-up of the literatures on carbazole-based G4 ligands with particular focus given on their detailed binding insights studied by NMR spectroscopy. The structure-activity relationships and the opportunities and challenges of their potential applications as biosensors and therapeutics are also discussed. This review will provide an overall picture of carbazole ligands with remarkable G4 topological preference, fluorescence properties and significant bioactivity; portraying carbazole as a very promising scaffold for assembling G4 ligands with a range of novel functional applications.
Chemical language models enable de novo drug design without the requirement for explicit molecular construction rules. While such models have been applied to generate novel compounds with desired bioactivity, the actual prioritization and selection of the most promising computational designs remains challenging. Herein, we leveraged the probabilities learnt by chemical language models with the beam search algorithm as a model-intrinsic technique for automated molecule design and scoring. Prospective application of this method yielded novel inverse agonists of retinoic acid receptor-related orphan receptors (RORs). Each design was synthesizable in three reaction steps and presented low-micromolar to nanomolar potency towards RORγ. This model-intrinsic sampling technique eliminates the strict need for external compound scoring functions, thereby further extending the applicability of generative artificial intelligence to data-driven drug discovery.
Two subvalent, redox-active diborane(4) anions, [3]4− and [3]2−, carrying exceptionally high negative charge densities are reported: Reduction of 9-methoxy-9-borafluorene with Li granules without stirring leads to the crystallization of the B(sp3)−B(sp2) diborane(5) anion salt Li[5]. [5]− contains a 2,2′-biphenyldiyl-bridged B−B core, a chelating 2,2′-biphenyldiyl moiety, and a MeO substituent. Reduction of Li[5] with Na metal gives the Na+ salt of the tetraanion [3]4− in which two doubly reduced 9-borafluorenyl fragments are linked via a B−B single bond. Comproportionation of Li[5] and Na4[3] quantitatively furnishes the diborane(4) dianion salt Na2[3], the doubly boron-doped congener of 9,9′-bis(fluorenylidene). Under acid catalysis, Na2[3] undergoes a formal Stone–Wales rearrangement to yield a dibenzo[g,p]chrysene derivative with B=B core. Na2[3] shows boron-centered nucleophilicity toward n-butyl chloride. Na4[3] produces bright blue chemiluminescence when exposed to air.
SARS-CoV-2 contains a positive single-stranded RNA genome of approximately 30 000 nucleotides. Within this genome, 15 RNA elements were identified as conserved between SARS-CoV and SARS-CoV-2. By nuclear magnetic resonance (NMR) spectroscopy, we previously determined that these elements fold independently, in line with data from in vivo and ex-vivo structural probing experiments. These elements contain non-base-paired regions that potentially harbor ligand-binding pockets. Here, we performed an NMR-based screening of a poised fragment library of 768 compounds for binding to these RNAs, employing three different 1H-based 1D NMR binding assays. The screening identified common as well as RNA-element specific hits. The results allow selection of the most promising of the 15 RNA elements as putative drug targets. Based on the identified hits, we derive key functional units and groups in ligands for effective targeting of the RNA of SARS-CoV-2.
Diversity-oriented synthesis (DOS) is a rich source for novel lead structures in Medicinal Chemistry. In this study, we present a DOS-compatible method for synthesis of compounds bearing a free thiol moiety. The procedure relies on Rh(II)-catalyzed coupling of dithiols to diazo building blocks. The synthetized library was probed against metallo-β-lactamases (MBLs) NDM-1 and VIM-1. Biochemical and biological evaluation led to identification of novel potent MBL inhibitors with antibiotic adjuvant activity.