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Die Wechselwirkungen von flüchtigen organischen Verbindungen (VOCs) mit Eis in der Atmosphäre sind für viele umweltrelevante Aspekte von Interesse, dennoch gibt es bisher erst wenige Untersuchungen zu dieser Thematik.
Im Rahmen dieser Arbeit wurden die Wechselwirkungen verschiedener VOCs mit Eis durch Kraftfeldrechnungen simuliert. Als Substanzen wurden das Keton Aceton, die Kohlenwasserstoffe Isopren und Mesitylen, die Alkohole Ethanol, tert-Butanol, 2-Methyl-3-buten-2-ol (MBO) und Perillylalkohol, die Ether Methyl-tert-butylether und Ethyl-tert-butylether (ETBE) sowie die Aldehyde Nonanal und Methacrolein ausgewählt.
Hierbei wurden sowohl die Adsorption an verschiedenen Oberflächen von hexagonalen Eis (Eis Ih) und von kubischem Eis (Eis Ic) als auch die Absorption in Eiskristallen und an den darin enthaltenen Linien- und Flächendefekten betrachtet. Für jedes VOC wurden die resultierenden Strukturen sowie die dazu gehörigen Enthalpien ermittelt und mittels Boltzmann-Statistik ausgewertet.
Für die Berechnung der Wechselwirkungen von VOC mit Eis wurde ein Kraftfeld entwickelt, das sowohl die Strukturen von Eis Ih und Eis Ic als auch die Strukturen der organischen Moleküle und ebenso die Wechselwirkungen zwischen Eis und organischem Molekül gut wiedergibt. Es basiert auf dem für organische Moleküle verwendeten DREIDING-Kraftfeld und wurde modifiziert mit Parametern für Wasser aus dem TIP5P-E-Kraftfeld. Das Kraftfeld wurde an Ab-initio-Rechnungen und experimentellen Daten validiert.
Die Simulationen erbrachten folgende Ergebnisse:
– Unpolare Kohlenwasserstoffe werden nur in geringem Maße an den Eisoberflächen adsorbiert; eine Absorption in die Eiskristalle ist energetisch noch wesentlich ungünstiger. Für diese Verbindungen ist der Austrag aus der Atmosphäre durch Wechselwirkungen mit der Eisphase daher nicht relevant.
– Sauerstoffhaltige Verbindungen werden an der Eisoberfläche gut adsorbiert. Zwischen dem VOC-Molekül und der Eisoberfläche bilden sich Wasserstoffbrückenbindungen aus. Ihre Anzahl ist abhängig von der Art des Moleküls (Keton, Aldehyd, Ether oder Alkohol). Die Simulationen zeigen, dass die nasse Deposition durch Wechselwirkungen mit der Eisphase für diese Stoffe ein Austragsweg aus der Atmosphäre ist, der nicht vernachlässigt werden darf.
– Bei einem Einbau von VOC-Molekülen in den Eiskristall wird die Eisstruktur teilweise erheblich verzerrt. Je kleiner die VOC-Moleküle sind, desto geeigneter sind sie für einen Einbau in den Eiskristall; bei größeren Molekülen ist der Einbau aufgrund des sterischen Anspruchs behindert. Zunehmende Größe des Moleküls begünstigt andererseits die Adsorption.
Parallel zu den theoretischen Untersuchungen wurde eine Apparatur entwickelt, mit der sich die Ad- und die Absorption von VOCs beim Wachsen der Eiskristalle experimentell untersuchen lässt. Die Eiskristalle entstehen dabei unter kontrollierten Bedingungen und wachsen, wie in der Atmosphäre, durch Anlagerung von Wasserdampf. Gleichzeitig wird dem Wasserdampf eine definierte Menge an VOC zugegeben. Das entstehende Eis wurde mittels GC analysiert. Als alternatives Analyseverfahren zur Bestimmung von VOCs in Wasser wurde ein NMR-Verfahren entwickelt, das quantitative Messungen im dreistelligen ppm-Bereich erlaubt. Erste Untersuchungen an Eiskristallen, die in Gegenwart von ETBE erzeugt wurden, zeigten, dass dieses VOC − wie auch in den Simulationen vorhergesagt − überwiegend an der Oberfläche von Eis adsorbiert, und nicht in den Eiskristall eingebaut wird.
Für ETBE wurde im Rahmen dieser Arbeit zusätzlich die Kristallstruktur der alpha-Phase aus Röntgenpulverdaten durch Kristallstrukturvorhersage und Realraummethoden bestimmt. ETBE kristallisiert in der für organische Verbindungen sehr seltenen Raumgruppe C 2/m. Die experimentelle Kristallstruktur entspricht der von der Dichte her günstigsten, von der Gitterenergie her zweitgünstigsten vorhergesagten Kristallstruktur. Die Kristallstruktur eines zweiten VOCs, MBO, konnte ebenfalls aus Röntgenpulverdaten bestimmt werden, obwohl die Kristallstruktur drei symmetrieunabhängige Moleküle pro asymmetrischer Einheit enthält. Da sowohl ETBE als auch MBO bei Raumtemperatur flüssig sind, wurden beide für die Messungen bei tiefer Temperatur kristallisiert.
Die Kristallstrukturen dieser beiden VOCs können wiederum zur Simulation von sekundären organischen Aerosolen in der Atmosphäre genutzt werden.
Auch die Kristallstrukturen zweier weiterer Verbindungen konnten aus Röntgenpulverdaten bestimmt werden: zum einen die Strukturen des Trihydrates, des Monohydrates und des Anhydrates von Pigment Red 57:1 (C18H12CaN2O6S), dem wichtigsten industriellen Rotpigment, mit dem weltweit die Mehrheit aller Zeitungen und Zeitschriften gedruckt werden, zum anderen die Struktur des 2-Butanol-Hemisolvats von Methyl-(2R,3R)-2-{3-[amino(imino)methyl]benzyl}-3-{[4-(1-oxido-4-pyridinyl)benzoyl]¬amino}butanoat-hydrochlorid. Mit diesen Arbeiten konnte gezeigt werden, dass Kristallstrukturen organischer Verbindungen aus Röntgenpulverdaten auch dann bestimmt werden können, wenn verschiedene Probleme kombiniert auftreten, z. B. schlecht kristalline Pulver, Textur, Solvate, Hydrate, Fehlordnung, funktionelle Gruppen mit vergleichbarer Streukraft, mehrere symmetrieunabhängige Moleküle, hohe Anzahl von Parametern bei der Strukturlösung etc.
Die Ergebnisse dieser Arbeit zeigen deutlich, dass die Wechselwirkungen zwischen sauerstoffhaltigen VOC-Molekülen und der Eisphase nicht vernachlässigt werden dürfen. Sie sollten in Simulationen der Atmosphäre berücksichtigt werden, um so Aussagen über Auswirkungen auf das Klima und andere umweltrelevante Aspekte zu verbessern.
Oxidative stress is thought to be a driver for several diseases. However, many data to support this concept were obtained by the addition of extracellular H2O2 to cells. This does not reflect the dynamics of intracellular redox modifications. Cells actively control their redox-state, and increased formation of ROS is a response to cellular stress situations such as chronic inflammation.
In this study, it was shown that different types of ROS lead to different metabolic and transcriptomic responses of HUVECs. While 300 μM extracellular H2O2 led to substantial metabolic and transcriptomic changes, the effects of DAO-derived H2O2 and menadione were low to moderate, indicating that the source and the concentration of ROS are important in eliciting changes in metabolism and gene expression.
Specifically, it was identified that acute increases in ROS transiently inactivate the enzyme ω-amidase/NIT2 of the glutaminase II pathway, which supplies cells with anaplerotic α-ketoglutarate. The pathway has not been studied systematically because, as noted above, the major intermediate, KGM, is not commercially available. In the present study, an internal standard for targeted detection of KGM in cells and blood plasma/serum was used. Deletion of NIT2 by CRISPR/Cas9 significantly reduced α-ketoglutarate levels in HUVECs and elevated KGM levels. It appears that in cell culture conditions, hydrolysis of KGM to α-ketoglutarate is very efficient. Knockout of the glutamine transaminases significantly reduced methionine, suggesting that the glutaminase II pathway is an important source of amino acid replenishment.
Similar to genetic silencing of GLS1 [91,92], HUVECs lacking NIT2 showed reduced proliferation and angiogenic sprouting. Furthermore, our results indicate that, at least in HUVECs, the enzyme also locates in the mitochondria where it interacts with key enzymes of glutamine/glutamate/α-ketoglutarate metabolism.
The data of the present work indicate that the glutaminase II pathway is an underappreciated, redox-sensitive pathway for glutamine utilization in HUVECs. Genetic deletion of NIT2 has considerable physiological effects highlighting the importance of glutamine for ECs.
The new class of microbial rhodopsins, called xenorhodopsins (XeRs),[1] extends the versatility of this family by inward H+ pumps.[2–4] These pumps are an alternative optogenetic tool to the light-gated ion channels (e.g. ChR1,2), because the activation of electrically excitable cells by XeRs is independent from the surrounding physiological conditions. In this work we functionally and spectroscopically characterized XeR from Nanosalina (NsXeR).[1] The photodynamic behavior of NsXeR was investigated on the ps to s time scale elucidating the formation of the J and K and a previously unknown long-lived intermediate. The pH dependent kinetics reveal that alkalization of the surrounding medium accelerates the photocycle and the pump turnover. In patch-clamp experiments the blue-light illumination of NsXeR in the M state shows a potential-dependent vectoriality of the photocurrent transients, suggesting a variable accessibility of reprotonation of the retinal Schiff base. Insights on the kinetically independent switching mechanism could furthermore be obtained by mutational studies on the putative intracellular H+ acceptor D220.
The new class of microbial rhodopsins, called xenorhodopsins (XeRs),[1] extends the versatility of this family by inward H+ pumps.[2–4] These pumps are an alternative optogenetic tool to the light-gated ion channels (e.g. ChR1,2), because the activation of electrically excitable cells by XeRs is independent from the surrounding physiological conditions. In this work we functionally and spectroscopically characterized XeR from Nanosalina (NsXeR).[1] The photodynamic behavior of NsXeR was investigated on the ps to s time scale elucidating the formation of the J and K and a previously unknown long-lived intermediate. The pH dependent kinetics reveal that alkalization of the surrounding medium accelerates the photocycle and the pump turnover. In patch-clamp experiments the blue-light illumination of NsXeR in the M state shows a potential-dependent vectoriality of the photocurrent transients, suggesting a variable accessibility of reprotonation of the retinal Schiff base. Insights on the kinetically independent switching mechanism could furthermore be obtained by mutational studies on the putative intracellular H+ acceptor D220.
The endosteal bone marrow niche and vascular endothelial cells provide sanctuaries to leukemic cells. In murine chronic myeloid leukemia (CML) CD44 on leukemia cells and E-selectin on bone marrow endothelium are essential mediators for the engraftment of leukemic stem cells (LSC). We hypothesized that non-adhesion of CML-initiating cells to E-selectin on the bone marrow endothelium may lead to superior eradication of LSC in CML after treatment with imatinib than imatinib alone. Indeed, here we show that treatment with the E-selectin inhibitor GMI-1271 in combination with imatinib prolongs survival of mice with CML via decreased contact time of leukemia cells with bone marrow endothelium. Non-adhesion of BCR-ABL1+ cells leads to an increase of cell cycle progression and an increase of expression of the hematopoietic transcription factor and protooncogene Scl/Tal1 in leukemia-initiating cells (LIC). We implicate SCL/TAL1 as indirect phosphorylation target of BCR-ABL1 and as a negative transcriptional regulator of CD44 expression. We show that increased SCL/TAL1 expression is associated with improved outcome in human CML. These data demonstrate the BCR-ABL1-specific, cell-intrinsic pathways leading to altered interactions with the vascular niche via the modulation of adhesion molecules - a strategy therapeutically exploitable in future.
Background: Zolpidem is a non-benzodiazepine hypnotic agent which has been shown to be effective in inducing and maintaining sleep in adults and is one of the most frequently prescribed hypnotics in the world. For drugs that are used to treat sleeping disorders, the time to reach the maximum concentration (Tmax) of the drug in plasma is important to achieving a fast onset of action and this must be maintained when switching from one product to another.
Objectives: The main objective of the present work was to create a PBPK/PD model for zolpidem and establish a clinically relevant “safe space” for dissolution of zolpidem from the commercial immediate release (IR) formulation. A second objective was to analyze literature pharmacokinetic data to verify the negative food effect ascribed to zolpidem and consider its ramifications in terms of the “safe space” for dissolution.
Methods: Using dissolution, pharmacokinetic and pharmacodynamic data, an integrated PBPK/PD model for immediate release zolpidem tablets was constructed in Simcyp®. This model was used to identify the clinically relevant dissolution specifications necessary to ensure efficacy.
Results: According to the simulations, as long as 85% of the drug is released in 45 minutes or less, the impact on the PK and PD profiles of zolpidem would be minimal. According to the FDA, the drug has to dissolve from the test and reference products at a similar rate and to an extent of 85% in not more than 30 minutes to pass bioequivalence via the BCS-biowaiver test. Thus, the BCS-biowaiver specifications are somewhat more stringent than the “safe space” based on the PBPK/PD model. Published data from fasted and fed state pharmacokinetic studies suggest but do not prove a negative food effect of zolpidem.
Conclusions: A PBPK/PD model indicates that current BCS biowaiver criteria are more restrictive for immediate release zolpidem tablets than they need to be. In view of the close relationship between PK and PD, it remains advisable to avoid taking zolpidem tablets with or immediately after a meal, as indicated by the Stilnox® labeling.
The assembly of a specific polymeric ubiquitin chain on a target protein is a key event in the regulation of numerous cellular processes. Yet, the mechanisms that govern the selective synthesis of particular polyubiquitin signals remain enigmatic. The homologous ubiquitin-conjugating (E2) enzymes Ubc1 (budding yeast) and Ube2K (mammals) exclusively generate polyubiquitin linked through lysine 48 (K48). Uniquely among E2 enzymes, Ubc1 and Ube2K harbor a ubiquitin-binding UBA domain with unknown function. We found that this UBA domain preferentially interacts with ubiquitin chains linked through lysine 63 (K63). Based on structural modeling, in vitro ubiquitination experiments, and NMR studies, we propose that the UBA domain aligns Ubc1 with K63-linked polyubiquitin and facilitates the selective assembly of K48/K63-branched ubiquitin conjugates. Genetic and proteomics experiments link the activity of the UBA domain, and hence the formation of this unusual ubiquitin chain topology, to the maintenance of cellular proteostasis.
Currently, due to the misuse of antibiotics, we are facing a major public health problem. The resistance to antibiotics of certain bacterial strains makes the treatment of infections very complex.
In this context, the present thesis project concerns the study of a bacterial efflux complex capable of transporting antibiotics from the cytoplasm to the outside of the cell. This complex is composed of an inner-membrane Major Facilitator Superfamily (MFS) transporter (EmrB, E. coli multidrug resistance), a channel of the outer membrane TolC (Tolerance to Colicin E1) and a periplasmic adapter (EmrA, E. coli multidrug resistance). Unlike RND-type efflux systems (such as AcrAB-TolC), little is known about the MFS-type EmrAB-TolC system. It is therefore important to study the entire complex on a structural and functional level, to analyse the marked differences between these two types of transport systems. The goal of my thesis project was to study at least one EmrAB-TolC complex from a structural point of view. For my studies the aim was to isolate the complex directly from bacteria overexpressing the three protein partners. In a first step, 15 homologous EmrAB-TolC systems were identified and their corresponding genes amplified from genomic DNA of different Gram-negative bacteria. Among the genes of the 15 systems, the genes coding for the E. coli and V. cholerae systems were further studied. The expression vectors encoded fluorescent markers for the monitoring of the expression levels of different proteins and for studying the formation of complexes. In a first step, the different protein expression levels (EmrB-mRFP1 and EmrA-sfGFP) were studied for several expression strains of E. coli by measuring the red and green fluorescence levels and by Western blot (anti-His, Myc, and Strep for EmrB, EmrA, and TolC). The E. coli strain C41(DE3) was best suited for co-expression of EmrAB-TolC. In a second step, the FSEC (Fluorescence detection Size Exclusion Chromatography) methodology was used to identify a complex suitable for structural study. Thus this method enabled the observation that the EmrAB-TolC complex of E. coli was produced in higher amount than that of V. cholerae. The final co-purification protocol consists in perfoming a gentle lysis of the bacteria using lysozyme, then after solubilization with DDM, the purification is started by a Ni2+-NTA affinity chromatography step followed by a size exclusion chromatography step. Finally, the fractions containing the three protein partners are used for the detergent-exchange by amphipol A8-35 before the structural study by electron microscopy. Negative stain EM-micrographs displayed elongated objects with a length of 33 nm in side view. An average image of EmrAB-TolC shows similarities to that of the AcrAB-TolC complex observed under similar conditions. Similarities included the characteristic densities of TolC. Whereas differences were found in the lower part of EmrAB which is thinner than the lower part of AcrAB. The densities visible above the amphipol-ring correspond to EmrA, which displays a channel-like structure as in AcrA. The channel however seems to extend further towards the amphipol belt. Since EmrB does not have an extended periplasmic domain as the RND proteins have, these densities are therefore solely assigned to EmrA. EmrA, on the other side, contacts TolC akin to the interaction of AcrA/MexA to their cognate outer membrane channels (TolC/OprM) in a ‘tip-to-tip’ fashion.
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 role of USP22 in nucleic acid sensing pathways and interferon-induced necroptotic cell death
(2023)
Every day, living organisms are challenged by internal and external factors that threaten to bring imbalance to their tightly regulated systems and disrupt homeostasis, leading to degeneration, and ultimately death. More than ever, we face the challenge of combating diseases such as COVID-19 caused by infection with the SARS-CoV-2 coronavirus. It is therefore crucial to identify host factors that control antiviral defense mechanisms. In addition, in the fight against cancer, it is becoming increasingly important to identify markers that could be used for targeted therapy to influence cellular processes and determine cell fate.
As a deubiquitylating enzyme, ubiquitin specific peptidase 22 (USP22) mediates the removal of the small molecule ubiquitin, which is post-translationally added to target proteins, thereby regulating several important processes such as protein degradation, activation or localization. Through its deubiquitylating function, USP22 controls several biological processes such as cell cycle regulation, proliferation and cancer immunoresistance by modulating key proteins involved in these pathways. Lately, USP22 was reported to positively regulate TNFα-mediated necroptosis, an inflammatory type of programmed cell death, in various human tumor cell lines by affecting RIPK3 phosphorylation. In addition, USP22 as a part of the Spt-Ada-Gcn5 acetyltransferase (SAGA) transcription complex is known to regulate gene expression by removing ubiquitin from histones H2A and H2B. However, little is known about the role of USP22 in global gene expression.
In this study, we performed a genome-wide screen in the human colon carcinoma cell line HT-29 and identified USP22 as a key negative regulator of basal interferon (IFN) expression. We further demonstrated that the absence of USP22 results in increased STING activity and ubiquitylation, both basally and in response to stimulation with the STING agonist 2'3'-cGAMP, thereby affecting IFNλ1 expression and basal expression of antiviral ISGs. In addition, we were able to establish USP22 as a critical host factor in controlling SARS-CoV-2 infection by regulating infection, replication, and the generation of infectious virus particles, which we attribute in part to its role in regulating STING signaling.
In the second part of the study, we connected the findings of USP22-dependent regulation of IFN signaling and TNFα-induced necroptosis and investigated the role of USP22 during necroptosis induced by the synergistic action of IFN and the Smac mimetic BV6 in caspase-deficient settings. We identified USP22 as a negative regulator of IFN-induced necroptosis, which does not depend on STING expression, but relies on a yet unknown mechanism.
In summary, we identify USP22 as an important regulator of IFN signaling with important implications for the defense against viral infections and regulation of the necroptotic pathway that could be exploited for devising targeted therapeutic strategies against viral infections and related diseases like COVID-19, and advancing precision medicine in cancer treatment.
Leukemia patients bearing t(6;11)(q27;q23) translocations can be divided in two subgroups: those with breakpoints in the major breakpoint cluster region of MLL (introns 9–10; associated mainly with AML M1/4/5), and others with breakpoints in the minor breakpoint cluster region (introns 21–23), associated with T-ALL. We cloned all four of the resulting fusion genes (MLL-AF6, AF6-MLL, exMLL-AF6, AF6-shMLL) and subsequently transfected them to generate stable cell culture models. Their molecular function was tested by inducing gene expression for 48 h in a Doxycycline-dependent fashion. Here, we present our results upon differential gene expression (DGE) that were obtained by the “Massive Analyses of cDNA Ends” (MACE-Seq) technology, an established 3′-end based RNA-Seq method. Our results indicate that the PHD/BD domain, present in the AF6-MLL and the exMLL-AF6 fusion protein, is responsible for chromatin activation in a genome-wide fashion. This led to strong deregulation of transcriptional processes involving protein-coding genes, pseudogenes, non-annotated genes, and RNA genes, e.g., LincRNAs and microRNAs, respectively. While cooperation between the MLL-AF6 and AF6-MLL fusion proteins appears to be required for the above-mentioned effects, exMLL-AF6 is able to cause similar effects on its own. The exMLL-AF6/AF6-shMLL co-expressing cell line displayed the induction of a myeloid-specific and a T-cell specific gene signature, which may explain the T-ALL disease phenotype observed in patients with such breakpoints. This again demonstrated that MLL fusion proteins are instructive and allow to study their pathomolecular mechanisms.
Leukemia patients bearing t(6;11)(q27;q23) translocations can be divided in two subgroups: those with breakpoints in the major breakpoint cluster region of MLL (introns 9–10; associated mainly with AML M1/4/5), and others with breakpoints in the minor breakpoint cluster region (introns 21–23), associated with T-ALL. We cloned all four of the resulting fusion genes (MLL-AF6, AF6-MLL, exMLL-AF6, AF6-shMLL) and subsequently transfected them to generate stable cell culture models. Their molecular function was tested by inducing gene expression for 48 h in a Doxycycline-dependent fashion. Here, we present our results upon differential gene expression (DGE) that were obtained by the “Massive Analyses of cDNA Ends” (MACE-Seq) technology, an established 3′-end based RNA-Seq method. Our results indicate that the PHD/BD domain, present in the AF6-MLL and the exMLL-AF6 fusion protein, is responsible for chromatin activation in a genome-wide fashion. This led to strong deregulation of transcriptional processes involving protein-coding genes, pseudogenes, non-annotated genes, and RNA genes, e.g., LincRNAs and microRNAs, respectively. While cooperation between the MLL-AF6 and AF6-MLL fusion proteins appears to be required for the above-mentioned effects, exMLL-AF6 is able to cause similar effects on its own. The exMLL-AF6/AF6-shMLL co-expressing cell line displayed the induction of a myeloid-specific and a T-cell specific gene signature, which may explain the T-ALL disease phenotype observed in patients with such breakpoints. This again demonstrated that MLL fusion proteins are instructive and allow to study their pathomolecular mechanisms.
Leukemia patients bearing the t(4;11)(q21;q23) translocations can be divided into two subgroups: those expressing both reciprocal fusion genes, and those that have only the MLL-AF4 fusion gene. Moreover, a recent study has demonstrated that patients expressing both fusion genes have a better outcome than patients that are expressing the MLL-AF4 fusion protein alone. All this may point to a clonal process where the reciprocal fusion gene AF4-MLL could be lost during disease progression, as this loss may select for a more aggressive type of leukemia. Therefore, we were interested in unraveling the decisive role of the AF4-MLL fusion protein at an early timepoint of disease development. We designed an experimental model system where the MLL-AF4 fusion protein was constitutively expressed, while an inducible AF4-MLL fusion gene was induced for only 48 h. Subsequently, we investigated genome-wide changes by RNA- and ATAC-Seq experiments at distinct timepoints. These analyses revealed that the expression of AF4-MLL for only 48 h was sufficient to significantly change the genomic landscape (transcription and chromatin) even on a longer time scale. Thus, we have to conclude that the AF4-MLL fusion protein works through a hit-and-run mechanism, probably necessary to set up pre-leukemic conditions, but being dispensable for later disease progression.
The majority of B-cell precursor acute leukemias in infants are associated with the chromosomal translocation t(4;11)(q21;q23), resulting in the fusion of the mixed-lineage leukemia (MLL) and ALL1-fused gene of chromosome 4 (AF4) genes. While the fusion protein MLL-AF4 is expressed in all t(4;11) patients and essential for leukemia progression, the distinct role of the reciprocal fusion protein AF4-MLL, that is expressed in only 50-80% of t(4;11) leukemia patients (Meyer et al., 2018), remains unclear. In addition, t(4;11) leukemia could so far exclusively be generated in vivo in the presence of AF4-MLL and independent of the co-expression of MLL-AF4 (Bursen et al., 2010).
In a multifactorial approach inhibiting histone deacetylases (HDACs) and expressing the dominant negative mutation of Taspase1 (dnTASP1), both MLL fusion proteins were targeted simultaneously to evaluate a possible cooperative effect between MLL-AF4 and AF4-MLL during the progression of leukemia. Of note, neither HDACi nor dnTASP1 expression negatively affect endogenous MLL, but rather endorse its function hampered by the MLL fusion proteins (Ahmad et al., 2014; Bursen et al., 2004; Zhao et al., 2019). The mere expression of dnTASP1 failed to induce apoptosis, whereas dnTASP1 could elevate apoptosis levels significantly in HDACi-treated t(4;11) cells underlining the therapeutic potential of co-inhibiting both MLL fusion proteins.
Next, the impact of inhibiting either MLL-AF4 or AF4-MLL in vivo was resolved using whole transcriptome analysis. In PDX cells obtained by the Jeremias Laboratory (Völse, 2020) that co-expressed both t(4;11) fusion proteins, the knock-down of MLL-AF4 revealed the down-regulation of pivotal hemato-malignant factors. The expression of dnTASP1 led to massive deregulation of cell-cycle genes in vivo. Considering that the inhibition of particularly MLL-AF4 but not AF4-MLL impaired leukemic cell growth in vivo (Völse, 2020), the results of this work suggest a cooperative effect between both fusion proteins, while the loss of AF4-MLL during leukemia progression appears not essential.
Thereafter, a possible short-term role of AF4-MLL during the establishment of t(4;11) leukemia was analyzed. For this purpose, an in vitro t(4;11) model was constructed to investigate the transforming potential of transiently expressed AF4-MLL in cells constitutively expressing MLL-AF4, putatively reflecting the situation in vivo. Due to the lack of a leukemic background of the applied cell line, the aim was to investigate the long-term potential of AF4-MLL to significantly alter the epigenome rather than mimicking the development of leukemia. Strikingly, short-term-expressed AF4-MLL in cooperation with MLL-AF4 exerted durable epigenetic effects on gene transcription and chromatin accessibility. The here obtained in vitro data suggest a clonal evolutionary process initiated by AF4-MLL in a cooperative manner with MLL-AF4. Importantly, no long-term changes in chromatin accessibility could be observed by the transient expression of either MLL-AF4 or AF4-MLL alone.
All in all, considering endogenous MLL, MLL-AF4 and AF4-MLL in a targeted treatment is a promising approach for a more tailored therapy against t(4;11) leukemia, and AF4-MLL is suggested to act in a cooperative manner with MLL-AF4 especially during the development of a t(4;11) leukemia.
Metabolites such as lactate and free fatty acids (FFAs) abundantly occur in high concentrations in tumor and stromal cells of solid malignancies. Their known functions comprise the allocation of nutrients and intermediates for the generation of cell components, the evasion of immune destruction, the induction of vessel formation and the stimulation of cell migration in order to promote tumor growth, progression and metastasis. However, the role of metabolites as signaling molecules and the downstream mechanisms of metabolite receptor mediated signaling in tumor and stromal cells is poorly understood. Our study confirms the expression of Hydroxycarboxylic acid receptor 1 (HCA1) in solid human breast tumors and the expression of Free fatty acid receptor 4 (FFA4) in solid human colorectal tumors. In addition, the expression of HCA1 in human breast cancer cell lines as well as the expression of FFA4 in human colorectal cancer cell lines was proved. Moreover, our research reveals the expression HCA2, FFA2 and FFA4 in tumor associated macrophages (TAMs).
To test whether the loss of any of the metabolite receptors affects tumor growth and progression we utilized a syngeneic Lewis lung cancer (LLC1) tumor model, an azoxymethane (AOM) – dextran sulfate (DSS) colorectal cancer model and a Mouse mammary tumor virus Polyoma Virus middle T antigen (MMTV-PyMT) breast cancer model. The loss of HCA2 did not lead to a changed outcome compared to wild type littermates in any of the models. Likewise, the deletion of FFA4 had no influence on the LLC1 model and, surprisingly, tumor number and area in the AOM-DSS model also remained unaltered. The impact of HCA1 deficiency was investigated utilizing the MMTV-PyMT model and revealed a moderately improved tumor growth. The absence of FFA2 did not affect tumor growth in the LLC1 model but led to an increased number of colorectal tumors in the AOM-DSS model while the tumor area remained unchanged. The most compelling results were obtained upon the deletion of FFA2 in the MMTV-PyMT model. Here, we demonstrate that the loss of FFA2 significantly reduces tumor latency and also significantly improves tumor growth. Nevertheless, the formation of metastases in the LLC1 model and the MMTV-PyMT model did not show any changes upon the loss of any of the metabolite receptors.
Together, our results describe a tumor-protective effect of FFA2 with an unclear impact on metastatic processes. Considerations about putative mechanisms of short chain fatty acid (SCFA) mediated FFA2 signaling suggest potential targets for pharmacological interventions to treat mammary tumors.
Krebs ist und wird voraussichtlich auch in näherer Zukunft eine der häufigsten Todesursachen weltweit bleiben. Trotz vielversprechenden Fortschritten in Therapeutik und Diagnostik bedarf es noch weiterer Forschung, um die vielfältigen molekularen Mechanismen zu entschlüsseln, welche dem Verlauf von malignen Tumorerkrankungen bestimmen und zu beeinflussen vermögen. Das RNA-Bindeprotein Hu antigen R (HuR) reguliert Genexpression auf posttranskriptioneller Ebene, indem es durch Bindung an Ziel mRNAs Einfluss auf deren Abbau, Lokalisation oder Translationseffizienz nimmt. Darüber hinaus zeigte sich in den letzten Jahren, dass HuR diese Prozesse auch indirekt durch Interaktion mit regulatorischen RNAs beeinflusst. In Krebszellen lässt sich häufig eine erhöhte Aktivität von HuR beobachten, welche in Verbindung mit verschiedenen tumorigenen Prozessen gebracht wird. Unter anderem trägt HuR zur Deregulation des Zellzyklus bei, indem es die Expression der Cycline A2, B1, D1 und E1 erhöht. Weiterhin unterstützt HuR das Tumorwachstum durch Regulation von proangiogenen Faktoren wie VEGF, IL8 und COX2. Da HuR generell eine prominente Rolle bei der Regulation von Immunantworten, sowohl in Immunzellen selbst als auch in solidem Gewebe einnimmt, wurde HuR in der Vergangenheit häufig auch mit der Ausbildung des inflammatorischen Tumormikromilieus in Verbindung gebracht, jedoch ist die Datenlage in dieser Hinsicht bis heute uneindeutig. Obwohl eine Großzahl an Zytokinen und inflammatorischen Faktoren prinzipiell als HuR Zielgene beschrieben sind, gibt es nur für die wenigsten dieser Proteine entsprechende Untersuchungen in Tumorzellen.
Ziel dieser Arbeit war es, den Einfluss von HuR in Tumoren auf die Rekrutierung von Makrophagen zu evaluieren. Hierfür bot sich als in vitro Modell die Brustkrebszelllinie MCF-7 an, da diese unter entsprechenden Kultivierungsbedingungen dreidimensionale Sphäroide bildet. Solch ein Sphäroidmodell bietet sich als Kompromiss zwischen der klassischen zweidimensionalen Zellkultur an, welche zwar höchst artifiziell, jedoch leicht zu handhaben und zu kontrollieren ist, und den physiologischeren, aber gleichzeitig experimentell unzugänglicheren und speziesfremden Tiermodellen. Mittels lentiviraler Transduktion wurde ein small hairpin RNA (shRNA) vermittelter stabiler Knockdown von HuR in MCF-7 erzielt, welcher zu vermindertem Zellwachstum führte, jedoch keinen weiteren Einfluss auf die Bildung von Sphäroiden hatte. Um die initiale Suche nach HuR-regulierten, potenziell relevanten Faktoren möglichst breit und unvoreingenommen zu halten, wurde die Expression von 174 Zytokinen in Wildtyp- und HuR-knockdown Sphäroiden mittels eines Protein Arrays untersucht. Überraschenderweise zeigte der Großteil der veränderten Proteins einen negativen Zusammenhang mit HuR, welches eigentlich eher als positiv regulierendes Protein beschrieben ist. Bemerkenswerterweise befand sich unter den mit am stärksten regulierten Faktoren das Chemokin CCL5 (auch RANTES genannt), welches einerseits als einer der beiden zentralen Faktoren für die Makrophageninfiltration in Brustkrebs gilt, andererseits bisher noch nicht in Verbindung mit HuR gebracht wurde.
Im Folgenden untersuchte ich zuerst den mechanistischen Hintergrund dieser Regulation. Da diese sich auch in adhärenten Zellrasen zeigte, wechselte ich für die entsprechenden Experimente zu zweidimensionaler Zellkultur. Eine negative regulatorische Funktion von HuR wird meist in Verbindung mit verminderter Translation von Zielfaktoren gebracht. Da die mRNA Level von CCL5 dem Effekt auf Proteinebene entsprachen, konnten entsprechende Mechanismen als Grund für die veränderten CCL5 Level ausgeschlossen werden. Desweiteren blieb die mRNA Stabilität ungeachtet der HuR Level konstant; dabei zeigte sich zudem, dass mRNA Abbau generell keinen relevanten Einfluss auf die Expression von CCL5 in MCF-7 hatte. Da diese Ergebnisse auf eine transkriptionelle Regulation hindeuteten, untersuchte ich im Folgenden den Einfluss von HuR auf die Promoteraktivität von CCL5. Hierfür isolierte ich zunächst die CCL5-Promoterregion aus genomischer DNA von MCF-7 Zellen und inserierte diese dann in einen zuvor promoterlosen Luciferase-Expressionsvektor. In den folgenden Reporteranalysen zeigte sich, dass HuR tatsächlich einen negativen Einfluss auf die Promoteraktivität von CCL5 ausübt. Durch sukzessive Verkürzung ließ sich der entscheidende DNA-Bereich auf die letzten 140 Nukleotide vor dem Transkriptionsstartpunkt eingrenzen. Dieser Bereich enthält vier prominente und sehr gut charakterisierte regulatorische Abschnitte: zwei benachbarte NF-κB Bindestellen sowie je ein Interferon-stimulated Response Element (ISRE) und ein C/EBPβ Erkennungsmotiv. Während das C/EBP Element keine funktionelle Relevanz in den Reporteranalysen hatte, reduzierte sich durch Deletion sowohl der ISRE als auch der NF-κB Elemente die Promoteraktivität um mehr als 50%, allerdings nur im ISRE-Deletionskonstrukt unter Nivellierung des HuR-abhängigen Unterschiedes. Somit ließ sich der Einfluss von HuR auf die CCL5 Promoteraktivität vollständig und ausschließlich auf das ISRE zurückführen. Im Gegensatz zu dem in Tumorzellen häufig basal überaktiven NF-κB Signalweg sind die kanonischen, ISRE-assoziierten Typ I Interferon Signalkaskaden und ihre vermittelnden Transkriptionsfaktoren, die sogenannten Interferon Regulatory Factors (IRFs) nicht konstitutiv überaktiviert. Eine Sonderstellung nehmen dabei die Faktoren IRF1 und IRF2 ein, da sie, für Proteine abseits der Stimulus-getriebenen ISRE-Interferon Achse, auch als konstitutive Transkriptionsfaktoren beschrieben sind, wobei IRF2 in diesem Kontext als IRF1-Antagonist und somit Transkriptionsrepressor fungiert. Überraschenderweise ließ sich mittels Chromatin Immunopräzipitation eine Assoziation von IRF1 mit dem CCL5 Promoter nur in Wildtyp-, jedoch nicht in HuR-knockdown Zellen nachweisen. Im Gegensatz dazu ergaben mRNA Expressionsanalysen der Tumor-relevanten IRFs, dass die CCL5 Induktion in HuR-depletierten Zellen mit einer allgemeinen, jedoch niedrigschwelligen Erhöhung von Typ I Interferon-assoziierten Signalen einhergeht. Interessanterweise korrelierte Interferon β zwar mit CCL5 auf mRNA Ebene, jedoch hatte eine Blockade des Interferon-α/β Rezeptors in HuR-depletierten Zellen keinen akuten Effekt auf CCL5. Umgekehrt zeigte sich auch keine erhöhten CCL5 Level in Wildtypzellen unter Kokultur mit HuR-knockdown Zellen, wie es bei parakriner Induktion durch Interferon β zu erwarten wäre. Ebenso konnte alternatives ISRE Signaling durch einen Komplex aus unphosphoryliertem Stat1 und IRF9, wie es in vitro unter länger anhaltender Niedriglevel Exposition mit Interferon β beobachtet wurde, ausgeschlossen werden. Um sicher zu stellen, dass diese Erhöhung kein sequenzabhängiges off-target Artefakt ist, wie es in der Vergangenheit für einzelne small hairpin RNAs (shRNAs) beobachtet wurde, wurde eine entsprechende Aktivierung von IRF3 und damit des IRF3/IRF7 Aktivierungsweges untersucht und ausgeschlossen. Zusätzlich konnte durch Tests unterschiedlicher shRNA Sequenzen sowie Zellsysteme demonstriert werden, dass die CCL5 Aktivierung tatsächlich ein spezifischer und in einer größeren Bandbreite an Krebszelllinien unterschiedlicher Herkunft, darunter Brust- und Lungenkarzinom, Glioblastom- sowie Melanom- Zelllinien, reproduzierbarer Effekt von HuR-Defizienz ist.
Da CCL5 als eines der zentralen Chemokine bei der Rekrutierung von Monozyten/Makrophagen in Tumore beschrieben ist, stellte sich die Frage, ob HuR mit diesem Vorgang in Verbindung zu bringen ist. Brusttumore weisen oft eine hohe Zahl von Tumor-assoziierten Makrophagen auf, welche von eingewanderten Blutmonozyten abstammen. Ein Einfluss von HuR auf diesen Vorgang in vitro konnte mittels einer Kokultur von Sphäroiden mit zuvor frisch aus Humanblut isolierten Primärmonozyten nachgewiesen werden. Hierbei wiesen HuR-knockdown Sphäroide trotz ihres geringeren Durchmessers eine erhöhte Anzahl von Monozyten/Makrophagen auf. Da sich in diesen Zellen weder Proliferation noch relevante Apoptose zeigte, ließ sich die erhöhte Anzahl auf verstärkte Einwanderung in das Sphäroid zurückführen. Hierbei erwies sich der direkte Zellkontakt zwischen Monozyten und Tumorzellen als erforderlich, da Monozyten keine unterschiedliche Chemotaxis gegenüber entsprechenden Sphäroidüberständen zeigten. Dass die erhöhte Infiltration in HuR-defizienten Sphäroiden tatsächlich auf CCL5 zurückzuführen ist, konnte in Kokulturexperimenten durch Inhibierung von CCL5 gezeigt werden. Unterstütztend wurde ein Zusammenhang zwischen HuR, CCL5 und Tumor assoziierten Makrophagen in silico unter Zuhilfenahme des TCGA Datensets für Estrogenrezeptor-positive Brusttumore untersucht. Im Einklang mit meinen Ergebnissen zeigte sich eine negative Korrelation zwischen HuR und CCL5. Außerdem ließ sich ein negativer Zusammenhang zwischen HuR und einer Makrophagensignatur feststellen, während CCL5 wie erwartet mit dieser Signatur positiv korrelierte.
Zusammenfassend zeigte sich in dieser Arbeit, dass HuR eine Rolle bei der zellulären Zusammensetzung des inflammatorischen Tumor-Mikromilieus spielt. Der Verlust von HuR in Tumorzellen führte zu einer erhöhten Expression des Chemokins CCL5. Dies ließ sich in Brust- und Lungenkarzinom-, Glioblastom- sowie Melanom- Zelllinien beobachten. In Brustkrebszellen zeigte sich, dass diese Regulation auf verstärkte Transkription, vermittelt durch ein ISRE innerhalb des CCL5 Promoters, zurückzuführen ist. Funktionell konnte die erhöhte CCL5 Produktion in HuR-defizienten Tumorsphäroiden in Verbindung mit verstärkter Infiltration von Monozyten/Makrophagen gebracht werden. Unterstützend zeigte sich auch bei einer in silico Analyse von Estrogenrezeptor-positiven Brusttumoren eine negative Korrelation zwischen HuR und CCL5, was mit einer entsprechend veränderten Makrophagensignatur einherging. Im Hinblick auf derzeit diskutierte Ansätze, das Wachstum von Tumoren mittels HuR Blockade zu inhibieren, sind meine Ergebnisse potenziell von therapeutischer Relevanz. Basierend auf meiner Arbeit sollte dabei in zukünftigen Studien näher untersucht werden, wie sich Inhibierung von HuR in Tumoren auf die Zusammensetzung und Funktion des Tumormikromilieus auswirkt und daraus resultierende Effekte auf das Tumorwachstum in Relation zu der allgemein wachstumsfördernden Rolle von HuR in Tumorzellen gesetzt werden.
Leukemia is a cancer of the blood and bone marrow characterized by an uncontrolled proliferation and accumulation of abnormal white blood cells. Leukemia can be classified based on the course of the disease (acute or chronic) and the blood cell type involved (myeloid or lymphocytic), leading to four main subtypes: acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), chronic lymphocytic leukemia (CLL) and chronic myeloid leukemia (CML). Leukemia represents 2.5% of all new cancer cases per year, and survival rates in some leukemias remain low at 40%.
The bone marrow microenvironment (BMM) is a system within the bone marrow comprising cellular and acellular components, all of which play a major role in hematopoiesis, providing the physical space where hematopoietic stem cells (HSCs) reside. The BMM interacts with HSCs, offering a “niche” for those cells and in case of leukemia, the BMM has a supportive role in disease maintenance and progression by supporting Leukemia stem cells (LSCs). One of the components of the BMM are calcium ions. Calcium is the most abundant mineral in the body, a key component of bones and is released by parathyroid hormone (PTH) induced bone remodeling. Calcium ions play a role in the localization, engraftment and adhesion of normal HSC to extracellular matrix (ECM) proteins in the BMM via the calcium sensing receptor (CaSR), thereby maintaining normal hematopoiesis. In addition of a major regulator of calcium homeostasis, CaSR contribute to the development of different cancers, functioning as either tumor suppressor or oncogene, depending on the involved tissue. However, the role of CaSR and its associated pathways in the local BMM for the development of leukemia is poorly understood. We hypothesized that calcium ions released from bone, subject to a fine balance between osteoblasts and osteoclasts, and/or CaSR, contribute to development, progression and response to therapy.
We have shown that the local calcium concentration forms a gradient in the bone marrow niche and in mice with CML is similarly low as in control mice, but significantly higher in mice suffering from BCR ABL1 driven B ALL or MLL AF9 driven AML. Similarly, the calcium concentration in the human BMM was found to be higher in AML than in other leukemias. Regarding the function of calcium in leukemia cells, we found that AML and CML cells respond differently to calcium exposure, with AML cells exhibiting regulation of cellular processes such as adhesion to the ECM protein fibronectin and migration toward CXCL 12, whereas CML cells remained mostly unaltered. Using genetic deletion or overexpression of CaSR in murine models of leukemia, we observed that CaSR acts as tumor suppressor in BCR-ABL1 driven CML and B ALL and as oncogene in AML.
Focusing on AML, our data shows that deficiency of CaSR on LICs leads, on one hand to increased apoptosis, and on the other hand to reduced cell cycle, reactive oxygen species (ROS) production and DNA damage in vivo, which may explain the observed prolongation of survival of mice. Complementary, in vitro experiments demonstrated that cells overexpressing CaSR have a distinct, cancer promoting phenotype compared to wildtype cells. Overexpression of CaSR led to an increase in proliferation, cell cycle, ROS production, DNA damage and reduced apoptosis. We have identified CaSR mediated pathways in AML and shown that CaSR enhances leukemia progression by activating MAPK/ERK and Wnt β catenin signaling. In addition, the CaSR interacting protein filamin A (FLNA) was shown to contribute to aggressive disease in vitro and in vivo. Furthermore, the mechanism underlying the role of CaSR in AML pathogenesis and possible regulation of LSCs was studied. Our findings demonstrated that CaSR ablation reduces myeloid progenitor function and proved that CaSR is required for maintenance of LSC pool by regulating its frequency and function. Further supporting the role of CaSR in LSC maintenance, genes associated with AML stemness and self renewal capacity were upregulated when CaSR was overexpressed and downregulated when CaSR was depleted. Given the role of CaSR in AML, the CaSR antagonist NPS 2143 was tested in vivo. The combination treatment of NPS 2143 with the standard of care, ara C, significantly reduced the tumor burden and prolonged the survival of mice with AML in syngeneic and xenotransplantation experiments. Based on the finding that CaSR functions as a tumor suppressor in CML, treatment of mice with the CaSR agonist cinacalcet in combination with imatinib prolonged survival of mice with CML compared to treatment with the mice given vehicle.
Our results suggest that calcium ions stemming from the calcium-rich BMM via CaSR strongly and differentially influence leukemia progression. As an adjunct to existing treatment therapies, targeting of CaSR with specific pharmacologic antagonists may prolong survival of patients with AML.
Bei ca. 95% der chronisch myeloischen Leukämie (CML) und 20-30% der akuten lymphatischen Leukämie (ALL) des Erwachsenen liegt eine reziproke Chromosomentranslokation t(9;22)(q34;q11) vor, in deren Rahmen das BCR (Breakpoint Cluster Region) Gen auf Chromosom 22 mit dem ABL (Abelson-Leukämie-Virus) Gen auf Chromosom 9 fusioniert. Auf Chromosom 22 gibt es zwei verschiedene Bruchpunkte, die somit zur Bildung von unterschiedlichen Fusionsgenen führen. Bei der CML findet man den sogenannten „großen“ Bruchpunkt (M-bcr), während bei der Ph+ ALL der sogenannte „kleine“ Bruchpunkt (m-bcr) vorkommt. Das hybride Fusionsgen auf Chromosom 22q+ (Philadelphia-Chromosom) kodiert für das jeweilige BCR/ABL Protein, während das Fusionsgen auf Chromosom 9q+ für das reziproke ABL/BCR Protein kodiert. Das ABL-Protein ist eine Nicht-Rezeptor Tyrosinkinase, die eine wichtige Rolle in der Signaltransduktion und der Regulation des Zellwachstums spielt. Im BCR/ABL Fusionsprotein wird die Kinase-Aktivität von ABL, die im Normalfall streng reguliert ist, durch die Fusion mit BCR konstitutiv aktiv. Dadurch kommt es zur Deregulierung intrazellulärer Signalwege, welche die maligne Transformation hämatopoetischer Zellen verursacht. Eine zielgerichtete Inhibierung von BCR/ABL mittels ABL-Kinase-Inhibitoren induziert Apoptose in BCR/ABL transformierten Zellen, was eine komplette Remission im größten Teil Ph+ Leukämie Patienten zur Folge hat.
Single-particle electron cryo-microscopy (cryoEM) has undergone a `resolution revolution' that makes it possible to characterize megadalton (MDa) complexes at atomic resolution without crystals. To fully exploit the new opportunities in molecular microscopy, new procedures for the cloning, expression and purification of macromolecular complexes need to be explored. Macromolecular assemblies are often unstable, and invasive construct design or inadequate purification conditions and sample-preparation methods can result in disassembly or denaturation. The structure of the 2.6 MDa yeast fatty acid synthase (FAS) has been studied by electron microscopy since the 1960s. Here, a new, streamlined protocol for the rapid production of purified yeast FAS for structure determination by high-resolution cryoEM is reported. Together with a companion protocol for preparing cryoEM specimens on a hydrophilized graphene layer, the new protocol yielded a 3.1 Å resolution map of yeast FAS from 15 000 automatically picked particles within a day. The high map quality enabled a complete atomic model of an intact fungal FAS to be built.
Endocannabinoids (eCB) are signaling lipids and became known for their importance in the central nervous system as well as in immune defense. Beneficial effects of eCB are shown in processes of excitotoxic lesion, secondary damage and neuronal plasticity throughout the last years. Two canabinoid receptors, type 1 (CB1) and type 2 (CB2) as the respective endogenous ligands belong to the endocannabinoid system (eCBS). In 1990, the CB1 could be cloned and was localised mainly on neurons. Shortly thereafter in 1993, the CB2 was characterised and found primarily on cells belonging to the immune system. N-arachidonoylethanolamide (AEA), often called anandamide, and 2-arachidonoylglycerol (2-AG) are the best characterised eCB. N-palmitylethanolamide (PEA) and N-oleoylethanolamide (OEA) have no or only low affinity to CB1 but enhance the affinity of AEA significantly. This group is therefore often summarized as N-ethanolamides (NEA). ECB are derivates of arachidonic acid and are stored in membranes where they become hydrolysed on demand by specific enzymes. Traumatic brain injury altered the levels of eCB in the blood in vivo and when applied in vitro after neuronal damage, eCB could reduce the damaging burden. Further studies demonstrated that eCB are potent to down-regulate pro-inflammatory cytokines and most important to decrease neuronal excitation.
In the present study, the intrinsic regulation of the endocannabinoid system after neuronal damage over time was investigated in rat Organotypic Hippocampal Slice Cultures (OHSC). Temporal and spatial dynamics of eCB levels were analysed after transection of the perforant pathway (PPT) in originating neurons (enthorhinal cortex, EC), areas of deafferentiation/anterograde axonal degeneration (dentate gyrus, DG) and of the synaptically linked cornu ammonis region 1 (CA1) as well as after excitotoxic lesion in the respective regions.
A strong increase of all eCB was observed only in the denervation zone of the DG 24 hours post PPT. In excitotoxic lesioned OHSC all eCB were elevated, in the investigated regions up to 72 hours post lesion (hpl). The responsible enzyme for biosynthesis of the NEA, NAPE-PLD protein, was increased during the early timepoints of measurement (1-6 hpl). The responsible catabolizing enzyme, FAAH, and the CB1 receptor were up-regulated at a later timepoint, 48 hpl, explaining the eCB levels. In the present model, the inhibition of the enzyme responsible for 2-AG hydrolysis (MAGL) was neuroprotective as previously shown and a re-distribution within neurons and astrocytes during neuronal damage could be observed. In primary cell cultures microglia expressed the regulating enzymes of 2-AG and the enzyme responsible for NEA down-regulation, FAAH. Astrocytes expressed mainly the catalyzing enzymes, indicating the role for eCB break-down. All these findings together demonstrate the great capacity of the eCBS to control inflammatory processes and consequently neuronal cell death.
All effects of the known eCB could not be clarified by CB1/CB2 deficient mice. Several G-protein coupled receptors (GPR) are recently in discussion whether they might and should belong to the endocannabinoid system. The GPR55, the not yet cloned abnormal cannabidiol receptor and further GPRs are candidates as potential endocannabinoid receptors. Recently GPR55 has been discussed as a putative cannabinoid receptor type 3 (CB3). Quantitative PCR revealed that Gpr55 is present in primary microglia and the brain, but the exact regional and cellular distribution and the physiological/pathological effects downstream of GPR55 activation in the CNS still remain open. Therefore, the excitotoxic rat OHSC model, previously used to investigate the neuroprotective potency of eCB, was now used to investigate the neuroprotective potency of GPR55. Activation of GPR55 protected dentate gyrus granule cells in vitro after excitotoxic lesion, induced by NMDA. In parallel, GPR55 activation was able to reduce the number of microglia in the dentate gyrus. These neuroprotective effects vanished however in microglia depleted OHSCs as well as in OHSC transfected with Gpr55 siRNA, indicating a strong involvement of microglia in GPR55 mediated neuroprotection.
In summary, the present study found a strong time-dependent and anterograde mechanism of action of eCB after long-range projection damage and provided further evidence for the neuroprotective properties of eCB. The potential cannabinoid receptor 3 (GPR55) mediates neuronal protection on behalf of microglia.