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Compartmental models are the theoretical tool of choice for understanding single neuron computations. However, many models are incomplete, built ad hoc and require tuning for each novel condition rendering them of limited usability. Here, we present T2N, a powerful interface to control NEURON with Matlab and TREES toolbox, which supports generating models stable over a broad range of reconstructed and synthetic morphologies. We illustrate this for a novel, highly detailed active model of dentate granule cells (GCs) replicating a wide palette of experiments from various labs. By implementing known differences in ion channel composition and morphology, our model reproduces data from mouse or rat, mature or adult-born GCs as well as pharmacological interventions and epileptic conditions. This work sets a new benchmark for detailed compartmental modeling. T2N is suitable for creating robust models useful for large-scale networks that could lead to novel predictions. We discuss possible T2N application in degeneracy studies.
Heat stress transcription factors (Hsfs) are required for transcriptional changes during heat stress (HS) thereby playing a crucial role in the heat stress response (HSR). The target genes of Hsfs include heat shock proteins (Hsps), other Hsfs and genes involved in protection of the cell from irreversible damages due to exposure to elevated temperatures. Among 27 Hsfs in Solanum lycopersicum, HsfA1a, HsfA2 and HsfB1 constitute a functional triad which regulates important aspects of the HSR. HsfA1a is constitutively expressed and described as the master regulator of stress response and thermotolerance. Activation of HsfA1a under elevated temperatures leads to the induction of HsfA2 and HsfB1 which further stimulate the transcription of HS-responsive genes by forming highly active complexes with HsfA1a. Despite the well-established role of these three Hsfs in tomato HSR, information about functional relevance of other Hsfs is currently missing.
The heat stress inducible HsfA7 belongs alongside with HsfA2 to a phylogenetically distinct clade. Thereby the two proteins share high homology and a functional redundancy has been assumed. However, HsfA7 function and contribution to stress responses have not been investigated into detail in any plant species.
Tomato HsfA7 protein accumulates already at moderately elevated temperatures (~35°C) while HsfA2 becomes dominant at higher temperatures (>40°C). HsfA7 pre-mRNA undergoes complex and temperature-dependent alternative splicing resulting in several transcripts that encode for three protein isoforms. HsfA7-I contains a functional nuclear export signal (NES) and shows nucleocytoplasmic shuttling while HsfA7-II and HsfA7-III have a truncated NES which leads to the strong nuclear retention of the protein. Differences in the nucleocytoplasmic equilibrium have a major impact on the stability of protein isoforms, as nuclear retention is associated with increased protein turnover. Consequently, HsfA7-I shows a higher stability and can be detected even after 24 hours of stress attenuation, while HsfA7-II is rapidly degraded. The degradation of these factors is mediated by the ubiquitin-proteasome pathway.
HsfA7 can physically interact with HsfA1a and HsfA3 and form co-activator (“superactivator”) complexes with a very high transcriptional activity as shown on different HS-inducible promoters. In order for the complex to be successfully transferred to the nucleus and confer its activity it needs a functional nuclear localization signal (NLS) of HsfA7. In contrast, the activator (AHA) motif of HsfA7 is not essential for its co-activator function. Interestingly, while interaction of HsfA7 with either HsfA3 or HsfA1a stabilizes HsfA7 isoforms, concomitantly this leads to an increased turnover of HsfA1a and HsfA3. In contrast, HsfA2 has a stabilizing effect on the master regulator HsfA1a.
Thus, HsfA7 knockout mutants generated by CRISPR/Cas9 gene editing, show increased HsfA1a levels and a stronger induction of HS-related genes at 35°C compared to wild-type plants and HsfA2 knockout mutants. Consequently, HsfA7 knockout seedlings exhibit increased thermotolerance as shown by the enhanced hypocotyl elongation under a prolonged mild stress treatment at 35°C. In summary, these results highlight the importance of HsfA7 in regulation of cellular responses at elevated temperatures. Under moderately elevated temperatures, the accumulation of HsfA7 and its subsequent interaction with HsfA1a, leads to increased turnover of the latter, thereby ensuring a milder transcriptional activation of temperature-responsive genes like Hsps. In turn, in response to further elevated temperatures, HsfA2 becomes the dominant stress-induced Hsf. HsfA2 forms co-activator complexes with HsfA1a which in contrast to HsfA7, allows the stabilization of the master regulator, leading to the stronger expression of HS-responsive genes required for survival. Thereby, this study uncovers a new regulatory mechanism, where the temperature-dependent competitive interaction of HsfA2 and HsfA7 with HsfA1a control the fate of the master regulator and consequently the activity of temperature-responsive networks.
In mammalian species, including humans, the hippocampal dentate gyrus (DG) is a primary region of adult neurogenesis. Aberrant adult hippocampal neurogenesis is associated with neurological pathologies. Understanding the cellular mechanisms controlling adult hippocampal neurogenesis is expected to open new therapeutic strategies for mental disorders. Microglia is intimately associated with neural progenitor cells in the hippocampal DG and has been implicated, under varying experimental conditions, in the control of the proliferation, differentiation and survival of neural precursor cells. But the underlying mechanisms remain poorly defined. Using fluorescent in situ hybridization we show that microglia in brain express the ADP-activated P2Y13 receptor under basal conditions and that P2ry13 mRNA is absent from neurons, astrocytes, and neural progenitor cells. Disrupting P2ry13 decreases structural complexity of microglia in the hippocampal subgranular zone (SGZ). But it increases progenitor cell proliferation and new neuron formation. Our data suggest that P2Y13 receptor-activated microglia constitutively attenuate hippocampal neurogenesis. This identifies a signaling pathway whereby microglia, via a nucleotide-mediated mechanism, contribute to the homeostatic control of adult hippocampal neurogenesis. Selective P2Y13R antagonists could boost neurogenesis in pathological conditions associated with impaired hippocampal neurogenesis.
The NF-κB-like velvet domain protein VosA (viability of spores) binds to more than 1,500 promoter sequences in the filamentous fungus Aspergillus nidulans. VosA inhibits premature induction of the developmental activator gene brlA, which promotes asexual spore formation in response to environmental cues as light. VosA represses a novel genetic network controlled by the sclB gene. Bfunction is antagonistic to VosA, because it induces the expression of early activator genes of asexual differentiation as flbC and flbD as well as brlA. The SclB controlled network promotes asexual development and spore viability, but is independent of the fungal light control. SclB interactions with the RcoA transcriptional repressor subunit suggest additional inhibitory functions on transcription. SclB links asexual spore formation to the synthesis of secondary metabolites including emericellamides, austinol as well as dehydroaustinol and activates the oxidative stress response of the fungus. The fungal VosA-SclB regulatory system of transcription includes a VosA control of the sclB promoter, common and opposite VosA and SclB control functions of fungal development and several additional regulatory genes. The relationship between VosA and SclB illustrates the presence of a convoluted surveillance apparatus of transcriptional control, which is required for accurate fungal development and the linkage to the appropriate secondary metabolism.
Modellierung der klimatischen Habitateignung verschiedener krankheitsübertragender Vektorarten
(2018)
Der Klimawandel hat einen starken Einfluss auf die Verbreitungsgebiete von Arten. Infolgedessen kann sich das Verbreitungsgebiet von Arten verschieben, einschränken oder ausweiten. Bei thermophilen Arten wird vermutet, dass sie von den klimatischen Änderungen profitieren und sie sich wahrscheinlich ausbreiten werden. Eine solche Ausbreitung, wozu auch die Einwanderung von gebietsfremden Arten zählt, hätte nicht nur zahlreiche Konsequenzen für diese Ökosysteme, sondern könnte sich auch zu einem ernsten Gesundheitsrisiko entwickeln, wenn es sich bei den einwandernden Neobiota um Vektorarten handelt.
Stechmücken und Sandmücken, als blutsaugende Insekten, zählen zu den bekanntesten Vektorarten. Sie sind in der Lage, eine Vielzahl von Infektionskrankheiten wie das Denguefieber oder das Gelbfieber, aber auch protozoische Parasiten wie "Leishmania"-Arten zu übertragen. Als thermophile Arten sind viele dieser Vektoren aktuell in ihrer Verbreitung weitgehend auf tropische und subtropische Gebiete beschränkt. Eine Einwanderung in gemäßigtere Gebiete kann zu einer Einschleppung der durch sie übertragenden Erreger führen und damit zum Ausbruch von Infektionskrankheiten. Aufgrund der medizinischen Relevanz dieser Arten ist es essentiell, die räumliche Verbreitung, sowie die abiotischen Ansprüche der Vektorarten zu kennen, um deren mögliche Ausbreitung nachzuvollziehen.
Vor diesem Hintergrund beschäftigte sich die vorliegende kumulative Dissertation mit den klimawandelinduzierten Änderungen der Habitateignung verschiedener medizinisch relevanter Vektorarten. Dabei wurden die zwei invasiven Stechmückenarten "Aedes albopictus" (I-III) und "Aedes japonicus" (III), sowie zehn in Europa bereits vorkommende Sandmückenarten der Gattung "Phlebotomus" (IV), untersucht. Die Arbeit basiert auf vier (ISI-) Publikationen. Unter Verwendung ökologischer Nischenmodellierung wurden geeignete Gebiete unter aktuellen und zukünftigen Klimabedingungen bestimmt. Um dabei sowohl räumliche als auch zeitliche Aspekte zu berücksichtigen, wurden mehrere räumliche Skalen (Deutschland und Europa), sowie Zeitperioden (2030, 2050 und 2070) betrachtet. Des Weiteren wurden verschiedene Ansätze (einzelne Algorithmen und Ensemble-Modelle) zur Modellierung der Habitateignung verwendet.
Die Ergebnisse dieser Dissertation zeigen eine zukünftige klimawandelbedingte Ausweitung der geeigneten Gebiete für viele der betrachteten Vektorarten. So konnte gezeigt werden, dass die Habitateignung für "Aedes albopictus" in Deutschland (I) und in Europa (III) zukünftig deutlich zunimmt. Auch für die Sandmückenarten "Phlebotomus alexandri", "Phlebotomus neglectus", "Phlebotomus papatasi", "Phlebotomus perfiliewi" und "Phlebotomus tobbi" konnte eine deutliche Zunahme der klimatisch geeigneten Gebieten projiziert werden (IV).
Lediglich Arten, wie die Asiatische Buschmücke "Aedes japonicus" (III) und auch kältetolerantere Sandmücken, wie "Phlebotomus ariasi" und "Phlebotomus mascittii" (IV) scheinen weniger von diesen klimatischen Veränderungen zu profitieren und könnten in Zukunft sogar aktuell geeignete Gebiete verlieren (klimawandelinduzierte Arealverkleinerung). Bei "Aedes japonicus" konnte dies auf eine engeren Nische mit einem Optimum bei vergleichsweise niedrigen Temperaturen zurückgeführt werden (III).
Am Beispiel von "Aedes albopictus" wurden ferner Umweltfaktoren identifiziert, die die Verbreitung der Art limitieren (II). Als wärmeliebende Art spielen bei "Aedes albopictus" in Mitteleuropa insbesondere die niedrigen Temperaturen eine Rolle, während in Zukunft die Sommertrockenheit in Südeuropa zunehmend eine Rolle spielen könnte.
Nischenmodellierung stellt trotz ihrer vereinfachenden Annahmen und Unsicherheiten, eine hilfreiche Methode zur Untersuchung klimawandelinduzierter Arealverschiebungen dar. Mit Hilfe der Modellierungsergebnisse konnten Gebiete mit einem hohen Etablierungsrisiko für die Vektorarten identifiziert werden, welche daher im Fokus künftiger Überwachungsprogramme stehen sollten. In Zukunft könnten mehr Vektorarten geeignete Bedingungen in Mitteleuropa finden, wodurch die Vektordiversität zunehmen wird. Dadurch könnte auch das Risiko für einen Ausbruch der durch die Vektoren übertragenen Krankheiten steigen.
Auch wenn das Vorhandensein eines kompetenten Vektors eine unerlässliche Voraussetzung für den Ausbruch einer Infektionskrankheit darstellt, gibt es noch weitere Faktoren, wie das Vorhandensein des Erregers. In Bezug auf die Risikoabschätzung vektorassoziierter Krankheiten sollten neben der Verbreitung des Vektors und des Erregers auch die abiotischen Bedingungen für die Entwicklung des Erregers berücksichtigt werden. Neben neu eingewanderten Arten sollten zudem auch die heimischen Arten in Bezug auf ihre Vektorkompetenz untersucht werden, da diese ebenfalls als potentielle Vektoren dienen und somit das Gesundheitsrisiko weiter erhöhen könnten.
Truffles (Tuber spp.) are the fruiting bodies of symbiotic fungi, which are prized food delicacies. The marked aroma variability observed among truffles of the same species has been attributed to a series of factors that are still debated. This is because factors (i.e. genetics, maturation, geographical location and the microbial community colonizing truffles) often co-vary in truffle orchards. Here, we removed the co-variance effect by investigating truffle flavour in axenic cultures of nine strains of the white truffle Tuber borchii. This allowed us to investigate the influence of genetics on truffle aroma. Specifically, we quantified aroma variability and explored whether strain selection could be used to improve human-sensed truffle flavour. Our results illustrate that aroma variability among strains is predominantly linked to amino acid catabolism through the Ehrlich pathway, as confirmed by 13C labelling experiments. We furthermore exemplified through sensory analysis that the human nose is able to distinguish among strains and that sulfur volatiles derived from the catabolism of methionine have the strongest influence on aroma characteristics. Overall, our results demonstrate that genetics influences truffle aroma much more deeply than previously thought and illustrate the usefulness of strain selection for improving truffle flavour.
Regulation of protein turnover allows cells to react to their environment and maintain homeostasis. Proteins can show different turnover rates in different tissue, but little is known about protein turnover in different brain cell types. We used dynamic SILAC to determine half-lives of over 5100 proteins in rat primary hippocampal cultures as well as in neuron-enriched and glia-enriched cultures ranging from <1 to >20 days. In contrast to synaptic proteins, membrane proteins were relatively shorter-lived and mitochondrial proteins were longer-lived compared to the population. Half-lives also correlate with protein functions and the dynamics of the complexes they are incorporated in. Proteins in glia possessed shorter half-lives than the same proteins in neurons. The presence of glia sped up or slowed down the turnover of neuronal proteins. Our results demonstrate that both the cell-type of origin as well as the nature of the extracellular environment have potent influences on protein turnover.
Echolocation allows bats to orientate in darkness without using visual information. Bats emit spatially directed high frequency calls and infer spatial information from echoes coming from call reflections in objects (Simmons 2012; Moss and Surlykke 2001, 2010). The echoes provide momentary snapshots, which have to be integrated to create an acoustic image of the surroundings. The spatial resolution of the computed image increases with the quantity of received echoes. Thus, a high call rate is required for a detailed representation of the surroundings.
One important parameter that the bats extract from the echoes is an object’s distance. The distance is inferred from the echo delay, which represents the duration between call emission and echo arrival (Kössl et al. 2014). The echo delay decreases with decreasing distance and delay-tuned neurons have been characterized in the ascending auditory pathway, which runs from the inferior colliculus (Wenstrup et al. 2012; Macías et al. 2016; Wenstrup and Portfors 2011; Dear and Suga 1995) to the auditory cortex (Hagemann et al. 2010; Suga and O'Neill 1979; O'Neill and Suga 1982).
Electrophysiological studies usually characterize neuronal processing by using artificial and simplified versions of the echolocation signals as stimuli (Hagemann et al. 2010; Hagemann et al. 2011; Hechavarría and Kössl 2014; Hechavarría et al. 2013). The high controllability of artificial stimuli simplifies the inference of the neuronal mechanisms underlying distance processing. But, it remains largely unexplored how the neurons process delay information from echolocation sequences. The main purpose of the thesis is to investigate how natural echolocation sequences are processed in the brain of the bat Carollia perspicillata. Bats actively control the sensory information that it gathers during echolocation. This allows experimenters to easily identify and record the acoustic stimuli that are behaviorally relevant for orientation. For recording echolocation sequences, a bat was placed in the mass of a swinging pendulum (Kobler et al. 1985; Beetz et al. 2016b). During the swing the bat emitted echolocation calls that were reflected in surrounding objects. An ultrasound sensitive microphone traveling with the bat and positioned above the bat’s head recorded the echolocation sequence. The echolocation sequence carried delay information of an approach flight and was used as stimulus for neuronal recordings from the auditory cortex and inferior colliculus of the bats.
Presentation of high stimulus rates to other species, such as rats, guinea pigs, suppresses cortical neuron activity (Wehr and Zador 2005; Creutzfeldt et al. 1980). Therefore, I tested if neurons of bats are suppressed when they are stimulated with high acoustic rates represented in echolocation sequences (sequence situation). Additionally, the bats were stimulated with randomized call echo elements of the sequence and an interstimulus time interval of 400 ms (element situation). To quantify neuronal suppression induced by the sequence, I compared the response pattern to the sequence situation with the concatenated response patterns to the element situation. Surprisingly, although the bats should be adapted for processing high acoustic rates, their cortical neurons are vastly suppressed in the sequence situation (Beetz et al. 2016b). However, instead of being completely suppressed during the sequence situation, the neurons partially recover from suppression at a unit specific call echo element. Multi-electrode recordings from the cortex allow assessment of the representation of echo delays along the cortical surface. At the cortical level, delay-tuned neurons are topographically organized. Cortical suppression improves sharpness of neuronal tuning and decreases the blurriness of the topographic map. With neuronal recordings from the inferior colliculus, I tested whether the echolocation sequence also induced neuronal suppression at subcortical level. The sequence induced suppression was weaker in the inferior colliculus than in the cortex. The collicular response makes the neurons able to track the acoustic events in the echolocation sequence. Collicular suppression mainly improves the signal-to-noise ratio. In conclusion, the results demonstrate that cortical suppression is not necessarily a shortcoming for temporal processing of rapidly occurring stimuli as it has previously been interpreted.
Natural environments are usually composed of multiple objects. Thus, each echolocation call reflects off multiple objects resulting in multiple echoes following the calls. At present, it is largely unexplored how neurons process echolocation sequences containing echo information from more than one object (multi-object sequences). Therefore, I stimulated bats with a multi-object sequence which contained echo information from three objects. The objects were different distances away from each other. I tested the influence of each object on the neuronal tuning by stimulating the bats with different sequences created from filtering object specific echoes from the multi-object sequence. The cortex most reliably processes echo information from the nearest object whereas echo information from distant objects is not processed due to neuronal suppression. Collicular neurons process less selectively echo information from certain objects and respond to each echo.
For proper echolocation, bats have to distinguish between own biosonar signals and the signals coming from conspecifics. This can be quite challenging when many bats echolocate adjacent to each other. In behavioral experiments, the echolocation performance of C. perspicillata was tested in the presence of potentially interfering sounds. In the presence of acoustic noise, the bats increase the sensory acquisition rate which may increase the update rate of sensory processing. Neuronal recordings from the auditory cortex and inferior colliculus could strengthen the hypothesis. Although there were signs of acoustic interference or jamming at neuronal level, the neurons were not completely suppressed and responded to the rest of the echolocation sequence.
The marine hydrocarbonoclastic bacterium Alcanivorax borkumensis is well known for its ability to successfully degrade various mixtures of n-alkanes occurring in marine oil spills. For effective growth on these compounds, the bacteria possess the unique capability not only to incorporate but also to modify fatty intermediates derived from the alkane degradation pathway. High efficiency of both these processes provides better competitiveness for a single bacteria species among hydrocarbon degraders. To examine the efficiency of A. borkumensis to cope with different sources of fatty acid intermediates, we studied the growth rates and membrane fatty acid patterns of this bacterium cultivated on diesel, biodiesel and rapeseed oil as carbon and energy source. Obtained results revealed significant differences in both parameters depending on growth substrate. Highest growth rates were observed with biodiesel, while growth rates on rapeseed oil and diesel were lower than on the standard reference compound (hexadecane). The most remarkable observation is that cells grown on rapeseed oil, biodiesel, and diesel showed significant amounts of the two polyunsaturated fatty acids linoleic acid and linolenic acid in their membrane. By direct incorporation of these external fatty acids, the bacteria save energy allowing them to degrade those pollutants in a more efficient way. Such fast adaptation may increase resilience of A. borkumensis and allow them to strive and maintain populations in more complex hydrocarbon degrading microbial communities.
The taxanes are effective microtubule-stabilizing chemotherapy drugs that inhibit mitosis, induce apoptosis, and produce regression in a fraction of cancers that arise at many sites including the ovary. Novel therapeutic targets that augment taxane effects are needed to improve clinical chemotherapy response in CCNE1-amplified high grade serous ovarian cancer (HGSOC) cells. In this study, we conducted an siRNA-based kinome screen to identify modulators of mitotic progression in CCNE1-amplified HGSOC cells that may influence clinical paclitaxel response. PLK1 is overexpressed in many types of cancer, which correlates with poor prognosis. Here, we identified a novel synthetic lethal interaction of the clinical PLK1 inhibitor BI6727 and the microtubule-targeting drug paclitaxel in HGSOC cell lines with CCNE1-amplification and elucidated the underlying molecular mechanisms of this synergism. BI6727 synergistically induces apoptosis together with paclitaxel in different cell lines including a patient-derived primary ovarian cancer culture. Moreover, the inhibition of PLK1 reduced the paclitaxel-induced neurotoxicity in a neurite outgrowth assay. Mechanistically, the combinatorial treatment with BI6727/paclitaxel triggers mitotic arrest, which initiates mitochondrial apoptosis by inactivation of anti-apoptotic BCL-2 family proteins, followed by significant loss of the mitochondrial membrane potential and activation of caspase-dependent effector pathways. This conclusion is supported by data showing that BI6727/paclitaxel-co-treatment stabilizes FBW7, a component of SCF-type ubiquitin ligases that bind and regulate key modulators of cell division and growth including MCL-1 and Cyclin E. This identification of a novel synthetic lethality of PLK1 inhibitors and a microtubule-stabilizing drug has important implications for developing PLK1 inhibitor-based combination treatments in CCNE1-amplified HGSOC cells.