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Photorhabdus and Xenorhabdus bacteria live in a highly specific symbiosis with nematodes that belong to the genus of Heterorhabditis and Steinernema, respectively. These cruiser type nematodes actively search for soil-dwelling insects and infect them via natural openings. Inside of the insect, the bacteria are released into the hemocoel where they start producing an array of secondary metabolites to bypass the insect immune system and kill the prey within 48 hours. Many of those natural products possess bioactivities against other bacteria, fungi, protozoa or insects, which makes them interesting candidates for pharmaceutical applications. Even though advanced molecular biological methods in combination with bioinformatics tools can now be used to predict biosynthetic gene clusters (BGCs) and their products, there are still many BGCs with unknown products. Even for the plethora of natural products that were successfully identified in the last couple of years, the exact ecological function often remains elusive, as laboratory conditions can vary considerably from the natural environment of the bacteria. Knowledge about the natural conditions that stimulate, or repress production of certain natural products and their underlying regulatory mechanisms yield new approaches for natural product research and enables possibilities for selective manipulations of the regulatory cascades.
The overarching goal of this work was to examine the regulatory networks in Photorhabdus and Xenorhabdus strains. The first part of this work focused on the Hfq-dependent regulation of specialized metabolite production. In those genera, the RNA chaperone, Hfq, represses expression of hexA, which encodes for a global transcriptional regulator that acts as the master repressor for SM production. Multiple global approaches were used to identify the sRNA ArcZ, which targets a specific region in the 5’-untranslated region of the hexA mRNA and ultimately guides Hfq in order to repress its expression. It was shown that a deletion of arcZ led to a drastic reduction of SM production in Photorhabdus and Xenorhabdus, consistent with the phenotype of their respective hfq deletion mutants. Transcriptomic profiling revealed far-reaching effects on the transcriptome, with up to 735 coding sequences significantly affected in the arcZ deletion strain. Finally, it was shown that the resulting chemical background, devoid of SMs, in combination with targeted promotor exchange can be used to exclusively overproduce a desired natural product, representing an alternative route of genetic manipulation.
The second part of this work focused on the influence and identification of insect related compounds that affect SM production in P. laumondii, X. szentirmaii and X. nematophila. Insect homogenate was generated from G. mellonella larvae, a model host for these bacteria. Supplementation of the cultivation medium with homogenate induced considerable shifts in the SM profiles of those bacteria. A global effect on the transcriptional output was determined by transcriptomic profiling. The core response to the simulation of an insect environment consisted of ten CDS, eight of which are involved in the degradation of fatty acids or the import of maltose and maltodextrin into the cells. Two abundant components in the insect homogenate, trehalose and putrescin, were added to the cultivation medium of those strains and subsequent HPLC-MS analysis revealed a direct correlation of their concentration in the medium and the production titres of certain SMs. These results indicated that the bacteria sense the insect environment via different insect specific components in order to initiate a metabolic adjustment, which is probably required for adaptation to the insect host.
The last part of this work examined the influence of other, so far not directly related genes on SM production, based on the isolation of P. laumondii transposon-insertion mutants with clear phenotypic alterations. Re-sequencing and SM profiling of the mutant strains revealed that a transposon-insertion in the gene encoding for a putative DNA-adenine methyltransferase affected SM production. The phenotype was confirmed by deleting this gene. Based on Single-Molecule Real-Time sequencing, the complete methylome of the WT, deletion- and complementation mutant were analysed (experimental work performed by Sacha J. Pidot, Melbourne, Australia). No obvious alterations were detected in the methylation patterns of the strains, indicating that the dam gene product does not methylate the adenine in GATC-motifs, as it was described in literature for E. coli. This data raises the question what the function of the putative DNA-adenine methyltransferase is in P. laumondii and how it can influence the secondary metabolism. Even though there is currently no clear evidence, the potential role of epigenetic gene regulation mechanisms should be considered in further work.
Synaptic plasticity is the activity dependent alteration of the composition, form and strength of synapses and believed to be the underlying mechanism of learning and memory formation. While initial changes in synaptic transmission are caused by second messenger signaling pathways and rapid modifications in the cytoskeleton, to achieve stable and persistent changes at individual synapses, the expression of new mRNAs and proteins is required. The central dogma postulated that the cell body is the only source of newly synthesized proteins. For neurons, with their unique morphology, this meant that proteins would need be transported long distances, often hundreds of microns, to reach their destined locations in dendrites and at spines. To overcome this limitation, neurons have developed a strategy to regulate protein synthesis locally by distributing thousands of mRNAs into neuronal processes and use them for local protein synthesis. Ample research has demonstrated the importance of local protein synthesis to many forms of long-term synaptic plasticity. One potential regulator of mRNA localization and local translation in neurons are non-coding RNAs. Intensive work over the past decades has highlighted the importance of non-coding RNAs in many aspects of brain function. The aim of this thesis is to obtain a better understanding of the role of non-coding RNAs in synaptic function and plasticity in the murine hippocampus. For this, we focused our studies on two classes of non-coding RNAs.
In the first part of my thesis, I describe our efforts on characterizing circular RNAs, a novel and peculiar family of non-coding RNAs, in the murine hippocampus by combining high throughput RNA-Sequencing with fluorescence in situ hybridization. Furthermore, we investigated the mechanisms of circular RNA biogenesis in hippocampal neurons by temporarily inhibiting spliceosome activity and analyzing the differentially regulated circular RNAs.
Iron is part of many redox and other enzymes and, thus, it is essential for all living beings. Many oxic environments have extremely low concentrations of free iron. Therefore, many prokaryotic species evolved siderophores, i.e., small organic molecules that complex Fe3+ with very high affinity. Siderophores of bacteria are intensely studied, in contrast to those of archaea. The haloarchaeon Haloferax volcanii contains a gene cluster that putatively encodes siderophore biosynthesis genes, including four iron uptake chelate (iuc) genes. Underscoring this hypothesis, Northern blot analyses revealed that a hexacistronic transcript is generated that is highly induced under iron starvation. A quadruple iuc deletion mutant was generated, which had a growth defect solely at very low concentrations of Fe3+, not Fe2+. Two experimental approaches showed that the wild type produced and exported an Fe3+-specific siderophore under low iron concentrations, in contrast to the iuc deletion mutant. Bioinformatic analyses revealed that haloarchaea obtained the gene cluster by lateral transfer from bacteria and enabled the prediction of enzymatic functions of all six gene products. Notably, a biosynthetic pathway is proposed that starts with aspartic acid, uses several group donors and citrate, and leads to the hydroxamate siderophore Schizokinen.
In welchen Situationen steht ein Tier unter Stress und wie beeinflusst Stress dessen Wohlbefinden? Dies sind die Kernfragen, mit denen Zoos konfrontiert sind, wenn es darum geht, den Bedürfnissen ihrer Tiere gerecht zu werden. Die Beantwortung dieser Fragen ist jedoch angesichts der großen individuellen Variabilität des Inputs, der Stress hervorrufen kann,und des Outputs, der das Wohlbefinden bestimmt, eine Herausforderung. Um diese Herausforderung zu meistern, brauchen Zoos Kenntnisse darüber, welche Haltungsbedingungen und Managementsituationen Verhaltens-, physiologische oder emotionale Veränderungen hervorrufen, sowohl positive als auch negative. Dies trifft insbesondere auf Arten zu, die aufgrund ihrer Biologie und des großen öffentlichen Interesses große Anforderungen an das Management in Menschenobhut stellen, wie den Afrikanischen Elefanten. Die vorliegende Arbeit hatte daher das Ziel, unter Berücksichtigung der individuellen Variation die Auswirkungen bestimmter Managementsituationen auf physiologischen Stress und das Wohlbefinden der Tiere zu evaluieren.
Für diese Arbeit wurden zehn Afrikanische Elefanten aus drei Zoos im Rahmen eines Experiments in 2016 und 2017 mehrmals untersucht. Dieses Experiment umfasste zum einen die Messung von physiologischem Stress auf der Basis der Konzentration des „Stresshormons“ Cortisol im Speichel der Elefanten. Zu diesem Zweck wurden an bestimmten Tagen und zu folgenden Zeitpunkten Speichelproben entnommen: morgens, nachmittags vor und mehrmals nach einer von zwei Managementsituationen (positives Verstärkungstraining [PRT] und neuartiges Enrichmentobjekt [NOV]). Zum anderen diente die Exposition gegenüber dem neuartigen Enrichmentobjekt als sogenannter Novel Object Test. Dieser Standardtest der Persönlichkeitsforschung bei Tieren deckte bei anderen Arten konsistente Verhaltensunterschiede zwischen Individuen auf. Um zu untersuchen, ob dies auch auf Afrikanische Elefanten zutrifft, wurden die individuellen Verhaltensreaktionen auf das neuartige Objekt aufgezeichnet. Darüber hinaus wurden unabhängig von dem Experiment vor und nach einem Transport jeweils morgens und nachmittags Speichelproben von dem transferierten Tier und von zwei Tieren im Bestimmungszoo gesammelt, um den Effekt dieses potenziellen Stressors auf die individuellen Cortisolspiegel zu untersuchen.
Publikation A zeigt, dass die Elefanten unter den Bedingungen des Routinemanagements (das heißt dem routinemäßigen Tagesablauf der Tierpflege) am Morgen signifikant höhere Cortisolwerte im Speichel aufwiesen als am Nachmittag. Diese diurnale Variation der Cortisolsekretion ist typisch für tagaktive Arten und wurde daher auch für die untersuchten Elefanten erwartet. Unter Stressbedingungen wurde weder ein signifikanter Unterschied zwischen den Cortisolspiegeln vor und nach dem Transport noch zwischen den Cortisolwerten am Morgen und am Nachmittag festgestellt. Der prozentuale Unterschied zwischen dem morgendlichen und nachmittäglichen Cortisolspiegel war jedoch beim transferierten Tier nach dem Transport wesentlich geringer als vor dem Transport, was möglicherweise auf eine Stressreaktion auf den Transport und die Eingewöhnung im neuen Zoo hindeutet. Darüber hinaus zeigten sich deutliche Cortisolanstiege unmittelbar nach der ersten Zusammenführung des transferierten Tiers mit dem Bullen im neuen Zoo. Dieses Ergebnis demonstriert zum einen, dass Cortisol physiologischen Stress widerspiegelt. Zum anderen zeigt es die Notwendigkeit, zeitnah nach einem Stressor Speichelproben zu entnehmen, was nach dem Transport nicht möglich war.
Die Studie in Manuskript B zeigt unterschiedliche durchschnittliche Zeitverläufe der Cortisolantworten im Speichel auf die Managementsituationen PRT und NOV. PRT könnte aufgrund des beobachteten cortisolsenkenden und damit potenziell stresspuffernden Effekts förderlich für das Wohlbefinden sein. NOV induzierte im Mittel eine moderate, kurzfristige Cortisolantwort. Dies deutet darauf hin, dass die Tiere geringem physiologischem Stress ausgesetzt waren, mit dem sie jedoch erfolgreich umgehen konnten. Außerdem bestand eine bemerkenswerte individuelle Variation in den Cortisolverläufen in derselben Situation. Die Unterschiede im Cortisolspiegel zwischen den Tieren hingen mit dem Alter (bei NOV) und dem Zoo (bei PRT) zusammen. Der Effekt des Geschlechts und des Haltungssystems auf den Cortisolspiegel war hingegen variabel. Die Ergebnisse der Studie zeigen, dass die individuelle Variation der Cortisolsekretion unbedingt berücksichtigt werden muss, um physiologischen Stress zuverlässig zu erkennen.
Die Studie in Manuskript C ergab, dass sich die untersuchten Tiere im Novel Object Test konsistent in ihrem Verhalten gegenüber einem neuartigen Objekt unterschieden. Dieses Ergebnis zeigt, dass der Novel Object Test auch bei Elefanten genutzt werden kann, um die Persönlichkeit der Tiere zu untersuchen...
Protein turnover, the net result of protein synthesis and degradation, enables cells to remodel their proteomes in response to internal and external cues. Previously, we analyzed protein turnover rates in cultured brain cells under basal neuronal activity and found that protein turnover is influenced by subcellular localization, protein function, complex association, cell type of origin, and by the cellular environment (Dörrbaum et al., 2018). Here, we advanced our experimental approach to quantify changes in protein synthesis and degradation, as well as the resulting changes in protein turnover or abundance in rat primary hippocampal cultures during homeostatic scaling. Our data demonstrate that a large fraction of the neuronal proteome shows changes in protein synthesis and/or degradation during homeostatic up- and down-scaling. More than half of the quantified synaptic proteins were regulated, including pre- as well as postsynaptic proteins with diverse molecular functions.
Primary determinants of communities in deadwood vary among taxa but are regionally consistent
(2020)
The evolutionary split between gymnosperms and angiosperms has far‐reaching implications for the current communities colonizing trees. The inherent characteristics of dead wood include its role as a spatially scattered habitat of plant tissue, transient in time. Thus, local assemblages in deadwood forming a food web in a necrobiome should be affected not only by dispersal ability but also by host tree identity, the decay stage and local abiotic conditions. However, experiments simultaneously manipulating these potential community drivers in deadwood are lacking. To disentangle the importance of spatial distance and microclimate, as well as host identity and decay stage as drivers of local assemblages, we conducted two consecutive experiments, a 2‐tree species and 6‐tree species experiment with 80 and 72 tree logs, respectively, located in canopy openings and under closed canopies of a montane and a lowland forest. We sampled saproxylic beetles, spiders, fungi and bacterial assemblages from logs. Variation partitioning for community metrics based on a unified framework of Hill numbers showed consistent results for both studies: host identity was most important for sporocarp‐detected fungal assemblages, decay stage and host tree for DNA‐detected fungal assemblages, microclimate and decay stage for beetles and spiders and decay stage for bacteria. Spatial distance was of minor importance for most taxa but showed the strongest effects for arthropods. The contrasting patterns among the taxa highlight the need for multi‐taxon analyses in identifying the importance of abiotic and biotic drivers of community composition. Moreover, the consistent finding of microclimate as the primary driver for saproxylic beetles compared to host identity shows, for the first time that existing evolutionary host adaptions can be outcompeted by local climate conditions in deadwood.
Freshwater is one of the most fundamental resources for life and is the habitat for a wide diversity of species. One of the most diverse aquatic insect taxa is Trichoptera Kirby, 1813, caddisflies. These semi-aquatic insects have aquatic larvae and terrestrial adults and are found all around the globe in freshwater habitats. Water is also one of the most important natural resources for the human population, but alarmingly, freshwaters are among the most threatened natural habitats. Thus, the monitoring and preservation of the quality of freshwater habitats should have a high priority. In order to track changes in the biota a baseline reference is necessary, but freshwater biodiversity is under-studied in many parts of the Earth such as the biodiversity hotspots of the Himalaya and the Hengduan Mountains. This thesis treats the trichopteran genus Himalopsyche Banks, 1940 (Rhyacophilidae) which has its diversity center in the Himalayas and the Hengduan Mountains. Himalopsyche larvae are large and conspicuous and only occur in clean, unpolluted streams. This makes Himalopsyche potentially suited as indicator organisms for freshwater quality monitoring, but taxonomic knowledge is yet insufficient. Based on samples from a field survey in the Hengduan Mountains targeting both larvae and adults I uncovered three new Himalopsyche species which are described in this thesis (Chapter II), and with the aid of molecular data I associated larvae of Himalopsyche to adult species (Chapter I). The molecular association enabled the first comparative morphological study of Himalopsyche species in the larval stage, and the morphological study in Chapter II revealed that there are four distinct larval types of Himalopsyche. However, no diagnostic characters to identify Himalopsyche larvae to species level were found. To understand Himalopsyche larval morphology from an evolutionary perspective, I reconstructed the first molecular phylogeny of the genus (Chapter III). This demonstrated that each larval type corresponds to a deep phylogenetic split, indicating that larval types evolved early in Himalopsyche evolution and remained constant since. Based on the phylogenetic results as well as larval and adult morphology, I re-defined five species groups of Himalopsyche: H. kuldschensis Group, H. lepcha Group, H. navasi Group, H. phryganea Group, and H. tibetana Group. The species groups differ with respect to their diversity centers. The monotypic H. lepcha Group resides in the Himalayas, and the monotypic H. phryganea Group inhabits Western Nearctic. The H. kuldschensis and H. tibetana Groups are geographically overlapping with distributions in the Himalayas, but the distribution of H. kuldschensis Group stretches more to the west to include the Tian Shan, and the H. tibetana Group is more concentrated around the eastern Himalayas and the Hengduan Mountains. The H. navasi Group has a more eastern distribution than most Himalopsyche including isolated areas such as Japan and Indonesia. The earliest split in Himalopsyche divides the H. navasi Group from remaining Himalopsyche, suggesting a more eastern area of origin of Himalopsyche than its current diversity center, with subsequent radiations in the Himalayas and Hengduan Mountains. In addition to the three chapters, in this thesis I discuss further aspects of Himalopsyche biology including genital evolution, species complexes, and Himalopsyche ecology.
Oomycetes infecting diatoms are biotrophic parasitoids and live in both marine and freshwater environments. They are ubiquitous, but the taxonomic affinity of many species remains unclear and the majority of them have not been studied for their molecular phylogeny. Only recently, the phylogenetic and taxonomic placement of some diatom-infecting, early-diverging oomycetes was resolved, including the genera Ectrogella, Miracula, Olpidiopsis, and Pontisma. A group of holocarpic diatom parasitoids with zoospores swarming within the sporangium before release were found to be unrelated to the known genera with diatom-infecting species, and were re-classified to a new genus, Diatomophthora. However, about a dozen species of holocarpic diatom parasitoids with unclear affinity remained unsequenced, which includes a commonly occurring species so far identified as Ectrogella perforans. However, this assignment to Ectrogella is doubtful, as the species was not reported to feature a clear-cut diplanetism, a hallmark of Ectrogella s. str. and the whole class Saprolegniomycetes. It was the aim of the current study to clarify the phylogenetic affinities of the species and if the rather broad host range reported is correct or a reflection of cryptic species. By targeted screening, the parasitoid was rediscovered from Helgoland Roads, North Sea and Oslo Fjord, Southern Norway and investigated for its phylogenetic placement using small ribosomal subunit (18S) sequences. Stages of its life cycle on different marine diatoms were described and its phylogenetic placement in the genus Diatomophthora revealed. A stable host-parasite axenic culture from single spore strains of the parasitoid were established on several strains of Pleurosigma intermedium and Coscinodiscus concinnus. These have been continuously cultivated along with their hosts for more than 2 years, and cultural characteristics are reported. Cross-infection trials revealed the transferability of the strains between hosts under laboratory conditions, despite some genetic distance between the pathogen strains. Thus, we hypothesise that D. perforans might be in the process of active radiation to new host species.
Neural oscillations are at the core of important computations in the mammalian brain. Interactions between oscillatory activities in different frequency bands, such as delta (1–4 Hz), theta (4–8 Hz) or gamma (>30 Hz), are a powerful mechanism for binding fundamentally distinct spatiotemporal scales of neural processing. Phase-amplitude coupling (PAC) is one such plausible and well-described interaction, but much is yet to be uncovered regarding how PAC dynamics contribute to sensory representations. In particular, although PAC appears to have a major role in audition, the characteristics of coupling profiles in sensory and integration (i.e. frontal) cortical areas remain obscure. Here, we address this question by studying PAC dynamics in the frontal-auditory field (FAF; an auditory area in the bat frontal cortex) and the auditory cortex (AC) of the bat Carollia perspicillata. By means of simultaneous electrophysiological recordings in frontal and auditory cortices examining local-field potentials (LFPs), we show that the amplitude of gamma-band activity couples with the phase of low-frequency LFPs in both structures. Our results demonstrate that the coupling in FAF occurs most prominently in delta/high-gamma frequencies (1-4/75-100 Hz), whereas in the AC the coupling is strongest in the delta-theta/low-gamma (2-8/25-55 Hz) range. We argue that distinct PAC profiles may represent different mechanisms for neuronal processing in frontal and auditory cortices, and might complement oscillatory interactions for sensory processing in the frontal-auditory cortex network.
Neural oscillations are at the core of important computations in the mammalian brain. Interactions between oscillatory activities in different frequency bands, such as delta (1-4 Hz), theta (4-8 Hz), or gamma (>30 Hz), are a powerful mechanism for binding fundamentally distinct spatiotemporal scales of neural processing. Phase-amplitude coupling (PAC) is one such plausible and well-described interaction, but much is yet to be uncovered regarding how PAC dynamics contribute to sensory representations. In particular, although PAC appears to have a major role in audition, the characteristics of coupling profiles in sensory and integration (i.e. frontal) cortical areas remain obscure. Here, we address this question by studying PAC dynamics in the frontal-auditory field (FAF; an auditory area in the bat frontal cortex) and the auditory cortex (AC) of the bat Carollia perspicillata. By means of simultaneous electrophysiological recordings in frontal and auditory cortices examining local-field potentials (LFPs), we show that the amplitude of gamma-band activity couples with the phase of low-frequency LFPs in both structures. Our results demonstrate that the coupling in FAF occurs most prominently in delta/high-gamma frequencies (1-4/75-100 Hz), whereas in the AC the coupling is strongest in the theta/low-gamma (2-8/25-55 Hz) range. We argue that distinct PAC profiles may represent different mechanisms for neuronal processing in frontal and auditory cortices, and might complement oscillatory interactions for sensory processing in the frontal-auditory cortex network.