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Across the entire animal kingdom, sociality, i.e. the tendency of individual animals to form a group with conspecifics, is a common trait. Environmental changes have to be met with corresponding, quick adaptations. For social species, the presence of conspecifics is important for survival and if social animals are deprived of access to conspecifics, this can lead to strong and lasting changes on a physiological level as well as behaviour. Gene expression changes responsible for these adaptations have so far not been understood in detail. As social isolation leads to changes on a neuronal level, it is important to investigate the gene expression changes that are induced in the brain. In this thesis, next-generation RNA-sequencing was applied to zebrafish, a well-established model organism characterized by its high degree of companionship. Within the entire brain, gene expression was analysed in zebrafish that were raised either with conspecifis or in isolation, ranging from 5 to 21 days post fertilization. Using this approach, several genes were identified that were downregulated by social isolation. In this thesis, I focused on one of these consistently downregulated genes, parathyroid hormone 2 (pth2). The expression of pth2 was demonstrated to be bidirectionally regulated by the number of conspecifics present and to be responsive to changes in the social environment within 30 minutes. Regulation of pth2 does not occur by visual or chemosensory access to conspecifcs, but is mediated by mechanosensory perception of other fish via the lateral line. In an experiment using an artificial mechanical stimulation paradigm, it was shown that the features necessary to elicit pth2 transcription closely mimick the locomotion of actual zebrafish. Other, similar stimulation paradigms are not capable to induce this transcriptional response.
Nematophilic bacteria as a source of novel macrocyclised antimicrobial non-ribosomal peptides
(2020)
A solution to ineffective clinical antimicrobials is the discovery of new ones from under-explored sources such as macrocyclic non-ribosomal peptides (NRP) from nematophilic bacteria. In this dissertation an antimicrobial discovery process –from soil sample to inhibitory peptide– is demonstrated through investigations on six nematophilic bacteria: Xenorhabdus griffiniae XN45, X. griffiniae VH1, Xenorhabdus sp. nov. BG5, Xenorhabdus sp. nov. BMMCB, X. ishibashii and Photorhabdus temperata. To demonstrate the first step of bacterium isolation and species delineation, endosymbionts were isolated from Steinernema sp. strains BG5 and VH1 that were isolated directly from soil samples in Western Kenya. After genome sequencing and assembly of novel Xenorhabdus isolates VH1 and BG5, species delineation was done via three overall genome relatedness indices. VH1 was identified as X. griffiniae VH1, BG5 as Xenorhabdus sp. nov. BG5 and X. griffiniae BMMCB was emended to Xenorhabdus sp. nov. BMMCB. The nematode host of X. griffiniae XN45, Steinernema sp. scarpo was highlighted as a putative novel species. To demonstrate the second step of genome mining and macrocyclic non-ribosomal peptide structure elucidation, chemosynthesis and biosynthesis, the non-ribosomal peptide whose production is encoded by the ishA-B genes in X. ishibashii was investigated. Through a combination of refactoring the ishA-B operon by a promoter exchange mechanism, isotope labelling experiments, high resolution tandem mass spectrometry analysis, bioinformatic protein domain analysis and chemoinformatic comparisons of actual to hypothetical mass spectrometry spectra, the structures of Ishipeptides were elucidated and confirmed by chemical synthesis. Ishipeptide A was a branch cyclic depsidodecapeptide macrocyclised via an ester bond between serine and the terminal glutamate. It chemosynthesis route was via a late stage macrolactamation and linearised Ishipeptide B was synthesised via solid phase iterative synthesis. Ishipeptides were not N-terminally acylated despite being biosynthesised from the IshA protein that had a C-starter domain. It was highlighted that more than restoration of the histidine active site of this domain is required to restore N-terminal acylation activity.
To demonstrate the final step of determination of antimicrobial activity, minimum inhibitory concentrations of Ishipeptides and Photoditritide from Photorhabdus temperata against fungi and bacteria were determined. None were antifungal while only the macrocyclic compounds were inhibitory, with Ishipeptide A inhibitory to Gram-positive bacteria at 37 µM. The cationic Photoditritide, a cyclic hexapeptide macrocyclised via a lactam bond between homoarginine and tryptophan, was 12 times more inhibitory (3.0 µM), even more effective than a current clinical compound, Ampicillin (4.2 µM). For both, macrocyclisation was hypothesised to contribute to antimicrobial activity. Ultimately, this dissertation demonstrated not only nematophilic bacteria as a source of novel macrocyclic antimicrobial non-ribosomal peptides but also a process of antimicrobial discovery–from soil sample to inhibitory peptide– from these useful bacteria genera. This is significant for the fight against antimicrobial resistance.
Nematophilic bacteria as a source of novel macrocyclised antimicrobial non-ribosomal peptides
(2020)
A solution to ineffective clinical antimicrobials is the discovery of new ones from under-explored sources such as macrocyclic non-ribosomal peptides (NRP) from nematophilic bacteria. In this dissertation an antimicrobial discovery process –from soil sample to inhibitory peptide– is demonstrated through investigations on six nematophilic bacteria: Xenorhabdus griffiniae XN45, X. griffiniae VH1, Xenorhabdus sp. nov. BG5, Xenorhabdus sp. nov. BMMCB, X. ishibashii and Photorhabdus temperata. To demonstrate the first step of bacterium isolation and species delineation, endosymbionts were isolated from Steinernema sp. strains BG5 and VH1 that were isolated directly from soil samples in Western Kenya. After genome sequencing and assembly of novel Xenorhabdus isolates VH1 and BG5, species delineation was done via three overall genome relatedness indices. VH1 was identified as X. griffiniae VH1, BG5 as Xenorhabdus sp. nov. BG5 and X. griffiniae BMMCB was emended to Xenorhabdus sp. nov. BMMCB. The nematode host of X. griffiniae XN45, Steinernema sp. scarpo was highlighted as a putative novel species. To demonstrate the second step of genome mining and macrocyclic non-ribosomal peptide structure elucidation, chemosynthesis and biosynthesis, the non-ribosomal peptide whose production is encoded by the ishA-B genes in X. ishibashii was investigated. Through a combination of refactoring the ishA-B operon by a promoter exchange mechanism, isotope labelling experiments, high resolution tandem mass spectrometry analysis, bioinformatic protein domain analysis and chemoinformatic comparisons of actual to hypothetical mass spectrometry spectra, the structures of Ishipeptides were elucidated and confirmed by chemical synthesis. Ishipeptide A was a branch cyclic depsidodecapeptide macrocyclised via an ester bond between serine and the terminal glutamate. It chemosynthesis route was via a late stage macrolactamation and linearised Ishipeptide B was synthesised via solid phase iterative synthesis. Ishipeptides were not N-terminally acylated despite being biosynthesised from the IshA protein that had a C-starter domain. It was highlighted that more than restoration of the histidine active site of this domain is required to restore N-terminal acylation activity.
To demonstrate the final step of determination of antimicrobial activity, minimum inhibitory concentrations of Ishipeptides and Photoditritide from Photorhabdus temperata against fungi and bacteria were determined. None were antifungal while only the macrocyclic compounds were inhibitory, with Ishipeptide A inhibitory to Gram-positive bacteria at 37 µM. The cationic Photoditritide, a cyclic hexapeptide macrocyclised via a lactam bond between homoarginine and tryptophan, was 12 times more inhibitory (3.0 µM), even more effective than a current clinical compound, Ampicillin (4.2 µM). For both, macrocyclisation was hypothesised to contribute to antimicrobial activity. Ultimately, this dissertation demonstrated not only nematophilic bacteria as a source of novel macrocyclic antimicrobial non-ribosomal peptides but also a process of antimicrobial discovery–from soil sample to inhibitory peptide– from these useful bacteria genera. This is significant for the fight against antimicrobial resistance.
The present study approached two related but conceptually different questions of EV biology in cancer. In both approaches, tailored variants of the Cre LoxP system were utilized. First, in the context of intradermal and intracranial tumours, it was examined which cells in the tumour microenvironment (TME) take up tumour derived
EVs and what effects EV uptake has on recipient cells. Secondly, in the context of glioma, peripheral macrophages (MF) were directly traced to the brain and
separated from brain resident microglia (MG). Furthermore, EV signalling between these entities was analysed.
Regarding the first approach, multidirectional transfer of functional Cre recombinase RNA in intradermal and intracranial mouse tumour models was observed. In spite of robust recombination rates in all tumour models, the total number of EV-uptaking cells is around three times higher than the total number of recombined cells, suggesting that interactions of cells and EVs which contain CremRNA does not necessarily lead to marker gene expression. Subsequent studies can build up on this established system and isolate and characterise EV-uptaking cells to identify geno- and phenotypical changes induced by EV uptake.
The second, conceptionally different aspect that was investigated in this study is the distinction and tracing of peripheral MF to the brain and their distinction from
brain resident MG in glioma. Glioblastoma multiforme (GBM) is the most common and the most malignant brain tumour. The average patient survival of 15 months
past diagnosis did not change much during the last decades, which stresses the need for new therapies. GBM location in the immune privileged brain, its characteristically highly immune suppressive TME and its highly invasive growth
makes this disease so difficult to treat. Immune therapies, which in general show good results in other types of cancer, are not effective in GBM. To a great extent, this can be ascribed to the lack of understanding of MG and MF function in GBM and their roles in tumour progression.
Carotinoide sind Pigmente, die in Pflanzen, Algen, einigen Pilzen und Bakterien vorkommen. Sie spielen eine wichtige Rolle bei der Photosynthese durch Absorption von Licht und beim Lichtschutz. Sie sind verantwortlich für die braunen, roten, orangen und gelben Farben von Obst, Gemüse, Herbstblättern und die Farbe einiger Blumen und Algen. Tiere können keine Carotinoide synthetisieren, daher ist ihre Anwesenheit auf die Nahrungsaufnahme zurückzuführen. Carotinoide sind Tetraterpenoide (40C), die aus Isoprenoidmolekülen (5C) synthetisiert werden. Der Methylerythritol-phosphatweg ist der Carotinoid-Vorläuferweg, der die Isoprenoideinheiten bildet. Carotinoide haben aufgrund ihrer gesundheitlichen Vorteile das Interesse der Nutrazeutika-Industrie geweckt.
Fucoxanthin ist ein Carotinoid, das nur in Kieselalgen, Braunalgen, Haptophyten und einigen Dinoflagellaten vorkommt. Aufgrund seiner Vorteile zur Vorbeugung von Krebs, kognitiven Erkrankungen und Fettleibigkeit sowie seiner antioxidativen Eigenschaften ist Fucoxanthin ein sehr interessantes Molekül fur die Nutrazeutikabranche.
Fucoxanthin hat eine komplexe chemische Struktur mit einer Allenbindung und einer Epoxyketogruppe. Daher wäre seine chemische Synthese kompliziert, da es auch eine stereokontrollierte Synthese erfordert86. Aus diesem Grund ist die Extraktion aus Makroalgen oder Mikroalgen die Methode der Wahl für die kommerzielle Herstellung von Fucoxanthin.
In dieser Arbeit bestand das Ziel darin, die Fucoxanthin-Produktivität in Kieselalgen mit gentechnischen Methoden zu steigern, damit die Zellen mehr Fucoxanthin produzieren. Zu diesem Zweck wurde der Effekt der Insertion zusätzlicher Kopien von Genen in das Genom untersucht, die für geschwindigkeitsbestimmende oder Schlüsselenzyme im Carotinoid- und MEP-Weg kodieren.
Zu Beginn wurden diese Effekte bei einzelnen Mutanten beobachtet. Letztendlich ist es jedoch das Ziel, eine Mutante zu erzeugen, die mehrere geschwindigkeitsbestimmende Enzyme überexprimiert, um auf diese Weise Engpässe zu vermeiden. In früheren Studien erreichten Eilers et al.54 durch die einmalige Überexpression der psy- und dxs-Gene in der Kieselalge P. tricornutum einen 2.4- und 1.8-fachen Anstieg der Fucoxanthin-Spiegel.
In dieser Arbeit führte die Insertion zusätzlicher Kopien der Gene idi und pds2 nicht dazu, dass die Zellen mehr Fucoxanthin produzieren. Im Gegensatz dazu erreichten die Mutanten mit zusätzlichen Kopien der Gen ggpps und mit zusätzlichen Kopien sowohl von psy als auch von dxs seine um 28% bzw. 10% höhere Fucoxanthin-Produktivität pro Million Zellen. Bei diesen Mutanten ist die Gesamtproduktivität jedoch geringer als beim Wildtyp, da ihr Wachstum langsamer als beim Wildtyp ist.
Unter Berücksichtigung der besten Zielgene wurden Mutanten erzeugt, die gleichzeitig zusätzliche Kopien von psy, dxs und ggpps enthielten. Die Mutanten hatten unter sehr niedriegen Lichtbedingungen eine um bis zu 61% höhere Produktivität pro Million Zellen als der Wildtyp. Ausnahmsweise wurden diese Mutanten bei sehr schwachem Licht (10 µE m-2 s-1) gezüchtet, da sie sehr gestresst waren und als Zellklumpen wuchsen. Obwohl die Gesamt-Fucoxanthin-Spiegel in diesen Mutanten unter diesen Bedingungen höher sind als im Wildtyp, sind sie daher niedriger als die Fucoxanthin-Spiegel bei den in anderen Experimenten verwendeten Lichtbedingungen (50 µE m-2 s-1). Als Ergebnis dieser Experimente kann gesagt werden, dass die Belastung der Zellen nach den genetischen Veränderungen untersucht werden muss, da dies zu einer Abnahme der Biomasse und folglich zu einer Abnahme der Fucoxanthinproduktion führt. Alternativ könnte auch eine 2-Stufen-Kultur etabliert werden, in der in einem ersten Schritt eine hohe Biomasse erreicht wird und im zweiten Schritt die Expression der interessierenden Gene induziert wird.
Aufgrund der antioxidativen Eigenschaften von Carotinoiden besteht eine übliche Strategie zur Akkumulation von Carotinoiden darin, die Zellen unter oxidative Stressbedingungen zu setzen. Diese Strategie ist jedoch nicht wirksam für die Anreicherung von Fucoxanthin unter hohen Salzkonzentrationen oder hohen Lichtbedingungen. Bessere Versuchspläne könnten jedoch eine 2-Stufen-Kultur oder adaptive Laborbedingungen gewesen sein.
Eine andere mögliche Strategie zur Erhöhung des Fucoxanthinspiegels wäre die Durchführung einer zufälligen Mutagenese der Zellen. Auf diese Weise sind keine Vorkenntnisse über den Carotinoidsyntheseweg und seine Regulation erforderlich und es kann zu Veränderungen in Genen führen, die keine offensichtlichen Ziele sind.
Experimente mit zufälliger Mutagenese erfordern ein Hochdurchsatz-Screeningsystem, da Hunderte oder sogar Tausende von Mutanten erhalten werden. Eine mögliche Strategie, um die Kultivierung der hohen Anzahl von Mutanten zu vereinfachen, ist die Einkapselung dieser Mutanten in Alginatkügelchen. Auf diese Weise können alle Mutanten in demselben Gefäß kultiviert werden. Die eingekapselten Zellen können dann beispielsweise mit einem Durchflusszytometer auf große Partikel durch Fluoreszenz- oder Absorptionsmessungen gescreent werden.
...
The early-diverging oomycetes contain a large number of holocarpic obligate parasites of diatoms, algae, aquatic phycomycetes, and invertebrate animals. These organisms are diverse and widespread. However, taxonomic placement most of the early-diverging oomycetes remains provisional and unresolved, since many have not been sequenced and studied for molecular phylogeny. Here, we report the taxonomy and phylogeny of several holocarpic oomycetes that we have rediscovered and newly classified, including several new species combinations. Phylogenetic reconstructions revealed that the type species of genus Ectrogella (E. bacillariacearum) is a member of the early-diverging Saprolegniales, while the type species of Olpidiopsis (O. saprolegniae) and Pontisma (P. lagenidioides) grouped within the early-diverging lineage of oomycetes forming distinct clades. Since the monophyletic red-algae parasitoids are unrelated to the Olpidiopsis, these were reclassified to the genus Pontisma, while genus Diatomophthora was introduced to accommodate all the diatom parasitoids that were previously assigned to Olpidiopsis. In addition, four new oomycete parasitoids, Miracula helgolandica, Miracula moenusica, Diatomophthora drebesii and Olpidiopsis parthenogenetica and a single rediscovered species, Diatomophthora gillii, are also classified here, including eight new species combinations of red-algae parasites (Pontisma bostrychiae, P. heterosiphoniae, P. muelleri, P. palmariae, P. porphyrae, P. pyropiae) and diatom parasitoids (Diatomophthora drebesii, D. gillii). The results obtained in this study have further improved the resolution and expanded the knowledge on the phylogeny of the earlydiverging oomycetes, leading to the establishment of three new orders (Miraculales, Diatomophthorales, Pontismatales) and one order (Anisolpidiales) being reintroduced.
Even one century after Santiago Ramón y Cajal’s groundbreaking contribu- tions to neuroscience, one of the most fundamental questions in the field is still largely open, namely understanding how the shape of a dendrite is adapted to its specific biological function. A systematic investigation of this problem is challenging both technically and conceptually because neurons have diverse genetic, molecular, morphological, connectional and functional properties.
In the light of the preceding, dendritic arborisation (da) neurons of the Drosophila melanogaster larva PNS have proven to be an excellent model system for the study of such growth and patterning processes. Structure and function in these cell classes are intimately intertwined, as class type-specific dendritic arbour differentiation processes are required to satisfy a given phys- iological need. Also, there is a remarkable genetic toolkit that enables one to selectively and reproducibly label, image and manipulate each one of these sensory neuron classes. In this thesis, I address the aforementioned open problem by linking single-cell patterning, information processing and wiring optimisation in sensory da neurons to behaviour in Drosophila larva.
In particular, I study Class I ventral peripherical dendritic arborisation (c1vpda) neurons. These are a class of proprioceptive neurons that relay information on the position of the larva’s body back to the CNS during crawling behaviour to assure proper locomotion. Their stereotypical comb- like shaped dendritic branches spread along the body-wall, and they get noticeably deformed during crawling behaviour. The bending of the den- dritic branches is hypothesised to be a possible mechanism to transduce the mechanosensory inputs arising from cuticle folding. Interestingly, c1vpda neurons do not necessarily satisfy optimal wiring constraints since they are required to pattern into a specific shape to fulfil their function. Therefore, I considered the da system to study how the specific functional requirements may be combined with optimal wiring constraints during development.
Although the molecular machinery of dendrite patterning in c1vpda neurons is well studied, the precise elaboration of the comb-like shaped dendrites of these cells remains elusive. Moreover, even though a lot of work has been put into the description and quantification of growth processes of the nervous system, there are still few solid and standardised models of arbour staging and patterning. Importantly, the defining parameters that determine the dendrite elaboration program that in turn is responsible for creating the final arbour morphology are still unknown. As a result, unraveling possible universal stages of dendrite elaboration shared between different model systems and cell types is challenging.
Thus, in order to understand the development of the fine regulation of branch outgrowth that leads to the observed terminal arbour morphology in the mature cell, I collected in vivo, long-term, non-invasive high temporal res- olution time-lapse recordings of dendritic trees during the differentiation process in the embryo and its maturation phase in the larva. For further analysis, I developed new algorithms that quantified the structural changes in dendrite morphology in the time-lapse videos. My approach provides a framework to analyse such developmental data, or any dataset comprising continuous morphological dynamical processes in an unbiased way. Using these newly developed methods, I examined the development of a sample of c1vpda cells and identified five stages of differentiation in these data: initial stem polarization, extension, pruning, stabilization, and isometric stretching during larval stages.
The beginning of the growth process is marked by the polarisation of the main stem. Subsequently, during the extension phase, branches emerge interstitially from the existing main stem. Later, higher-order branches sprout from pre-existing lateral branches, increasing arbour complexity. This is followed by a pruning stage where developmental intermediate dendritic branches are removed. This step leads to a spatial rearrangement of the dendritic tree. The end of the pruning step is followed by a stabilisation period where arbour morphology remains virtually unaltered in the embryo. After hatching, c1vpda dendrites experience an isometric scaling, with their branching complexity and pattern being invariant across all larval stages.
After dissecting the c1vpda dendrites spatiotemporal differentiation process, I established a link between dendritic shape and behaviour. I measured intra- cellular Ca++ activity in the dendrite branches of l1 larvae during forward locomotion, while simultaneously recording branch deformation using a dual genetic line. I reported that post-embryonic c1vpda dendrites Ca++ responses increased in freely crawling larvae. Furthermore, I showed strong correlations between Ca++ signal and deformation of the comb-like dendritic ranches during body-wall contractions.
Then, using a geometrical model, I provided evidence that the pruning stage could reorganise the dendrite morphology to maximise mechanosensory re- sponses during body wall contraction. I showed that the angle orientation of each side branch correlates with the bending curvature and thus with the me- chanical displacement of the cell membrane during locomotion. During the pruning phase, I observed a preferential reduction of less efficient branches with low bending curvature, influencing the mechanisms of dendritic sig- nal integration of c1vpda sensory neurons. I proceeded to quantify branch dynamics at single tip resolution during pruning, providing evidence that a simple random pruning mechanism is sufficient to remodel the tree structure compatible with the observed way.
I used these time-lapse data to constrain a new computational noisy growth model with random pruning based on optimal wiring principles. This model is able to generate highly realistic synthetic c1vpda morphologies. The model furthermore requires few parameters to generate highly accurate temporal development trajectories and morphologies at single-cell level. Utilising this data and model enabled me to investigate upon the hypothesis that a noisy dendrite growth and random pruning mechanism synergise to achieve den- dritic trees efficient in terms of both wiring and function. My findings show how single neurons can create functionally specialised dendrites while min- imising wiring costs, elucidating how general principles of self-organisation may be involved in the generation of these structures.
Die CXCR4/CXCL12-Achse ist von entscheidender Bedeutung für die Entstehung und Aufrechterhaltung einer gesunden, reifen Hämatopoese. Erstmals beschrieben wurde der später als CXCR4 bezeichnete Rezeptor 1996 allerdings als Co-Rezeptor für den Eintritt humaner HI-Viren in Lymphozyten. Ein großes Interesse bestand daraufhin darin, sowohl natürliche Inhibitoren des G-Protein gekoppelten Rezeptors zu identifizieren, als auch synthetische herzustellen, um einen Eintritt des Virus in den menschlichen Organismus zu verhindern bzw. seine Ausbreitung zu unterbinden. Ein natürlich vorkommender CXCR4-Ligand, der 2015 von Zirafi und Kollegen erstmals beschrieben wurde, fand sich im Hämofiltrat von Dialysepatienten. Der im weiteren Verlauf als EPI-X4 bezeichnete CXCR4-Antagonist wurde als Spaltprodukt von Albumin identifiziert, welches über viele Spezies hochkonserviert ist. Diese Eigenschaft interpretieren wir als Hinweis auf eine relevante physiologische Funktion des Peptids. Da die Halbwertszeit von natürlich vorkommendem EPI-X4 beim Menschen vermutlich sehr kurz ist, sind in vivo- und darauffolgende in vitro-Analysen schwierig durchzuführen. In-vitro-Spike-Analysen von synthetischem EPI-X4 in humanem Plasma ergaben eine Halbwertszeit von nur 17 Minuten. Die geringen auftretenden Konzentrationen erschweren die Problematik zusätzlich. In dieser Arbeit sollen deshalb im Mausmodell in vivo-Analysen durchgeführt werden, um die Effekte von potentiell entstehendem EPI-X4 in verschiedenen experimentellen Ansätzen aufzudecken. Ein probates, hier verwendetes Mittel, ist die Analyse einer Knock-out (KO)-Maus. Die für die Bindung an CXCR4 entscheidende Aminosäure von EPI-X4, das am N-Terminus gelegene Leucin, wurde durch Alanin ersetzt, welches die Entstehung von EPI-X4 unterbindet und zusätzlich dessen Bindung an CXCR4 verhindert. Mit Hilfe zweier Mausmodelle können nun Analysen im EPI-X4-defizienten Modell durchgeführt werden, die im Umkehrschluss Informationen über die organismische Wirkung von EPI-X4 beinhalten. Zunächst wurde in beiden Modellen die physiologisch normale reife und unreife Hämatopoese charakterisiert. Hierbei zeigte sich kein signifikanter systematischer Einfluss von EPI-X4 auf reife Leukozyten (WBC), lediglich eine leichte Lymphozytose in der HR-Ala-Variante. Im weiteren Verlauf der homöostatischen Analyse der Hämatopoese der Ala-EPI-X4-Mäuse zeigten sich keine signifikanten Unterschiede zu wildtypischen Mäusen. Sowohl reife als auch unreife Zellen zeigten, außer in der T- und B-Zelllinie, keine zahlenmäßigen oder funktionalen Auffälligkeiten, weder im Blut, noch in der Milz oder im Knochenmark. Analysen der Zellzyklusaktivität unterschiedlicher Unreifestufen wiesen ebenfalls keine Auffälligkeiten auf. Diese Daten einer normalen, von einer C57Bl/6-Maus zu erwartenden Ergebnisse dienten als Grundlage zur Bewertung und Analyse von durchgeführten hämatopoetischen Stressmodellen. Hierfür wurden
zunächst hämatopoetische Stamm- und Vorläuferzellen (HSPC) mobilisiert. In den angewandten Mobilisierungsmodellen fanden sich lediglich unter G-CSF-Behandlung im Knochenmark eine größere Anzahl Granulozyten, was auf einen Einfluss von EPI-X4 auf HSPC schließen lässt. Um potentielle Auswirkungen von EPI-X4 im Knochenmark weiter zu untersuchen, wurde ein weiteres Stressmodell gewählt, welches ebenfalls mutmaßlich die Bedingungen zur EPI-X4-Generierung schafft: Subletale Bestrahlung der Mäuse sorgt für Schäden an allen Zellarten im Knochenmark, es wird ein steriles entzündliches Milieu kreiert. Unter diesen Umständen wurde die Regeneration von Blutzellen analysiert. Es zeigten sich keine nennenswerten Unterschiede sowohl in der akuten Phase des Schadens als auch in regelmäßigen Blutentnahmen während der Regenerierung.
Die Beschreibung von natürlich vorkommendem EPI-X4 in Vaginal- und Rektalschleimhaut zeigt seine Entstehung an Schleimhautbarrieren auf. Ala-EPI-X4-Muse werden deshalb auf deren Durchlässigkeit untersucht: LPS-Konzentrationen als Marker für eindringende pathogene Bakterien wurden im Plasma untersucht. Hierbei zeigten sich keine Unterschiede zwischen den Gruppen, eine Störung scheint hier nicht vorzuliegen. Zusätzlich wurde die Zusammensetzung des Mikrobioms im Darm untersucht, da beschrieben wurde, dass sich Mikrobiom und die Integrität der Darmschleimhaut gegenseitig beeinflussen. Im Falle der EPI-X4-defizienten Mäuse liegt zwar keine offensichtliche pathologische Veränderung vor, dennoch konnte in männlichen HR-Ala-Mäusen die Abwesenheit des Proteobakteriums Parasutterella nachgewiesen werden. Um eine mögliche Defizienz der Barrierefunktion weiter zu testen, wurden zwei Stressmodelle gewählt: Zunächst wurde den Mäusen eine akute, sterile Peritonitis zugefügt, woraufhin die Anzahl und Zusammensetzung der ins Peritoneum einströmenden Leukozyten analysiert wird. Die Reaktion auf diesen Entzündungsprozess war nicht verändert. Ähnliche Ergebnisse zeigten sich auch in einem akuten Colitis-Stressmodell.
Insgesamt konnte in dieser Arbeit mithilfe zweier KO-Mausmodelle die Rolle von EPI-X4 in der Hämatopoese und der Immunologie von Mäusen beginnend charakterisiert werden. Die homöostatische Hämatopoese scheint kaum von EPI-X4 abhängig zu sein, lediglich die Zahl der B- und T-Zellen, insbesondere der regulatorischen T-Zellen, scheint beeinflusst. Damit einhergehend konnten Veränderungen in Zytokinlevels bei inflammatorischen Ereignissen gezeigt werden. Experimente zur beeinflussten, eventuell gestörten Barrierefunktion von Ala-EPI-X4-Mäusen zeigten vielversprechende Ansätze und sollten in Zukunft weiter analysiert werden.
The blood-brain barrier (BBB) protects the brain microenvironment from external damage. It is formed by endothelial cells (ECs) lining the brain vessels, expressing tight junctions and having reduced transcytosis, resulting in a very low paracellular and transcellular passage of substances, respectively (low permeability). The specific BBB phenotype is maintained by Wnt molecules secreted by astrocytes (ACs) that bind to receptors in ECs, and start a molecular cascade that leads to β-catenin translocating to the nucleus and activating the transcription of BBB genes.
An increasing number of studies report BBB dysfunction in Alzheimer’s disease (AD), although the topic is currently under debate. AD is a neurodegenerative condition characterized by brain depositions of Aβ aggregates and Tau neurofibrillary tangles. The aetiology of AD is unknown, although round 5% of all AD cases have a genetic origin. Mutations in APP or PSEN1/2 can lead to Aβ over-production and accumulation, causing familiar AD. There is no cure for AD, as all clinical trials failed during the past years. Consequently, I studied the role of the BBB in AD, aiming to investigate if a BBB dysfunction occurs in AD, and to identify by transcriptomic analysis novel gene regulations happening at the BBB in AD. The final objective was to evaluate the potential of identified BBB genes as therapeutical target.
I used transgenic mice expressing the human APP mutations Swiss, Dutch and Iowa under the control of the neuronal promoter Thy1 (Thy1-APPSwDI) as AD model. In this AD mouse model, I could detect Aβ deposits and memory loss by immunofluorescence (IF) and behavioural tests. Importantly, I identified an increase of BBB permeability to 3-4 kDa dextrans in 6 months, 9-12 months, and 18 months or older AD mice compared to age-matched control wild types (WT), indicating BBB dysfunction in AD mice.
In order to study the BBB transcriptional changes in AD, I sequenced the RNA from 6 and 18 months old AD and WT mouse brain microvessels (MBMVs), as well as of FACS-sorted ECs, mural cells (MuCs), ACs, and microglia (MG) in collaboration with GenXPro, a company specialized in 3’ RNA sequencing. Currently, no transcriptomic datasets of ECs and MuCs are publicly available, suggesting that this is the first study sequencing those cell types in the context of AD.
The analysis of sequencing data from MBMVs and ECs revealed a Wnt/β-catenin repression, and an increase of inflammatory genes like Ccl3 in ECs, that could explain the BBB dysfunction observed in AD mice. Furthermore, the sequencing data from MuCs identified a set of 11 genes strongly regulated in both 6 and 18 month AD groups. Three of those 11 genes are known to be involved in inflammatory processes, demonstrating that inflammation affects and plays an important role in MuCs and ECs during AD.
Thanks to published sequencing data, some up-regulated MG genes in AD are well known and recognized, such as Trem2 and Apoe. Those genes were found in the FACS-sorted MG data as well, validating the AD model and with it, the other novel sequenced datasets. Importantly, one of the most strongly AD-regulated genes in MBMV and MG samples was Dkk2, a member of the Dickkopf family of secreted proteins known to be involved in Wnt signalling modulation. Importantly, a dual luciferase reporter assay proved that Dkk2 is a Wnt inhibitor. A preliminary immunohistochemistry examination of DKK2 in human brain autopsy tissue from an AD patient and age-matched control revealed a stronger DKK2 immunoreactivity in the AD brain.
In order to answer the question whether a rescue of BBB function would ameliorate AD symptoms, I made use of a tamoxifen-inducible transgenic mouse line to activate the Wnt/β-catenin pathway specifically in ECs, leading to a gain of function (GOF) condition (Cdh5-CreERT2+/–/Ctnnb1(Ex3)fl/fl). This mouse line was then crossed with the AD line, creating AD/GOF and AD/control groups.
AD/GOF mice performed better in a Y-Maze memory test than AD/controls when the Wnt/β-catenin pathway was induced before AD onset, indicating a protective effect. Moreover, the finding implies that shielding BBB functioning in AD further protects the brain from AD toxic effects, suggesting an important role of brain vasculature in AD and its potential as therapeutic target.
Light is one of the most important abiotic factors for plant physiological processes. In addition to light intensity, the spectral quality of light can also influence the plant morphology and the content of secondary metabolites. In the horticultural industry, artificial light is used in to enable year-round production of herbs, ornamental plants and vegetables in winter terms.
Until today, discharge lamps like high-pressure sodium (HPS) lamps, emitting predominantly orange and red light and high amounts of infrared radiation, are the most common lamp systems in greenhouses. In the last decades, light-emitting diodes (LEDs) emerged as an efficient alternative light source. LEDs have the advantage of distinct adjustments to the light spectrum. For a usage in horticultural industry LEDs are often too expensive. Furthermore, reduced plant growth can occur due to incorrectly adjusted light spectra and lower leaf temperatures caused by the lack of infrared radiation.
In a research project (LOEWE, funding no. 487/15-29) funded by the Hessen State Ministry of Higher Education, Research and Arts, Microwave plasma lamps (MPL) were tested as new light sources for horticultural industry and plant research. The electrodeless lamp systems emit light in similar properties like sun light. The aim of the study was to determine the influence of artificial sunlight of the MPL on the accumulation of secondary metabolites, plant architecture and plant physiology of three different species (coleus, basil and potted roses). The MPL was compared with other light systems such as commercial HPS lamps, LEDs or ceramic metal halide lamps (CDM). In addition to morphological parameters such as plant height, internode length or fresh and dry weight, the phenolic content of leaves grown under the respective light sources were examined.
Overall an increased far-red light content in the emission spectra of the MPL showed high influence on the plant architecture which was observed in all three plant species. Artificial sunlight from MPL induced stem elongation in coleus and basil plants, compared to the other tested light sources. In potted roses a reduced branching degree was observed under MPL light compared to HPS grown plants.
In addition to the impact of far-red light also the blue light content of the emission spectra was found to be a strong influencing factor for plant physiological processes. A positive correlation between blue light content and leaf thickness was determined in coleus cultivated under MPL, LED, HPS and CDM lamps. Low blue light content in HPS emission spectra resulted in shade-adapted leaves with low photosynthetic capacity and susceptibility to high irradiances. Blue light was assumed to increase phenolic metabolites in basil and rose leaves. Furthermore, the different light treatments resulted in an alteration of the composition of essential oils of basil.
Experiments with coleus plants demonstrated that besides light color also the infrared radiation, had an influence on secondary metabolites by causing different leaf temperatures. Coleus plants grown with MPL showed the lowest content of phenolic compounds such as rosmarinic acid per dry weight. Infrared radiation resulted in a faster plant development indicated by increased biomass production and higher leaf formation rate as observed in coleus and basil plants.
The results obtained in this study show that the influence of leaf temperature should always be considered when comparing different lamp systems. Especially when LEDs are compared to discharge lamps an overestimation of light color can be a consequence since also infrared radiation influences the content of phenolic compounds and plant growth.
Zur Evolution der Hirnmorphologie und Anpassungen an Extremhabitate im Taxon Poecilia (Teleostei)
(2020)
Diese Dissertation befasst sich mit den Auswirkungen kontrastierender Umweltbedingungen auf die Gehirnmorphologie von neotropischen Fischen der Gattung Poecilia, welche unterschiedlichen abiotischen sowie biotischen Stressoren ausgesetzt sind. Da das Gehirn der Teleostei ein energetisch kostspieliges Organ und viel plastischer ist als z. B. bei Säugetieren, stellt sich die Frage, wie die Gehirnanatomie durch divergierende ökologische Faktoren in verschiedenen Umgebungen geformt wird, die ´extreme´, ´ressourcenbeschränkte und günstige´ Umgebungen repräsentieren. Zur Beantwortung dieser Frage wurden intraspezifische Studien an freilebenden und Laborindividuen von Poecilia-Arten durchgeführt, um die evolutionäre und ökologische Formgebung des Gehirns besser verstehen zu lernen. Im ersten Teil der Arbeit wurden Gehirnvolumina verglichen zwischen reproduktiv isolierten Populationen des neotropischen Fisches Poecilia mexicana (Ntotal = 95), die in Dunkelheit leben (Cueva Luna Azufre), in einem nahegelegenen Oberflächenhabitat (El Azufre), welcher giftigen Schwefelwasserstoff enthält und einer Kombination aus beiden Stressoren Dunkelheit und H2S (Cueva del Azufre). In einer zweiten Studie wurde auf anatomische („konvergente“) Veränderungen im Teleost-Gehirn entlang eines natürlichen Gradienten von Sulfidkonzentrationen getestet. Hierfür wurden Gehirne (Ntotal = 100) von P. mexicana verglichen, die in drei Flusssystemen im Süden Mexikos unabhängig voneinander eine erhöhte Toleranz gegenüber Schwefelwasserstoff (H2S) entwickelt haben. Dazu gehörten eine phylogenetisch alte H2S-adaptierte Form (P. sulphuraria) und zwei P. mexicana Formen, welche frühere Stufen der Anpassung an H2S darstellen. Zur Überprüfung des Einflusses anderer abiotischer und biotischer Faktoren auf die Morphologie der Gehirnregionen wurde eine weitere Studie durchgeführt. Hierbei wurden die phänotypischen Variationen der Gehirnregionen und der Körpermorphologie von Poecilia vivipara-Populationen (Ntotal = 211) aus Lagunen des Restinga de Jurubatiba Nationalpark untersucht, die sich in abiotischen Umgebungsbedingungen, insbesondere in Salzgehalt, Wassertransparenz, Phosphat und Nitrat sowie biotischen Faktoren wie Prädatorendichte unterschieden. Die erste Studie zeigte lebensraumabhängige Unterschiede bei freilebenden Fischen. Bei Fischen, die in Dunkelheit ohne H2S (LA) oder in Oberflächenhabitaten mit H2S lebten, wurden vergrößerte telenzephale Lappen, kleinere Augen und optische Tekta gefunden. Fische aus der sulfidischen Höhle (CA) zeigten zusätzlich vergrößerte Corpus cerebelli. Der Vergleich mit den Gehirnen von Labor aufgezogenen weiblichen Fischen (Ntotal = 25) zeigt eine allgemeine Verringerung der Gehirngröße sowie eine geringe Abweichung der Gehirngröße zwischen Labor aufgezogenen und freilebenden Fischen. Auch in der zweiten Studie zeigten alle in H2S-haltigen Lebensräumen lebenden Fische kleinere Augen, ein kleineres optisches Tektum und ein kleineres Gehirnvolumen, jedoch größere Corpus cerebelli und Hypothalamusvolumen als Fische aus nicht-sulfidischen Lebensräumen. Flusssystem-spezifische Effekte wurden für die telenzephalen Lappen, das gesamte Gehirn und die Augengröße festgestellt, da die Geschlechter je nach Quelle des Flusssystems unterschiedlich auf das Vorhandensein von H2S reagierten. Die dritte Studie zeigt auch, dass andere Umwelteinflüsse bemerkenswerte Verschiebungen im Gehirn und in den Gehirnregionen verursachen können. Fische, die im Süßwasser leben, zeigten eine verringerte Gesamthirngröße, telenzephale Lappen, Corpus cerebelli und Hypothalamusvolumen. Darüber hinaus zeigten Fische aus Salzwasserlagunen (hypersalin), ein verringertes Volumen des optischen Tektum, während telenzephale Lappen, Corpus cerebelli und Hypothalamusvolumen im Vergleich zu Süßwasserfischen vergrößert waren. Im Brackwasser lebende Fische wiesen im Vergleich zu Süß- und Salzwasserfischen die größten Gehirnregion-Volumen auf. Darüber hinaus zeigten die Ergebnisse über die Lagunen hinweg auch Unterschiede in der Morphologie der Kopf- und Augendurchmesser. Bei Augengröße, Kopfgröße, optischem Tektum Volumen, Hypothalamusvolumen und dem Gesamthirnvolumen wurde ein sexueller Dimorphismus beobachtet. Die dargestellten Ergebnisse verdeutlichen, dass die gefundenen Muster nahezu mit denen von H2S-Fischen identisch sind. Die ausgeprägten Unterschiede in den Hirnregionen zwischen freilebenden Fischen können als Teil der Mosaikentwicklung interpretiert werden. Die Ergebnisse der Laborpopulation zeigen jedoch eine hohe phänotypische Plastizität. Diese Studie unterstreicht damit die Bedeutung der Kombination der Untersuchung von freilebenden mit im Labor lebenden Individuen zur Beantwortung von Fragen der Gehirnentwicklung. Kleinere Augen und ein kleineres optisches Tektum, aber größere telenzephale Lappen wurden auch bei Fischen aus einem sulfidischen Oberflächenhabitat in der Nähe einer der Höhlen gefunden und sind den Ergebnissen zufolge das Resultat begrenzter Sehkraft in trüben sulfidischen Lebensräumen.
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A novel role for mutant mRNA degradation in triggering transcriptional adaptation to mutations
(2020)
Robustness to mutations promotes organisms’ well-being and fitness. The increasing number of mutants in various model organisms, and humans, showing no obvious phenotype (Bouche and Bouchez, 2001; Chen et al., 2016b; Giaever et al., 2002; Kok et al., 2015) has renewed interest into how organisms adapt to gene loss. In the presence of deleterious mutations, genetic compensation by transcriptional upregulation of related gene(s) (also known as transcriptional adaptation) has been reported in numerous systems (El-Brolosy and Stainier, 2017; Rossi et al., 2015; Tondeleir et al., 2012); however, the molecular mechanisms underlying this response remained unclear. To investigate this phenomenon, I develop and study multiple models of transcriptional adaptation in zebrafish and mouse cell lines. I first show that transcriptional adaptation is not caused by loss of protein function, indicating that the trigger lies upstream, and find that the response involves enhanced transcription of the related gene(s). Furthermore, I observe a correlation between levels of mutant mRNA degradation and upregulation of related genes. To investigate the role of mutant mRNA degradation in triggering the response, I generate mutant alleles that do not transcribe the mutated gene and find that they fail to induce a transcriptional response and display stronger phenotypes. Transcriptome analysis of alleles displaying mutant mRNA degradation revealed upregulation of a significant proportion of genes displaying sequence similarity with the mutated gene’s mRNA, suggesting a model whereby mRNA degradation intermediates induce transcriptional adaptation via sequence similarity. Further mechanistic analyses suggested RNA-decay factors-dependent chromatin remodeling, and repression of antisense RNAs to be implicated in the response. These results identify a novel role for mutant mRNA degradation in buffering against mutations. Besides, they hold huge implications on understanding disease-causing mutations and shall help in designing mutations that lead to minimal transcriptional adaptation-induced compensation, facilitating studying gene function in model organisms.
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...
As fossil resources are diminishing, environmental concerns arise and chemical synthesis often involves expensive catalysts or extensive extraction procedures, the demand for production of industrially relevant compounds from renewable resources increases. In this context, engineering microorganisms for production of specialty chemicals, such as 3-alkylphenols, presents an attractive, environmental-friendly approach. 3-alkylphenols have various applications: due to their antiseptic and stabilizing properties many 3-alkylphenols, including 3-methylphenol (3-MP), are utilized as additives in disinfectant reagents and biological products, while they can be also implemented as platform chemicals for production of lubricating oil additives or flavors. Some 3-akylphenols have potential for transmission control of the disease sleeping sickness that is transmitted by tsetse flies in sub-saharan Africa, since 3-ethylphenol (3-EP) and 3-propylphenol (3-PP) and to a lesser degree 3-MP were found to attract tsetse flies and improved catch rates in impregnated tsetse fly traps. Microbial fermentation of 3-alkylphenols would provide a simple and inexpensive way for local communities in Africa to produce these compounds and prepare their own tsetse fly traps.
Some molds synthesize 3-MP as an intermediate during biosynthesis of the mycotoxin patulin. However, the heterologous host Saccharomyces cerevisiae has advantageous traits for industrial application, since it is well characterized, robust, simple to handle and easily genetically accessible. In this thesis, genetical engineering approaches were utilized to establish the yeast S. cerevisiae for biotechnological production of 3-alkylphenols. As a proof of concept, the iterative polyketide synthase from Penicillium patulum, 6-methylsalicylic acid synthase (MSAS), and 6-methylsalicylic acid (6-MSA) decarboxylase PatG from Aspergillus clavatus were heterologously expressed in S. cerevisiae resulting in the first reported de novo biosynthesis of 3-MP via 6-MSA in yeast from sugars (Hitschler & Boles, 2019). It was shown that codon-optimization and genomic integration of heterologous genes, high initial cell densities and a balanced expression of PatG were beneficial for heterologous production of up to 589 mg/L 3-MP in S. cerevisiae. However, toxicity of 3-MP limited higher product accumulation.
Different in vivo detoxification strategies were implemented to face this bottleneck. Growth tests revealed that 3-methylanisole (3-MA) is less toxic to the yeast cells than 3-MP. Expression of an orcinol-O-methyltransferase from chinese rose hybrids (OOMT2) was combined with in situ extraction converting the toxic 3-MP product into the volatile 3-MA and accumulating up to 211 mg/L 3-MA in the dodecane phase. Alternatively, up to 533 mg/L 3-MP glucoside were synthesized by expression of a UDP-glycosyltransferase (UGT72B27) from Vitis vinifera in the 3-MP producing strain, revealing saccharose as beneficial carbon source and ethanol growth phase as essential for high 3-MP production, although 3-MP conversions were not yet complete. Both detoxification strategies allowed circumvention of the toxicity imposed limited product accumulation. This was demonstrated when both detoxification strategies were combined with redirection of the carbon flux through deletion of phosphoglucose isomerase gene PGI1 and feeding a mixture of fructose and glucose leading to majorly improved product formation, with up to 899 mg/L 3-MA/3-MP and 873 mg/L 3-MP/3-MP glucoside, compared to less than 313 mg/L product titers in the wild type controls (Hitschler & Boles, 2020).
For provision of the tsetse fly attractants 3-EP from propionyl-CoA and 3-PP from butyryl-CoA, the substrate promiscuities of MSAS and PatG were exploited. However, slower formation rates with the alternative substrates propionyl-CoA and butyryl-CoA suggested that competing formation of 6-MSA from the preferred priming unit acetyl-CoA was dominating in vivo. Indeed, 3-EP or 3-PP formation was not observed in 3-MP producing yeast strains. Assuming that intracellular levels of propionyl-CoA and butyryl-CoA were limiting 3-EP and 3-PP formation, different strategies were implemented to raise the supply of these alternative priming units and successfully compete with acetyl-CoA for MSAS priming.
Supplementation of propionate increased propionyl-CoA levels by endogenous pathways sufficiently to enable 3-EP formation in yeast mediated by MSAS and PatG. Deletion of the 2-methylcitrate synthases CIT2 and CIT3 revealed that degradation of propionyl-CoA was not limiting 3-EP formation at this stage. In order to raise propionyl-CoA levels further, a heterologous propionyl-CoA synthase (PrpE) was expressed in the 3-MP producing yeast strain leading to up to 12.5 mg/L 3-EP with propionate feeding and blockage of degradation. Moreover, PrpE enabled also 3-EP formation without propionate supplementation suggesting that an endogenous supply of propionate existed that was reactivated by PrpE. As threonine or 2-ketobutyrate feeding increased 3-EP titers in combination with PrpE, this indicated that threonine degradation via 2-ketobutyrate was responsible for the endogenous propionate supply. Moreover, expression of branched-chain ketoacid dehydrogenase complex from Pseudomonas putida combined with PrpE provided propionyl-CoA from endogenous 2-ketobutyrate and raised 3-EP titers up to 5.9 mg/L compared to 2.8 mg/L with only PrpE indicating a potential route for optimization of 3-EP titers independent of propionate or threonine feeding.
For 3-PP production from butyryl-CoA, a heterologous ‘reverse ß-oxidation’ pathway was introduced in the 3-MP producing yeast strain providing sufficient butyryl-CoA for biosynthesis of up to 2 mg/L 3-PP. Degradation of the precursor via ß-oxidation was slightly limiting, since deletion of fatty acyl-CoA oxidase POX1 increased 3-PP titers slightly to 2.6 mg/L.
As the concentrations of 3-alkylphenols are close to the concentrations implemented in tsetse fly traps, the engineered yeast strains have the potential for simple and inexpensive on-site production of 3-alkylphenols as tsetse fly attractants by local rural communities in Africa. In spite of this success, 3-MP remained the main product in the developed yeast strains. Since 3-EP and 3-PP are more efficient tsetse fly attractants, a shift in substrate specificities of MSAS and PatG is desirable for a more favorable 3-EP/3-MP and 3-PP/3-MP product ratio regarding tsetse fly attraction. During rational engineering of MSAS, the MSASQ625A/I752V mutant showed a beneficial shift of product ratios with up to 11 mg/L 3-EP/63 mg/L 3-MP and 4.5 mg/L 3-PP/116 mg/L 3-MP, compared to a higher proportion of 3-MP with up to 343 mg/L, 11 mg/L 3-EP and 1.5 mg/L 3-PP in the wild type controls. Further engineering of MSAS and PatG might majorly improve production of 3-EP and 3-PP.
In summary, this thesis successfully established the yeast S. cerevisiae as cell factory for production of different 3-alkylphenols optimizing expression of the heterologous production pathway, elucidating means to detoxify products and establishing different approaches to increase intracellular levels of acyl-CoA precursors. The engineered yeast strains can be potentially implemented for simple and inexpensive fermentation of tsetse fly attractants in Africa.
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.
Downy mildew of common sage (Salvia officinalis), caused by Peronospora salviae-officinalis, has become a serious problem in sage production worldwide. The causal agent of the disease belongs to the Pe. belbahrii species complex and was described as a species of its own in 2009. Nevertheless, very little is known about its infection biology and epidemiology. The aims of the current study were therefore to unravel the life cycle of this downy mildew and gain deeper insights into the epidemiology of the disease, as well as to clarify the species boundaries in the Pe. belbahrii species complex.
Infection studies showed that temperatures between 15 and 20 °C were most favourable for infection and disease progress. At 5 °C Pe. salviae-officinalis is still able to infect sage plants, but sporulation was only observed at higher temperatures. Furthermore, Pe. salviae-officinalis needs two events of leaf wetness or high humidity, a first one of at least three hours for conidial germination and penetration of the host, and a second one for sporulation. Additionally, contamination of sage seeds by Pe. salviae-officinalis was proven by seed washing and by PCR and DNA sequence comparisons, suggesting that infested seeds might play a major role in the fast spread of sage downy mildew, which is an important finding for phytosanitary or quarantine measures.
A protocol for fluorescence staining and confocal laser scanning microscopy was established and the whole life cycle of Pe. salviae-officinalis was tracked including oospore formation. The method was also used to examine samples of Pe. lamii on Lamium purpureum and Pe. belbahrii on Ocimum basilicum demonstrating the usefulness of this method for studying the infection process of downy mildews in general.
Peronospora species parasitizing S. sclarea, S. pratensis, O. basilicum, and Plectranthus scutellarioides were studied using light microscopy and molecular phylogenetic analyses based on six loci (ITS rDNA, cox1, cox2, ef1a, hsp90 and β-tubulin). The downy mildew on S. pratensis was shown to be distinct from Pe. salviae-officinalis and closely related to Pe. glechomae, and is herein described as a new taxon, Peronospora salviae-pratensis. The downy mildew on S. sclarea was found to be caused by Peronospora salviae-officinalis. The multi-gene phylogeny revealed that the causal agent of downy mildew on coleus is distinct from Pe. belbahrii on basil, and is herein described as a new taxon, Pe. choii.
Connectomic analysis of apical dendrite innervation in pyramidal neurons of mouse cerebral cortex
(2020)
The central goal of this study was to generate synapse-resolution maps of local and long-range innervation on apical dendrites (AD) in mouse cerebral cortex. We used three-dimensional electron microscopy (3D-EM) to first measure the cell-type specific balance in the excitatory and inhibitory input on ADs. Further, we found two inhibitory axon populations with preference for apical dendrites originating from layer 2 and 3/5. Additionally, we used a combination of large-scale volumetric light and electron microscopy to investigate the innervation preference of long-range cortical projections onto ADs. To generate such large-scale 3D-EM datasets, we also developed a software package to automate aberration adjustment.
The balance of excitation and inhibition defines the computational properties of neurons. We, therefore, generated 6 datasets and annotated 26,548 excitatory and inhibitory synapses to map the relative inhibitory strength on the AD of pyramidal neurons in layers 1 and 2 (L1 and 2) of the cortex. We found consistent and cell-type specific patterns of inhibitory strength along the apical dendrite of L2-5 pyramidal neurons in primary somatosensory (S1), secondary visual (V2), posterior parietal (PPC) and anterior cingulate (ACC) cortices. L2 and L5 pyramidal neurons had inhibitory hot-zones at their main bifurcation and distal apical dendrite tuft, respectively. In contrast, L3 neurons had a baseline (~10%) level of inhibition along their apical dendrite. As controls, we quantified the effect of synapse strength (size), dendrite diameter, AD classification and synapse identification methods on the cell-type specific synapse densities. To classify L5 pyramidal subtypes, we performed hierarchical clustering using morphological properties that were described to differentiate slender- and thick-tufted L5 neurons.
We also investigated the distance to soma as a predictor of fractional inhibition around the main bifurcation of apical dendrites. Interestingly, we found a strong exponential relationship that was absent in density of either synapse type. This suggests a distance dependent control mechanism designed specifically for the balance (in synapse numbers) of excitation and inhibition.
Next, we focused on the inhibitory innervation preference for apical dendrite of pyramidal neuron. We, therefore, annotated 5,448 output synapses of AD-targeting inhibitory axons and found two populations specific for either L2 or L3/5 apical dendrites. Together with previous findings on preferential innervation of sub-cellular structures by inhibitory axons, this suggests two distinct inhibitory circuits for control of AD activity in L2 vs. deep-layer pyramidal neurons. This innervation preference was surprisingly consistent across S1, V2, PPC and ACC cortices.
3D-EM data acquisition is a laborious process that is made easier and more popular everyday by technical progress in the laboratory and industrial settings. To make data acquisition robust using our custom-built 3D-EM microscopes, an automatic aberration software was implemented to adjust the objective lens and the stigmators of the electron microscope. This method was used in multiple month-long experiments across 2 microscopes and 10 datasets. The aberration adjustment used the reduction in image details (high-frequency elements) to estimate the level of deviation from optimal focus and stigmator parameters. However, large objects in EM micrographs such as blood vessel and nuclei cross-sections generated anomalous results. We, therefore, added image processing routines based on edge detection combined with morphological operations to exclude such large objects.
Finally, we performed a correlative three-dimensional (3D) light (LM) and electron (EM) microscopy experiment to map the long-range primary visual (V1) and secondary motor (M2) cortical input to ADs in layer 1 of PPC using the “FluoEM” approach. This method allows for identification of the long-range source of projection axons in EM volumes without the need for EM-dense label conversion or heat-induced markings. The long-range source of an axon in EM is identified based on the fluorescent protein that is expressed in its LM counterpart. In comparison to M2 input, Long-range axons from V1 had a higher tendency to target L3 pyramidal neurons in PPC according to our preliminary analysis. In combination with the difference observed in the synapse composition of L2 and L3 apical dendrites, this suggests the need for separate functional and structural analysis of L2 and 3 pyramidal neurons.
Droughts impair plant growth, limit global net primary production and are predicted to increase in the course of climate change. Knowledge of the plant drought response on a molecular level can facilitate the selection of drought resistant genotypes and genetic engineering and thereby can help to implement strategies, such as assisted migration projects or crop improvement, in order to preserve natural and agricultural vegetation against droughts.
Studies on gene expression under drought stress were conducted in three species each of the genera Quercus and Panicum, to shed light on the molecular drought response in these species and identify drought responsive genes as a basis for technical applications.
In the genus Quercus, gene expression studies were conducted in the three major European forest trees Q. ilex, Q. pubescens and Q. robur, for which a distributional shift caused by climate change is predicted for the 21st century. RNA-Seq experiments were conducted in the three Quercus species for the first time, ortholog groups were assigned and unregulated genes, as well as drought responsive genes, were identified (Madritsch et al. 2019). For a set of the unregulated genes, a stable expression over the course of long-term drought periods was evaluated in order to enable an application as reference genes for normalizing qRT-PCR experiments (Kotrade 2019a). The reference genes were used in subsequent experiments to generate gene expression profiles over the course of a two-year drought experiment with consecutive drought periods for a set of twelve drought responsive genes and revealed a highly variable gene regulation under long-term drought stress in the Quercus species (Kotrade et al. 2019b).
In the genus Panicum, the gene expression in response to drought was examined in the two wild crop species, P. laetum and P. turgidum, and in the less drought tolerant species P. bisulcatum via RNA-Seq experiments (Kotrade et al. 2020 (in revision). The transcriptomes of the species were sequenced for the first time, ortholog groups were assigned and the gene regulation was compared across the species. The common grounds of the drought response in Panicum were determined by identifying similarities across the species, while the identification of differences between the species led to genes that might contribute to the higher drought tolerance of P. laetum and P. turgidum
A comparison across the two genera showed large differences in the gene regulation upon drought. This might be largely explained by different experimental setups that resulted in different drought conditions in the genera, such as drought intensity, drought duration and velocity of drought development.
The sequence information and the drought responsive genes identified in the Quercus and Panicum species can be used to develop marker assays for marker-assisted selection. The genes that putatively contribute to the higher drought tolerance of the two wild crop Panicum species should be considered as candidate targets in genetic engineering studies. Marker-assisted selection and genetic engineering can be applied, for example, in assisted migration projects to support natural vegetation in the course of climate change or to breed more drought tolerant crop strains to mitigate crop failure rates caused by droughts.
This manuscript-based thesis is divided into four chapters. Chapter one is an introduction to lichens and the Antarctic. It introduces the goal of the thesis and the problems related with lichen systematics and the lack of knowledge about Antarctic lichens. The Antarctic is one of the last wildernesses, isolated from the other continents by the Antarctic Circumpolar Current, the Subantarctic Front, the Antarctic Polar Front, and the Drake Passage. Terrestrial life in Antarctica is restricted to widely separated and small ice-free areas that cover only 0.3% of the continent. Colonization of the Antarctic is a challenge for many taxa and is related to their ability for long-range dispersal and their adaptation to the harsh climate. Antarctic terrestrial ecosystems are significantly threatened by climate change, invasive species, and their interactions. Glacial retreat caused by higher than average temperatures exposes new habitats that can be easily colonized from local biota, but non-native species can also be favored by the new climatic conditions. In addition, propagule movement mediated by humans can introduce new species or change the population structure of many taxa. The terrestrial biota is comprised almost exclusively by “lower organisms” (invertebrates, bryophytes, algae, lichenized fungi, and microorganisms). Lichens are the dominant component, and the most important primary producers. Lichens are symbiotic associations consisting of a fungus (mycobiont) and one or more photosynthetic (photobiont) partners. They can disperse sexually or vegetatively. There are several problems related to the symbiotic nature of lichens that do not facilitate easy identification; although molecular data offers additional evidence, species delimitation in lichens is still not straightforward. The true number of species is underestimated due to the presence of cryptic species and species pairs. Recommended universal fungal barcode sequences (e. g. ITS) sometimes fail to delimit species pairs. Thus, it is necessary to identify fast-evolving markers that allow for the delimitation of closely related species before proceeding with the analysis of lichen populations. The goal of this thesis is to elucidate the so far unknown genetic structure among Antarctic lichen populations because of the immediate consequences for conservation strategies. The thesis focuses not only on patterns of differentiation and gene flow, but also investigates the question of human-mediated propagule transfer into Antarctica and among Antarctic sites. This project provides data on the genetic structure of Antarctic lichens that is urgently needed to develop conservation strategies in the face of global warming and increased human activities in the region. Due to the fact that it is not possible to apply all of the unspecific fingerprinting methods to lichens, microsatellites or simple sequence repeats (SSRs) are one of the best tools to investigate the genetic structure of lichen populations. SSRs offer the possibility to discriminate the lichen partners, but species-specific microsatellites have been developed for only a few species. Regarding the Antarctic, only one species has been studied with SSRs.
The second chapter describes new methods and tools to delimit closely related species of lichens and provides fast evolving markers to characterize their genetic structure. The chapter introduces the lichen species analysed in this thesis and the problems related to their correct identification by morphological methods and molecular data. Chapter two explains the sampling methods for lichen populations and the localities from small areas in which the species pairs occur together. Then the methods used to generate and validate fungal specific microsatellites that cross-amplify species pairs are described. This chapter focuses on the species pair Usnea antarctica and U. aurantiacoatra because they are the most common lichens in the Maritime Antarctic. An internal transcribed spacer (ITS) marker do not discriminate between these species, and some authors have suggested to synonymize them. Unpublished results from another Antarctic species pair, Placopsis antarctica and P. contortuplicata, are included to confirm the capability of SSRs to discriminate closely related lichen species. This thesis is the first study to generate SSRs that cross amplify species pairs, using BLAST to compare one genome against the other to obtain markers with the same length in flanking regions. The de novo developed SSRs are able to discriminate the two closely related species, and can detect variability at the population level. In the end of the chapter, ITS sequences, microsatellites, and SNPs are used to delimit the species of Usnea antarctica and U. aurantiacoatra. The chapter exposes the importance of a correct species delimitation and the ability of SSRs and SNPs to delimit the Antarctic Usnea species pair compared with the recommended universal fungal barcode sequence ITS. ...