Biologische Hochschulschriften (Goethe-Universität)
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Bees of the family Halictidae Thomson, 1869 from Dominica, Lesser Antilles (Hymenoptera: Apoidea)
(2016)
The bees of the family Halictidae Thomson, 1869 from Dominica are reviewed. Seven new species are described and illustrated: Lasioglossum (Dialictus) kalinago sp. nov., L. (D.) dominicense sp. nov., L. (D.) kilpatrickae sp. nov., L. (Habralictellus) roseauense sp. nov., Sphecodes diablotinus sp. nov., S. albifacies sp. nov. and Habralictus antillarus sp. nov. A description and images of the previously unknown female of Microsphecodes dominicanus (Stage, 1972) are provided. In total, eleven species are recognized: eight nest-building species and three kleptoparasites. All halictid species from Dominica are currently known only from the island. A key to halictid bees from Dominica is provided.
This thesis primarily covers a systematic assessment of quantum chemical methods to predict accurate 19F NMR shifts for fluoroarenes and magnetic exchange coupling constant (J) in organic spin dimers which are basic building blocks for rational designing of organic magnetic materials.
One of the most important goals in chemistry is to design and synthesize molecules with optimum properties. This thesis is divided into two parts: the first part comprises of a systematic effort to find an inexpensive quantum chemical method to predict accurate 19F NMR chemical shifts (within an accuracy of 2 ppm) for perfluoraromatics. Essentially, these strenuous efforts have been devoted to find best DFT functional and basis set combination to predict accurate 19F shifts. In addition,the influence of geometrical parameters, solvents, chemical environment was also analyzed. Various correction approaches were tested to correct the calculated shifts. The influence of various functionals and basis sets was also analyzed on the correction efficiency of an individual scheme. All the NMR calculation methods already being used and correction approaches were verified to predict shifts of three different fluorine-substituted molecular sets. These structure sets include fluorobenzenes, substituted benzenes and fluorine substituted aromatic fused rings (e.g. fluorine substituted anthracene).
In the second part of this thesis, we investigated the accurate prediction of magnetic exchange couplings (J) for organic spin dimers using quantum chemical methods. We analyzed the performance of various DFT methods and various post-HF methods, such as the CASSCF, CASPT2, MSTDISD, DDCI1, DDCI2, DDCI3, and FCI to predict magnetic exchange couplings (J).
Overview of the Chapters:
Chapter 1, presents a brief theoretical introduction to the Schrödinger equation and its application in quantum mechanical calculations, the Hartree-Fock approximation, basis sets, electron correlation energy, and density functional theory (using pure and hybrid functionals).
In chapters 2 and 3, an introduction is given for quantum chemical approaches used to calculate NMR parameters and magnetic exchange coupling constants. We discuss an effective spin Hamiltonian, the Breit-Pauli Hamiltonian (BPH), chemical shielding tensor and total energy relationship, measuring of the NMR spectra, and different techniques to deal with gauge origin problem. In addition, the theoretical background of magnetic exchange coupling constant calculation for spin dimers, the Heisenberg-Dirac-van-Vleck Hamiltonian (HDVV) and the Noodelman's broken-symmetry approach for calculating J values are briefly discussed.
Chapter 4, presents a benchmark study of various DFT functionals and basis sets to calculate accurate C-F bond lengths and 19F chemical shifts. High-resolution NMR spectral data of complex molecules are often difficult to interpret. Great scientific efforts have been devoted to search for a computational approach to interpret experimental NMR data. Quantum chemical methods such as the CCSD(T) method offer high accuracy in calculation of NMR parameters but being computationally too demanding they cannot be applied to large chemical systems. On the other hand, density functional theory (DFT) is achieving a steady progress among diversity of computational techniques. An accuracy within 2 ppm deviation from the experimental values in 19F chemical shifts can be achieved if the NMR calculation is performed using accurate equilibrium geometries, GIAO is used to tackle gauge origin problem and electron correlation is properly treated by employing a high level of theory (e.g. CCSD (T)/cc-pVQZ). We found that the calculation of 19F shielding tensors with the density-functional theory does not provide any noticeable improvement over the HF method. Post-HF theory demands too much computational resources that makes them impossible to use for large systems [35] .
We found that a quantitative prediction of NMR shifts can be made as the errors introduced by theoretical methods are cancelled out while calculating shifts. Various benchmark studies in this thesis show that 19F chemical shifts calculated for perfluoraromatics with the M06-L, BHandH, BHandHLYP in combination with the 6-311+G (2d,p) basis set are within 4 ppm deviation from the experiments. Furthermore, we noted that NMR calculations on accurate
C-F (e.g. PBE/6-311G (d, p)) bond lengths does not show any improvement if the NMR calculation and optimization are performed at the same level of theory. A significant improvement can be achieved on calculated 19F NMR shifts, if some correction schemes are used.
In chapter 4 we discuss various correction schemes applied to correct the calculated 19F chemical shifts. A multi-standard approach (MSTD) was used to minimize the error that may occur due to the difference in the nature of the reference compound and test molecules [122]. We propose another approach to correct shielding constants which is the reference corrected approach. This approach makes a correction similar to the MSTD. We also tested a Linear Regression Correction Approach and we noted that this is the best approach amongst all. This is found to be less dependent on the theoretical method. We use conformation averaging corrections to correct the calculated shifts[126].
...
This thesis reports on the results obtained by expression photoactivatable adenylyl cyclase from Beggiatoa spp. (bPAC) in cholinergic neurons from Caenorhabditis elegans (C. elegans) and the characterization of the role of a single neuron, RIS, during locomotion in the adult animal.
Pharmacological activation of adenylyl cyclases through Forskolin is known to induce increased neuronal output in diverse model organisms through a protein kinase A (PKA) dependent mechanism. Nevertheless, pharmacological assays are not spatially restricted, do not allow for precise and acute activation nor to cessation of the signal. Thus, an optogenetic approach for was selected trough the expression of photoactivatable adenylyl cyclase from Beggiatoa spp. (bPAC) in cholinergic neurons of Caenorhabditis elegans (C. elegans). This model organism was chosen due to its transparency, ease of maintenance, fast generation cycles as well as for being an eutelic animal. Further, its genome has been fully sequenced and the connectome of the neuronal network is known, thus allowing for precise analysis of neuronal function. Furthermore, the molecular mechanisms governing neuronal functions are well conserved up to primates. Mainly two optogenetical tools were applied, bPAC and the light gated cation channel channelrhodopsin 2 (ChR2).
Behavioral assays of bPAC photostimulation in cholinergic neurons recapitulated previous work performed with the photoactivatable adenylyl cyclase from Euglena gracilis (EuPACa), in which swimming frequency and speed on solid substrate were increased. Electrophysiological recordings of body wall muscle (BWM) cells by Dr. Jana F. Liewald showed that bPAC photoactivation led to an increase in miniature postsynaptic current (mPSC) rate and, in contrast to ChR2 invoked depolarization, also amplitude. Analysis of mutants deficient in neuropeptidergic signaling (UNC- 31) via electrophysiology performed by Dr. Jana F. Liewald showed that the increase in mPSC amplitude due to bPAC photoactivation requires neuropeptide release. This was confirmed by co-expression of bPAC with the neuropeptide marker NLP-21::Venus and subsequent fluorescence analysis of release, exploiting the fact that released neuropeptides are ultimately degraded by scavenger cells (coelomocytes). These were enriched with NLP-21::Venus after bPAC photostimulation, but no fluorescence could be observed in the UNC-31 mutants.
Additional analysis of the electrophysiological data performed by myself showed no modulation of mPSC kinetics dues to neuropeptidergic release induced by bPAC. Hence, neuropeptide release and action sites were in the cholinergic neurons, the latter including cholinergic motoneurons.
Dr. Szi-chieh Yu provided electron microscopy images of high pressure frozen, bPAC or ChR2 expressing animals. These were tagged by myself for automatic analysis of ultrastructural properties of the cholinergic presynapse, also during photoactivation of both optogenetic tools. Photoactivation of both induced a reduction of synaptic vesicles, with ChR2 showing a more severe effect. In contrast to ChR2, though, bPAC also reduced the amount of dense core vesicles (DCV), the neuropeptide transporters. Additionally, long bPAC photoactivation as well as ChR2 photoactivation led to the appearance of large vesicles (LV), presumably in response to the increased SV fusion rate. bPAC photostimulation also induced an increase in SV size, not observed after ChR2 photostimulation. In UNC-31 mutants, bPAC photostimulation could not lead to the SV size increase, a further argument for the presynaptic effect of the released neuropeptide. Additional analysis of electrophysiology paired with pharmacology, performed by Dr. Jana F. Liewald, showed that mPSC amplitude increase requires the function of the vesicular acetylcholine transporter.
A further effect observed in the ultrastructure of bPAC photostimulated cholinergic presynapses was a shift in the distribution of SV regarding the dense projection. An analysis of cAMP pathway mutants showed that synapsin is required for bPAC induced behavior effects. Synapsin is known to mediate SV tethering to the cytoskeleton. Here, I show evidence for a new role of synapsin in controlling the availability of DCVs for fusion and thus, in neuropeptidergic signaling.
In the second part of my thesis I characterized the function of the GABAergic interneuron RIS in the neuronal network of C. elegans. RIS was shown to induce lethargus, a sleep-like state, during all larval molts, but its function in the adult animal was not yet described. Specific RIS expression of ChR2 achieved by a recombinase based system allowed to acutely depolarize the neuron during locomotion, which led to an acute behavioral stop. Diverse signal transduction pathway mutants were analyzed showing that the phenotype was induced by neuropeptidergic signaling. Through mutagenesis followed by whole genome sequencing data analysis as well as analysis of RIS specific RNA sequencing data further narrowed the signal transduction pathway to mediate the locomotion stop behavior. Since the neuropeptide and, to some extent, the neuron are conserved across nematodes, an argument is outlined in favor of the conservation of this sleep-like state.
In addition, since ChR2 could induce neuropeptidergic signaling from RIS, secretion of vesicles is regulated by variable pathways depending on the neuronal identity. Nevertheless, expression of bPAC in RIS allowed to optogenetically increase the probability of short stops, as observed by expression of a calcium sensor (GCaMP) in RIS and analysis of its intrinsic activity in the adult animal.
Die mitochondriale Innenmembran (IM) besteht aus zwei Subkompartimenten. Der Cristae Membran (CM) und der inneren Grenzmembran (IBM), welche durch die runden und schlitzartige Strukturen der Christa Junctions (CJs) verbunden werden Der MICOS-Komplex ist an den CJs lokalisiert und besteht aus mindestens 6 Komponenten, Mic60, Mic27, Mic26, Mic19, Mic12 und Mic10. Es ist bekannt, dass der MICOS-Komplex essentiell für die Stabilität der CJs ist. Die in dieser Arbeit gezeigten Ergebnisse, geben Aufschluss darüber, wie sich einzelne MICOS-Komponenten auf die Stabilität von Cristae und CJs im Modellsystem Hefe (S cerevisiae) auswirken. Zu Beginn dieser Arbeit war zum einen bekannt, dass die MICOS-Komponente Mic60 essentiell für die Bildung von CJs ist. Zum Anderen wurden im Vorfeld dieser Arbeit Interaktionen von Mic60 mit Proteinen in der mitochondrialen Außenmembran, vor allem Proteinkomplexe mit β-barrel-Proteinen identifiziert. Diese Interaktionen werden über den evolutionär, konservierten C-Terminus von Mic60 vermittelt.
β-barrel Proteine besitzen eine charakteristische Peptidsequenz, die β-Sequenz. Diese dient nach dem Import der β-barrel Proteine in die Mitochondrien als Signalpeptid für den SAM-/TOB-Komplex, welcher daraufhin die Proteine in die Außenmembran insertiert. In dieser Arbeit wurde ebenfalls eine β-Sequenz im C-Terminus von Mic60 identifiziert, diese zeigte einen Einfluss auf die Cristae-Stabilität. Zellen die eine Mic60-Variante mit einer Deletion oder Punktmutation der β- Domäne exprimieren, zeigten eine reduzierte Anzahl an CJs. Auch das Verkürzen des C-Terminus von Mic60 hatte diesen Effekt auf die mitochondriale Ultrastruktur. So konnte gezeigt werden, dass die β-Domäne und die Integrität des C-Terminus essentiell für die Stabilität von CJs sind.
Der Fokus dieser Arbeit lag in der Charakterisierung der MICOS-Komponenten Mic26 und Mic27. Es konnte bewiesen werden, dass beide Proteine genetisch mit der MICOS-Kernkomponente Mic60 interagieren. Die Untersuchung der mitochondrialen Ultrastruktur von Δmic26- und Δmic27-Zellen zeigte, dass eine Deletion vom Mic26 keinen Einfluss auf die Organisation der mitochondrialen Innenmembran hat. Im Gegensatz dazu, ist im Vergleich zum Wildtyp die Anzahl an CJs in Δmic27-Zellen um zwei Drittel reduziert. Auch die Innenmembranoberfläche ist in diesen Zellen stark vergrößert. Die Untersuchung der Morphologie der mitochondrialen Innenmembran in Zellen ohne Mic27 durch Kryo-Elektronentomographie isolierter Mitochondrien, veranschaulichte die Struktur der CJs in diesen Zellen genauer. Es zeigten sich hier breitere CJs, und der Übergang von der Cristaemembran in den Bereich der inneren Grenzmembran ist sehr flach und undefiniert. In Wildtyp-Mitochondrien waren die CJs schmal und schlitzartig und haben einen scharfkantigen Übergang von der Cristaemembran zur inneren Grenzmembran. Des Weiteren wies die Cristaemembran in Δmic27-Zellen unregelmäßige zackige Strukturelemente auf, was auf eine Anhäufung an Dimeren der F1FO-ATP Synthase hinweist.
Diese Beobachtungen in den Kryo-Tomogrammen, wurde durch Analysen des Oligomerisierungszustands der F1FO-ATP Synthase in Δmic27-Zellen, bestätigt. Hier fanden sich deutlich weniger höhere Oligomere und vermehrt Dimere. So kann aus diesen Befunden geschlossen werden, dass Mic27 die Oligomere der F1FO-ATP Synthase stabilisiert.
Um zu untersuchen, wie der MICOS-Komplex mit der F1FO-ATP Synthase in Verbindung steht, wurde mittels 2D-BNE-Analysen und einem Complexome Profiling die Komplexierung der nativen Komplexe in Wildtyp- und Δmic27-Mitochondrien analysiert. Zum einen konnte durch diese Untersuchungen gezeigt werden, dass Mic27 neben der F1FO-ATP Synthase auch stabilisierend auf den MICOS-Komplex wirkt. Die Komplexe im hochmolekularen Bereich der MICOS-Komponenten zerfielen in Δmic27-Zellen, was darauf hinweist, dass die anderen MICOS-Komponenten hier nicht mehr assemblieren können. Mic10 war die einzige MICOS-Komponente die in Δmic27-Zellen noch stabile Komplexe im hohen Massenbereich ausbildete. Mic10 findet sich zudem nicht nur in Klustern mit anderen MICOS-Komponenten sondern auch mit der F1FO-ATP Synthase.
Die Interaktion von Mic10 und der F1FO-ATP Synthase wurde auch biochemisch, mittels chemischer Quervernetzern und Ko-Immunpräzipitationsexperimenten bestätigt. Dies legt nahe, dass Mic10 die CJs mit hoher Wahrscheinlichkeit, durch die Verbindung mit der F1FO-ATP Synthase, mit der Cristaemembran verbindet und so stabilisiert.
Aufgrund der Erkenntnisse dieser Arbeit konnte ein neuartiges Modell postuliert werden. Die MICOS-Komponente Mic60 stabilisiert die CJs durch eine Interaktion seines C-Terminus mit Proteinen in der Außenmembran. Mic27 vermittelt über Mic10 die Interaktion zur F1FO-ATP Synthase. Somit ist diese neu identifizierte Interaktion des MICOS-Komplex zur F1FO-ATP Synthase essentiell für die Stabilität von CJs ist, indem es den MICOS-Komplex mit den Oligomeren der F1FO-ATP Synthase verbindet.
The transition from the marine to the terrestrial realm is one of the most fascinating issues in evolutionary biology for it required the appearance, in different organisms, of several novel adaptations to deal with the demands of the new realm. Adaptations include, for instance, modifications in different metabolic pathways, development of body structures to facilitate movement and respiration, or tolerance to new conditions of stress. The transition to the land also gives an extraordinary opportunity to study whether evolution used similar changes at the genomic level to produce parallel adaptations in different taxa. Mollusks are among taxa that were successful in the conquest of the land. For instance, several lineages of the molluscan clade Panpulmonata (Gastropoda, Heterobranchia) invaded the intertidal, freshwater and land zones from the marine realm. In my dissertation, using tools from bioinformatics, phylogenetics, and molecular evolution, I used panpulmonates as a suitable model group to study the independent invasions into the terrestrial realm and the adaptive signatures in genes that may have favored the realm transitions. My work includes two peer-reviewed published papers and one manuscript under review. In Publication 1 (Romero et al., 2016a), I used mitochondrial and nuclear molecular markers to resolve the phylogeny of the Ellobiidae, a family that possesses intertidal and terrestrial species. The phylogeny provided an improved resolution of the relationships within inner clades and a framework to study the tempo and mode of the land transitions. I showed that the terrestrialization events occurred independently, in different lineages (Carychiinae, Pythiinae) and in different geological periods (Mesozoic, Cenozoic). In addition, the diversification in this group may not have been affected by past geological or climate changes as the Cretaceous-Paleogene (K-Pg) event or the sea-level decrease during the Oligocene. In Publication 2 (Romero et al., 2016b), I generated new mitochondrial genomes from terrestrial species and compared them with other panpulmonates. I used the branch-site test of positive selection and detected significant nonsynonymous changes in the terrestrial lineages from Ellobioidea and Stylommatophora. Two genes appeared under positive selection: cob (Cytochrome b) and nad5 (NADH dehydrogenase 5). Surprisingly, I found that the same amino acid positions in the proteins encoded by these genes were also under positive selection in several vertebrate lineages that transitioned between different habitats (whales, bats and subterranean rodents). This result suggested an adaptation pattern that required parallel genetic modifications to cope with novel metabolic demands in the new realms. In Manuscript 1 (Romero et al., under review), I de novo assembled transcriptomes from several panpulmonate specimens resulting in thousands of genes that were clustered in 702 orthologous groups. Again, I applied the branch-site test of positive selection in the terrestrial lineages from Ellobioidea and Stylommatophora and in the freshwater lineages from Hygrophila and Acochlidia. Different sets of genes appeared under positive selection in land and freshwater snails, supporting independent adaptation events. I identified adaptive signatures in genes involved in gas-exchange surface development and energy metabolism in land snails, and genes involved in the response to abiotic stress factors (radiation, desiccation, xenobiotics) in freshwater snails. My work provided evidence that supported multiple land invasions within Panpulmonata and provided new insights towards understanding the genomic basis of the adaptation during sea-to-land transitions. The results of my work are the first reports on the adaptive signatures at the codon level in genes that may have facilitated metabolic and developmental changes during the terrestrialization in the phylum Mollusca. Moreover, they contribute to the current debate on the conquest of land from the marine habitat, a discussion that has been only based in vertebrate taxa. Future comparative genome-wide analyses would increase the number of genes that may have played a key role during the realm transitions.
Ziel der vorliegenden Arbeit war es, vor- und nachbereitenden Unterricht zu Biodiversitätsführungen an den vier außerschulischen Lernorten Palmengarten, Senckenbergmuseum, Stadtwaldhaus und Zoo Frankfurt zu evaluieren. Durch den Unterricht mithilfe neu entwickelter Arbeitsmaterialien sollte die aktuelle Motivation der Schüler und weitere pädagogisch-psychologische Lernvariablen gefördert werden. Es stellte sich die Frage, ob so eine erhöhte Auseinandersetzung mit dem Themenkomplex Biodiversität erreicht werden kann und welche Einflussfaktoren dabei eine Rolle spielen.
Theoretische Grundlage war dabei das Risikowahlmodell der Leistungsmotivation nach Atkinson, das von Rheinberg zum handlungstheoretischen Modell der Motivation erweitert wurde (Rheinberg & Vollmeyer, 2012). Auf dieses bezieht sich der von Rheinberg et al. (2001) entwickelte und hier eingesetzte Fragebogen zur aktuellen Motivation (FAM).
Die Stichprobe setzte sich aus insgesamt 523 Schülern der Klassen 5 bis 9 zusammen. Davon nahm jeweils die Hälfte mit (Versuchsgruppe) und die andere ohne (Kontrollgruppe) vor- und nachbereitendem Unterricht an den Biodiversitätsführungen teil. Die Erhebung der aktuellen Motivation, des erworbenen Fachwissens und weiterer Variablen erfolgte in einem Pre/Post/Follow-Up-Design mit Fragebögen, deren Auswertung analytisch statistisch durgeführt wurde.
Es zeigte sich, dass in der Gesamtstichprobe die Teilnahme an der Biodiversitätsführung die aktuelle Motivation der Schüler erhöhte. Dauerhafte Lernparameter wie die Biologieeinstellung und die Interessenshandlung wurden jedoch nicht signifikant verändert. Ein eindeutiger Effekt der unterrichtlichen Vorbereitung konnte jedoch nicht ermittelt werden. Einzig beim gemessen Fachwissen zu den Führungsinhalten schnitt die Versuchsgruppe signifikant besser ab. Insgesamt wird angenommen, dass der Effekt des Besuchs des außerschulischen Lernortes an sich den Effekt der Vor- und Nachbereitung überdeckt oder vom Einfluss anderer Parameter beeinflusst wird. Hier stach besonders das Alter der Jugendlichen hervor, das vor allem in der hier evaluierten Schülergruppe bedingt durch die Pubertät eine große Rolle spielt. Weitere Einflussfaktoren waren die Biologieeinstellung und die Unterrichtsvariablen der Führung. In den Stichproben der einzelnen außerschulischen Lernorte zeigten sich leichte Abweichungen von der Gesamtstichprobe. Diese waren meist auf die leicht unterschiedliche Zusammensetzung der Stichproben zurückzuführen. Aber auch Besonderheiten der Lernorte hatten dabei ein bedeutendes Gewicht.
Bezüglich der Lernbedingungen für die Lernorte ließen sich aus den Ergebnissen vor allem zwei Komponenten ermitteln: Zum einen die Architektur/räumliche Struktur der Lernorte. Hier können Faktoren wie drinnen/ draußen, Größe und die räumliche Orientierung unterschieden werden. All dies hat Auswirkungen auf das physische Wohlbefinden der Schüler, was wiederum eine Voraussetzung für eine hohe Lernmotivation ist. Die andere Hauptkomponente ist das am Lernort behandelte Thema. Hier kann grob zwischen Pflanzen und Tieren unterschieden werden. Pflanzen wurden dabei in mehreren Studien von den Schülern als weniger attraktiv eingeschätzt. Trotzdem sollten aber die Möglichkeiten, auch botanische Themen außerhalb der Schule zu behandeln, von den Lehrkräften zur Vermittlung biologischer Vielfalt genutzt werden.
Als Konsequenz der Ergebnisse kann der Besuch eines außerschulischen Lernrotes im Biologieunterricht bezüglich der Förderung der Lernmotivation unbedingt empfohlen werden. Da kein klarer Effekt des vor- und nachbereitenden Unterrichts der Biodiversitätsführungen erkennbar war, wären hier weitere Untersuchungen vonnöten, um genauere Aussagen machen zu können. Hier böten sich Studien mit Schülern anderer Altersgruppen und der Vergleich nur zweier außerschulischer Lernorte an.
Weltweit sind ca. 130–180 Millionen Menschen mit HCV infiziert und jährlich sterben etwa 500.000 Menschen an dessen Folgen. Die neuartigen Therapien versprechen zwar eine sehr hohe Heilungsrate, sind aber aufgrund ihrer enorm hohen Kosten nur in Industrieländern verfügbar. Noch immer gibt es keine prophylaktische Vakzinierung gegen HCV. Deshalb ist es wichtig, den HCV-Lebenszyklus und die Interaktion zwischen Wirtszelle und Virus detailliert zu verstehen, um die Entwicklung von Therapien und Impfungen zu ermöglichen. Außerdem kann ein fundiertes Wissen von HCV translatiert werden und auf neuartige Erreger der Familie der Flaviviridae, wie Denguevirus und Zikavirus, angewendet werden. Während der Zelleintritt und die Replikation von HCV relativ gut charakterisiert sind, bleiben die Assemblierung und Freisetzung der viralen Partikel schlecht verstandene Schritte des HCV-Lebenszyklus. In dieser Arbeit sollte die Rolle des zellulären Proteins α-Taxilin im Lebenszyklus von HCV untersucht werden. In einer späteren Phase der Arbeit wurde der endosomale Freisetzungsweg von HCV untersucht. Dazu wurden HCV Varianten generiert und charakterisiert, die Fluoreszenz-Proteine im NS5A- und E1-Protein enthalten, durch die es möglich ist, den Replikationskomplex und die Viruspartikel zu visualisieren und zu quantifizieren und den viralen Lebenszyklus dadurch besser untersuchen zu können...
Saccharomyces cerevisiae is a natural producer of isobutanol, which has more advantages as biofuel than ethanol, i.e. superior combustion energy, weaker corrosive action and reduced aqueous miscibility. Isobutanol is produced by the combination of the valine biosynthesis and the Ehrlich pathway. In this work, an industrial strain was employed for isobutanol production, in which the valine pathway was relocated into the cytosol. The valine pathway in yeast has a cofactor imbalance, since the glycolysis produces NADH, while Ilv5 employs NADPH for the reaction. Therefore, the cofactor specificity of the pathway was rebalanced with exchange of Ilv5 by an NADH-consuming mutant, IlvC6E6. Furthermore, Ilv6, which regulates the feed-back inhibition of the valine biosynthesis, was tested to boost isobutanol production; however, none of these Ilv6 alternatives could greatly enhance isobutanol production. Therefore, due to a still low production yield, the bottlenecks of the isobutanol pathway were deeper studied.
The major observed bottleneck concerned the conversion of DIV into KIV, since high concentrations of acetoin, 2,3-butandiol and, specially, DIV were observed in the fermentation supernatant, while neither KIV nor isobutyraldehyde were detected. This step is performed by the dihydroxy-acid dehydratase, Ilv3, which needs iron-sulfur clusters for its activity. Therefore, the first approach to circumvent this limitation was to increase the FeS assembly and its transference into the cytoplasm; however, Ilv3Δ19 activity was not improvement. Afterwards, Ilv3 alternatives were screened for substitution of Ilv3Δ19. Heterologous ILV3 orthologous with possible advantages were investigated, but Ilv3Δ19 was still the most promising alternative. Furthermore, sugar-acid enolases were tested as Ilv3Δ19 substitutes. These enolases also catalyze the dehydration of the substrate in the same way as Ilv3, but uses Mg2+ as cofactor. One of the employed enolases could complement valine auxotrophy; however, it allowed just a very slow growth of the Δilv3 strain and its activity could not be enhanced by mutagenesis studies.
Interestingly, we observed that once DIV is secreted out of the cell, it cannot be re-uptaken from the medium and this possibly further aggravates the pathway flux and Ilv3Δ19 activity. In order to suppress DIV waste, two strategies were formulated: the deletion of the possible DIV transporter, and the substrate channeling of DIV from IlvC6E6 to Ilv3Δ19. In order to find possible DIV export proteins, a transcriptome analysis of a strain producing high amounts of DIV against a strain producing no detected DIV were compared. Several transporters were found upregulated in the DIV producing strain, but, alone, none of these were responsible for the DIV efflux. For the substrate channeling, an artificial enzymatic net was constructed by the fusion of IlvC6E6 and Ilv319 with synthetic zippers, which have high affinity to each other, and as both enzymes are alone organized as oligomers. The use of this enzymatic net enhanced not only the isobutanol production in about 17%, but also 3-methyl-butanol production yield was 25% increased.
Nevertheless, together with bottlenecks arising from Ilv3 activity, the isobutanol production is limited by the ethanol production, which is the main product of S. cerevisiae. Therefore, in order to abolish ethanol production, PDC1 and PDC5 were deleted. Moreover, BDH1 and BDH2 were also deleted to create an NADH-driving force towards isobutanol production. However, the isobutanol yield of this mutant was even lower than that of the strain without the mentioned deletions. As a high production of isobutyric acid was observed, and it could be produced directly from KIV, different KIV decarboxylases and isobutanol dehydrogenases were investigated; but without improvement. Then, alternative pathways were abolished in other to favor isobutanol production, e.g. valine, leucine, isoleucine and panthotenate biosyntheses. Nevertheless, isobutanol yields were still low and the main byproducts were glycerol, acetoin, DIV and isobutyric acid. Despite the outcomes were not enough to enhance isobutanol production up to commercially required yields, these results help in the comprehension of the bottlenecks surrounding the isobutanol production pathway and serve as basis for further studies within the branched-chain amino acids biosynthesis and Ehrlich pathway.
In the adult mammalian brain stem cells within defined neurogenic niches retain the capacity for lifelong de novo generation of neurons. The subventricular zone (SVZ) of the lateral ventricles and the subgranular layer (SGL) of the hippocampal dentate gyrus (DG) have been identified as the two major sites of adult neurogenesis. Moreover, the third ventricle in the hypothalamus is emerging as a new neurogenic niche in the adult brain. Extracellular purine and pyrimidine nucleotides are involved in the control of both embryonic and adult neuro-genesis. These nucleotides act via ionotropic P2X or metabotropic P2Y receptors and studies of the adult SVZ and the DG provide strong evidence that ATP promotes progenitor cell proliferation in this stem cell rich regions. Previous studies have shown that the extracellular nucleotide-hydrolyzing enzyme NTPDase2 is highly expressed by adult neural stem and progenitor cells of the SVZ and the rostral migratory stream (RMS), the hippocampal SGL, and the third ventricle. NTPDase2 preferentially hydrolyzes extracellular nucleoside triphosphates (NTPs) and, to a lower extent, diphosphates, thus modulating their effect on nearby nucleotide receptors. Deletion of the enzyme increases extracellular NTP concentrations, and might indicate roles of purinergic signaling in adult neurogenesis. As shown by enzyme histochemistry, genetic deletion of NTPDase2 essentially eliminates ATPase activity in neurogenic niches but does not affect protein expression levels and activity of other ectonucleotidases. Lack of NTPDase2 leads to expansion of the hippocampal stem cell pool as well as of the inter-mediate progenitor type-2 cells. Cell expansion is lost at around type-3 stage, paralleled by increased labeling for caspase-3, indicating increased apoptosis, and decreased levels in CREB phosphorylation in doublecortin-expressing cells, diminishing survival in this cell population. In line with increased cell death, P2Y12 receptor-expressing microglia is enriched at the hilus orientated side of the granule cell layer. These data strongly suggest that NTPDase2 functions as central homeostatic regulator of nucleotide-mediated neural progenitor cell proliferation and expansion in the adult brain by balancing extracellular nucleotide concentrations and activation of purinergic receptors.
In order to further characterize the role of purinergic signaling in adult neurogenesis, the ADP-sensitive P2Y13 receptor was identified as a potential candidate whose activation might inhibit neurogenesis in the hippocampal dentate gyrus and the newly identified neurogenic niche at the third ventricle. Deletion of P2ry13 increased progenitor cell proliferation and long-term progenitor survival as well as new neuron formation in the hippocampal neurogenic niche. This was further paralleled by increased thickening of the granule cell layer, CREB phosphorylation, and expression of the neuronal activity marker c-Fos. Increased progenitor cell proliferation and progenitor survival persist in aged P2ry13 knockout animals. However, in the ventral dentate gyrus proliferation and expansion levels of progenitor cells did not differ significantly from the wild type. This study strongly supports the notion that extracellular nucleotides significantly contribute to the control of adult neurogenesis in the dentate gyrus in situ. Data in this work suggest that activation of the P2Y13 receptor dampens progenitor cell proliferation, new neuron formation, and neuronal activity. In contrast to several in vitro studies and studies in the SVZ in situ, a contribution of the ATP/ADP-sensitive P2Y1 receptor could not be confirmed in the dentate gyrus in vivo.
To unravel implications of purinergic signaling and P2Y13 receptor action in the control of adult hypothalamic neurogenesis a pilot study was performed. Mice null for P2ry13 revealed increased progenitor cell proliferation at the third ventricle as well as long-term progeny survival and new neuron formation in the hypothalamus. In contrast to results obtained in the dentate gyrus expression of the neuronal activity marker c-Fos was significantly decreased in hypothalamic nuclei, indicating increased inhibition of appetite-regulating neuronal circuits by surplus neurons in knockout animals. These data provide first evidence that extracellular nucleotide signaling contributes to the control of adult hypothalamic neurogenesis in situ. Activation of the P2Y13 receptor inhibits progenitor cell proliferation, long-term survival and neuron formation and therefore controls inhibition of appetite-regulating circuits in the adult rodent hypothalamus.
The baker’s yeast Saccharomyces cerevisiae is a valuable and increasingly important microorganism for industrial applications (Hong and Nielsen, 2012). Its robustness concerning process conditions like low pH, osmotic and mechanical stress as well as toxic compounds is an advantage. Moreover, S. cerevisiae is ‘generally regarded as safe’ (GRAS). The model organism has been studied intensively. The collected data, including genomic, proteomic and metabolic information, can be used to genetically modify and improve its metabolism. Fatty acids and fatty acid derivatives have wide applications as biofuels, biomaterials, and other biochemicals. Several studies have been dealing with the overproduction of fatty acids and derivatives thereof in S. cerevisiae. The fatty acid biosynthesis starting with acetyl-CoA requires two enzymes, the acetyl-CoA carboxylase (Acc1p) and the fatty acid synthase complex (FAS), to produce acyl-CoA esters with predominantly 16 to 18 carbon atoms chain length (Lynen et al., 1980). For the synthesis of monounsaturated fatty acids in S. cerevisiae the ER bound acyl-CoA desaturase, Ole1p is essential (Tamura et al., 1976; Certik and Shimizu, 1999).
Using S. cerevisiae, the first section of this work dealt with the heterologous characterization of potential ω1-desaturases. Due to the fact that unsaturated fatty compounds can be modified further by hydrosilylations, hydrovinylations, oxidations to epoxides, acids, aldehydes, ketones or metathesis reactions, the interest in ω1-fatty acids is tremendous (Behr and Gomes, 2010). With the intention to find enzymes in fungi, that have a terminal desaturase activity a search in different genome databases was performed. The sequences of Pex-Desat3 and Obr-TerDes were used as reference sequences. The analysed proteins from Schizophyllum commune (EFI94599.1), Schizosaccharomyces octosporus (EPX72095.1), Wallemia mellicola (EIM20316.1), Wallemia ichthyophaga (EOR00207.1) and Agaricus bisporus var. bisporus (EKV44635.1), however, finally turned out to be Δ9 desaturases. A fungal desaturase with ω1-activity could not be found. The Δ9 desaturase SCD1 from Mus musculus was crystallized by Bai et al. (2015) and the information for specific amino acids responsible for the substrate specificity or enzyme activity were allocated. In combination with sequence and enzyme activity data form ChDes1 from Calanus hyperboreus, Desat2 from Drosophila melanogaster, Pex-Desat3 from Planotortrix excessana and Obr-TerDes from Operophtera brumata single amino acid exchanges were performed in the Δ9 desaturase Ole1p from S. cerevisiae. For all mutants, only fatty acids (C16 - C18) with a double bond between carbon C9 and C10 could be found. This indicates, that all inserted amino acid exchanges do not affect the substrate specificity or the position of the introduced double bond.
In the second section the focus was in the development of a production system for fatty acids in S. cerevisiae with regard to the previously established procedures by metabolic engineering. The combination of cytosolic malate dehydrogenase (MDH3), cytosolic malate enzyme (MAE1) and a citrate- α-ketoglutarate- carrier (YHM2) should improve the availability of acetyl-CoA in the cytosol, which is an important precursor for the fatty acid biosynthesis. If the major pathway (acetyl-CoA carboxylase and fatty acid synthase) was already optimized by high expression levels than no positive effect on increased fatty acid synthesis was detectable. Only non-optimized strains, with the additional overexpression of ATP-citrate lyase and cytosolic malate dehydrogenase, lead to a 41 % (20 mg/g dcw) improvement of fatty acid synthesis. In order to increase the fatty acid content further, the additional overexpression of DGA1 and TGL3 was performed. Hence, the highest amount of fatty acids could be observed with the strain S. cerevisiae WRY1ΔFAA1ΔFAA4 (2.5 g/L ± 0.8 g/L). The additional elimination of acyl-CoA synthetase Fat1p did not improve the yield.
It was recently reported, that chain length control of the fatty acid synthesis of bacterial FAS can be changed by rational engineering (Gajewski et al., 2017a). The knowledge about bacterial FAS was transferred in this work to S. cerevisiae FAS. Mutating up to five amino acids in the FAS complex enabled S. cerevisiae to produce medium chain fatty acids (C6 - C12). Further improvement was done by metabolic pathway engineering (promoter of alcohol dehydrogenase II from S. cerevisiae (pADH2), deletion of acyl-CoA synthetase FAA2) and optimization of fermentation conditions (YEPD-bacto medium buffered with potassium phosphate). The production of medium chain fatty acids resulted in the highest yield of 464 mg/L (C6 to C12 fatty acids). Furthermore, strains were created specifically overproducing hexanoic acid (158 mg/L) and octanoic acid (301 mg/L). The characterization of transferases, which could be responsible for the de-esterification of CoA-bound fatty acids, was analysed in an additional approach. It could be shown, that the genes EHT1, EEB1 and MGL2 have an influence on the MCFA yield in the supernatant. Generally speaking, the data from the single and double deletion strains suggest that Eeb1p has a selective hydrolytic activity for hexanoic acid-CoA ester, while Eht1p shows selective hydrolytic activity for octanoic acid-CoA ester, which is in line with Saerens et al. (2006).