Biologische Hochschulschriften (Goethe-Universität)
Refine
Year of publication
- 2010 (18) (remove)
Document Type
- Doctoral Thesis (17)
- Article (1)
Language
- English (18) (remove)
Has Fulltext
- yes (18) (remove)
Is part of the Bibliography
- no (18)
Keywords
- Arzneimitteldesign (2)
- Computational chemistry (2)
- Alignment <Biochemie> (1)
- Allergie (1)
- Allergy (1)
- Anpassung (1)
- Biotest (1)
- Blech- und Metallwarenindustrie (1)
- De-Novo-Synthese (1)
- Deterministische Optimierung (1)
Institute
- Biowissenschaften (11)
- Biochemie und Chemie (4)
- Institut für Ökologie, Evolution und Diversität (1)
- Medizin (1)
- Pharmazie (1)
Therapy of hemorrhagic shock with following resuscitation-induced liver injury : in vivo study
(2010)
Shock resulting from life-threatening blood-loss (hemorrhagic shock) represents the most frequent injury pattern after a traumatic insult. Hemorrhagic shock induces inflammatory changes, characterized by highly complex pathophysiological pathways often resulting in death. In this study, we establish an experimental in vivo model of H/R in rats and study the mechanisms which determine the hepatic injury after H/R. Furthermore, we show that hemorrhagic shock with following resuscitation is accompanied with release of systemic and local pro-inflammatory mediators, increased infiltration of hepatic neutrophils in the liver, increased oxidative and nitrosative stress, enhanced cell death of both types, apoptosis and necrosis, conspicuous cytoskeletal rearrangements, loss of hepatic integrity and finally high general mortality rates, up to 80%. In addition, the effects of two potential therapeutic interventions to prevent the H/R induced liver injury are explored in a model of H/R in rats. First, the role of JNK and its inhibition by D-JNKI-1 in preservation of hepatic integrity following H/R was analyzed. Second, we investigated the potential of simvastatin to prevent the disturbed inflammatory response and hepatic injury after H/R. The effects of both therapeutic interventions were studied by looking at several inflammatory parameters, markers of oxidative and nitrosative stress, cytoskeleton integrity, microcirculatory parameters, underlying signaling cascades, liver damage and mortality. Highly specific blockade of JNK with the potent, inhibitory peptide D-JNKI-1 revealed the crucial role of the JNK signaling pathway in the H/R induced pathophysiology and strong protective effects of DJNKI- 1 in H/R induced liver injury, when the peptide was applied before and even after hemorrhagic shock. The other therapeutic intervention tested in this study was the use of simvastatin which also revealed protective effects after H/R and even a remarkable improvement in survival after H/R. We show that H/R induced release of pro-inflammatory cytokines, hepatic PMNL infiltration, increased oxidative and nitrosative stress, apoptosis and necrosis can be diminished by treatment with D-JNKI-1 but also with simvastatin in vivo. Furthermore, simvastatin reduces H/R induced cytoskelatal rearrangements, loss of liver integrity and the mortality rate after H/R. The key pathway which underlies these beneficial effects of simvastatin is the Rho kinase pathway. Identification of both mechanisms as well as the effectiveness of both substances provide new insights in the close interaction between hypoxia and the immune system and present a promising basis for the anti-inflammatory, hepatoprotective treatment after H/R.
Die Maillard-Reaktion findet während der Lagerung und thermischen Verarbeitung von Lebensmitteln zwischen den darin enthaltenen Proteinen und reduzierenden Kohlehydraten statt. Als Ergebnis der Reaktion entstehen sogenannte advanced glycation end products (AGEs), Protein-Derivate mit Glykierungs-Strukturen. Da Lebensmittel vor dem Verzehr häufig erhitzt werden, ist der Einfluss von AGEs auf die Pathogenese von Nahrungsmittelallergien von großem Interesse. Die Maillard-Reaktion könnte zur Bildung von neuen, für die Pathogenese der Nahrungsmittelallergie relevanten, Immunepitopen beitragen. Das Ziel dieser Arbeit war es, den Einfluss der Maillard-Reaktion auf die T-Zell-Immunogenität, die Antigenität und die von beiden Eigenschaften abhängige Allergenität von Nahrungsmittelallergenen zu untersuchen. Zunächst wurde der Einfluss der Maillard-Reaktion auf die T-Zell-Immunogenität von Ovalbumin (OVA), einem Allergen des Hühnereiweißes, untersucht. Dafür wurde glykiertes OVA (AGE-OVA) hergestellt indem das Protein zusammen mit Glukose erhitzt wurde. In dieser Arbeit konnte zum ersten Mal gezeigt werden, dass ein AGE-Derivat eines Lebensmittelallergens eine höhere T-Zellen-Immunogenität besitzt, als sein natives Gegenstück. Die Aktivierung und Proliferation von CD4+ T-Zellen durch AGE-OVA wurde in vitro durch Co-Kultivierung der T-Zellen mit dendritischen Zellen (DZ) untersucht. DZ sind professionelle Antigen- präsentierende Zellen, welche im Pathomechanismus der Allergie eine wichtige Rolle spielen. Im Vergleich zu nativen OVA und OVA welches ohne Glukose erhitzt wurde, führte die Stimulierung mit AGE-OVA zu einer deutlich erhöhten Aktivierung von OVA-spezifischen CD4+ T-Zellen. Damit DZ T-Zellen aktivieren können, muss das Allergen zunächst durch die DZ aufgenommen werden. In der vorliegenden Arbeit wurde gezeigt, dass die Aufnahme von AGE-OVA wesentlich höher war als die der Kontrollen. Außerdem konnte der scavenger receptor class A type I and II (SR-AI/II) als einer der hauptverantwortlichen Rezeptoren für die Aufnahme von AGE-OVA identifiziert werden. Zusammenfassend lässt sich aus den Ergebnissen dieser Arbeit die Hypothese aufstellen, dass die Glykierung von OVA eine erhöhte Assoziation des Allergens mit SR-AI/II ermöglicht, welche zu einer verstärkten Aufnahme des Allergens durch die DZ führt. Dadurch können mehr Peptide des Allergens an MHC II gebunden und auf der Zelloberfläche präsentiert werden. Das wiederum führt zur beobachteten stärkeren OVA-spezifischen CD4+ T-Zell-Aktivierung durch AGE-OVA. Als nächstes wurde die T-Zell-Immunogenität und Antigenität von AGE-OVA in vivo in einem Mausmodel untersucht. Es zeigte sich, dass AGE-OVA auch in vivo im Vergleich zu den nicht glykierten OVA-Formen eine erhöhte T-Zell-Immunogenität besitzt. Des weiteren führte die Immunisierung mit AGE-OVA zu einer erhöhten Produktion von IgE-Antikörpern. Somit wurde in dieser Arbeit gezeigt, dass AGE-OVA in vivo nicht nur eine erhöhte CD4+ T-Zell-Immunogenität besitzt, sondern auch eine höhere Antigenität hat als natives und ohne Glukose erhitztes OVA. Diese Ergebnisse harmonieren gut miteinander da CD4+ T-Zellen eine zentrale Rolle in der Aktivierung von B-Zellen und der IgE-Produktion durch selbige Zellen spielen. IgE-Antikörper besitzen eine essentielle Funktion beim Auslösen der klinischen Symptomatik der Allergie. Zusammenfassend lässt deshalb sagen, dass die Maillard-Reaktion die Allergenität von OVA erhöhen könnte. Zum Schluss wurden noch die immunstimulatorischen Eigenschaften des Erdnussallergens (AGE)-Ara h 2 untersucht. Da Erdnüsse häufig ernsthafte allergische Reaktionen hervorrufen und selten roh verzehrt werden, war es vom großen Interesse den Einfluss der Maillard-Reaktion auf Immunogenität und Antigenität von rekombinanten Ara h 2 (rAra h 2) zu untersuchen. Es zeigte sich, dass die Glykierung von rAra h 2 durch die Maillard-Reaktion die T-Zellen-Immunogenität, als auch die Antigenität des Allergens reduziert. Abschließend lässt sich sagen, dass die Maillard-Reaktion die allergenen Eigenschaften von Lebensmittelallergenen erheblich beeinflusst indem es die T-Zell-Immunogenität des Allergens verändert. Die Mechanismen welche die T-Zell-Immunogenität beeinflussen wurden hier näher untersucht. Wenn die Glykierung nicht die Bindung der T-Zellen- und/oder B-Zellen-Rezeptoren inhibiert, wird die Allergen-spezifische CD4+ T-Zell-Aktivierung und die davon abhängige IgE-Produktion dadurch erhöht, dass das glykierte Allergen durch DZ verstärkt über SR-AI/II aufgenommen wird. Die vorliegende Arbeit liefert wertvolle Information über die Allergenität von Proteinen die durch die Maillard-Reaktion modifiziert wurden and trägt dazu bei die Mechanismen von Nahrungsmittelallergien besser zu verstehen.
The estimation model PhytoCalc allows a non-destructive quantification of dry weight and nutrient pools of understorey plants in forests by using the relationship between species biomass, cover and mean shoot length. The model has been validated with independent samples in several German forest types and can be a useful tool in forest monitoring. However, in open areas within forests (e.g. clearcuts), the current model version underestimates biomass and produces unreliable nutrient pool estimations. Thus, tissue density, as approximated by leaf dry matter content (LDMC), is systematically higher under high light compared to low light conditions. We demonstrate that the ratio of LDMC under clearcut conditions to LDMC under forest conditions can be used to adjust the PhytoCalc model to clearcut conditions. We investigated the LDMC ratio of five exemplary species commonly occurring on clearcuts. Integrating the square of the ratio as a correction factor improved estimates of biomass to more than 70% fit between observations and predictions. Results also suggest this ratio can be used to correct nutrient concentrations modelled in PhytoCalc, which tend to be overestimated in clearcuts. As morphological groups of plant species exhibit significantly different ratios, we advise using group-specific correction factors for clearcut adjustments in the future.
This work investigated the applicability of global pairwise sequence alignment to the detection of functional analogues in virtual screening. This variant of sequence comparison was developed for the identification of homologue proteins based on amino acid or nucleotide sequences. Because of the significant differences between biopolymers and small molecules several aspects of this approach for sequence comparison had to be adapted. All proposed concepts were implemented as the ‘Pharmacophore Alignment Search Tool’ (PhAST) and evaluated in retrospective experiments on the COBRA dataset in version 6.1. The aim to identify functional analogues raised the necessity for identification and classification of functional properties in molecular structures. This was realized by fragment-based atom-typing, where one out of nine functional properties was assigned to each non-hydrogen atom in a structure. These properties were pre-assigned to atoms in the fragments. Whenever a fragment matched a substructure in a molecule, the assigned properties were transferred from fragment atoms to structure atoms. Each functional property was represented by exactly one symbol. Unlike amino acid or nucleotide sequences, small drug-like molecules contain branches and cycles. This was a major obstacle in the application of sequence alignment to virtual screening, since this technique can only be applied to linear sequences of symbols. The best linearization technique was shown to be Minimum Volume Embedding. To the best of knowledge, this work represents the first application of dimensionality reduction to graph linearization. Sequence alignment relies on a scoring system that rates symbol equivalences (matches) and differences (mismatches) based on functional properties that correspond to rated symbols. Existing scoring schemes are applicable only to amino acids and nucleotides. In this work, scoring schemes for functional properties in drug-like molecules were developed based on property frequencies and isofunctionality judged from chemical experience, pairwise sequence alignments, pairwise kernel-based assignments and stochastic optimization. The scoring system based on property frequencies and isofunctionality proved to be the most powerful (measured in enrichment capability). All developed scoring systems performed superior compared to simple scoring approaches that rate matches and mismatches uniformly. The frameworks proposed for score calculations can be used to guide modifications to the atom-typing in promising directions. The scoring system was further modified to allow for emphasis on particular symbols in a sequence. It was proven that the application of weights to symbols that correspond to key interaction points important to receptor-ligand-interaction significantly improves screening capabilities of PhAST. It was demonstrated that the systematic application of weights to all sequence positions in retrospective experiments can be used for pharmacophore elucidation. A scoring system based on structural instead of functional similarity was investigated and found to be suitable for similarity searches in shape-constrained datasets. Three methods for similarity assessment based on alignments were evaluated: Sequence identity, alignment score and significance. PhAST achieved significantly higher enrichment with alignment scores compared to sequence identity. p-values as significance estimates were calculated in a combination of Marcov Chain Monte Carlo Simulation and Importance Sampling. p-values were adapted to library size in a Bonferroni correction, yielding E-values. A significance threshold of an E-value of 1*10-5 was proposed for the application in prospective screenings. PhAST was compared to state-of-the-art methods for virtual screening. The unweighted version was shown to exhibit comparable enrichment capabilities. Compound rankings obtained with PhAST were proven to be complementary to those of other methods. The application to three-dimensional instead of two-dimensional molecular representations resulted in altered compound rankings without increased enrichment. PhAST was employed in two prospective applications. A screening for non-nucleoside analogue inhibitors of bacterial thymidin kinase yielded a hit with a distinct structural framework but only weak activity. The search for drugs not member of the NSAID (non-steroidal anti-inflammatory drug) class as modulators of gamma-secretase resulted in a potent modulator with clear structural distiction from the reference compound. The calculation of significance estimates, emphasizing on key interactions, the pharmacophore elucidation capabilities and the unique compound rannkings set PhAST apart from other screening techniques.
Der L-Carnitin/gamma-Butyrobetain Antiporter CaiT ist ein Mitglied der Betain/Carnitin/Cholin Transporter (BCCT) Familie. Sekundärtransporter der BCCT Familie transportieren Substrate, die eine positiv-geladene quartäre Ammoniumgruppe besitzen. CaiT besteht aus 504 Amiosäuren und besitzt ein moleculares Gewicht von etwa 56 kDa. In Enterobakterien wie Escherichia coli, Proteus mirabilis und Salmonella typhimurium wird die Expression des caiTABCDE Operons unter anaeroben Bedingungen induziert. Unter diesen Bedinungen ist CaiT der Haupttransporter des Betain-Derivates L-Carnitin. In Enterobakterien wird L-Carnitin unter anaeroben Bedingungen aufgenommen und dehydratisiert wobei Crotonobetain ensteht. Crotonobetain wird anschließend zum Endprodukt gamma-Butyrobetain reduziert. Gamma-Butyrobetain ist das Gegensubstrat, das aus der Zelle hinaustransportiert wird, wenn L-Carnitin in die Zelle aufgenommen wird. Der Austauschmechanismus von LCarnitin gegen gamma-Butyrobetain geschieht ohne das Vorhandensein eines elektrochemischen Gradients, d.h. CaiT ist sowohl H+- als auch Na+-unabhängig. Ein Ziel dieser Arbeit war es die drei-dimensionale (3D) Struktur von CaiT mittels Röntgenstrukturanalyse zu lösen. Weiterhin sollten mit Hilfe der 3D-Struktur und funktionellen Studien detailiertere Erkenntnisse über den kationenunabhängigen Antiportmechanismus von CaiT ermittelt werden. Im Rahmen dieser Arbeit wurden die 3D-Röntgenkristallstrukturen von drei CaiT-Homologen der Enterobakterien P. mirabilis (PmCaiT), E. coli (EcCaiT) und S. typhimurium (StCaiT) mittels molekularem Ersatz (engl.: molecular replacement, MR) mit einem Alanin-Model des CaiT verwandten Na+/Glycinbetain Symporters BetP gelöst. PmCaiT konnte mit einer Auflösung von 2.3 Å gelöst werden. Das Protein kristallisierte in der Kristallraumgruppe H3, mit drei Molekülen in der asymmetrischen Einheit (engl.: asymmetric unit, AU). Die drei PmCaiT-Moleküle ordneten sich innerhalb der AU um eine kristallographische dreifach Symmetrieachse an. EcCaiT wurde mittels MR mit einem Alanin-Model von PmCaiT bei einer Auflösung von 3.5 Å gelöst. EcCaiT kristallisierte in der Kristallraumgruppe P32, ebenfalls mit drei Molekülen in der AU, jedoch ohne kristallographische Symmetry. Während der Verfeinerung des EcCaiT-Models wurde eine strenge dreifache nichtkristallographische Symmetry (engl.: non-crystallographic symmetry, NCS) angewandt. StCaiT, das ebenfalls mittels MR mit einem Alanin-Model von PmCaiT, aber bei einer Auflösung von 4.0 Å gelöst wurde, kristallisierte in der Kristallraumgruppe P65, ebenfalls mit drei StCaiT-Molekülen in der AU, ohne kristallographische Symmetry. Bei der Verfeinerung des StCaiT-Modells wurde wie bei EcCaiT eine strenge NCS angewandt. Da die Auflösung von 4.0 Å bei StCaiT zu niedrig ist um detailierte moleculare Erkenntnisse zu gewinnen, wurden Protein- sowie Substratinteraktionen nur an den Strukturen von PmCaiT und EcCaiT analysiert. Alle drei CaiT-Homologe weisen jedoch einen ähnlichen strukturellen Aufbau auf. In der Röntgenkristallstruktur bildet CaiT ein symmetrisches Trimer, das über ionische und polare Wechselwirkungen zwischen den Protomeren stabilisiert wird. Der trimere Oligomerisierungszustand von CaiT in Detergenzlösung sowie in zweidimensionalen Lipidmembrankristallen wurde bereits in früheren Arbeiten gezeigt. Jedes der drei CaiT-Protomere besteht aus zwölf Transmembranhelices (TMH), die N- und C-terminalen Domänen des Proteins befinden sich auf der cytoplasmatischen Seite. Zehn der TMH bilden zwei invertierte Wiederholungseinheiten aus jeweils fünf TMH. Die erste Einheit besteht aus den TMH 3 – 7, die invertierte zweite Einheit besteht aus den TMH 8 – 12. Beide Wiederholungseinheiten sind strukturell nahezu identisch und lassen sich fast vollständig übereinanderlegen, jedoch weisen die Aminosäuren der beiden Einheiten keine signifikante Sequenzidentität auf. Die ersten beiden Helices der Wiederholungseinheiten, die TMH 3 – 4 und die TMH 8 – 9, bilden ein antiparalleles vier-Helix-Bündel, in dem in CaiT zwei Substratbindestellen lokalisiert sind. Eine derartige Transporterarchitektur wurde erstmals in der Struktur des Na+/Alanin Symporters LeuTAa des thermophilen Bakteriums Aquifex aeolicus gezeigt. Bislang wurden, inklusive CaiT, sieben Sekundärtransporterstrukturen gelöst, die diese LeuT-Transporterarchitektur aufweisen. Ungewöhnlich dabei ist, dass diese sieben Sekundärtransporter fünf verschiedenen Transporterfamilien angehören und eine Verwandschaft auf Basis der Aminosäuren nicht zu finden ist. Da jedoch die tertiäre Struktur dieser Tansporter konserviert ist, kann davon ausgegangen werden, dass sie alle von einem Urprotein entstanden sind, welches zunächst aus fünf TMH bestanden haben muss. Im Laufe der Evolution hat sich das Urgen des Urproteins zunächst dupliziert und die weitere Evolution hat zwar die Aminosäuresequenz verändert und den Umweltbedingungen angepasst, jedoch ist die tertiäre Struktur erhalten geblieben. Da sich die tertiäre Struktur der sieben Sekundärtransporter so stark ähnelt, ist zu vermuten, dass auch der Transportmechanismus ähnlich, jedoch nicht identisch ist. Nach dem strukturellen Aufbau der Transporter, der Lage der Substratbindestellen in den jeweiligen Transportern und der Tatsache, dass es sich bei diesen Proteinen um Membranproteine handelt, wurde ein Transportmechanismus aufgestellt, in dem die Bindestelle des zu transportierende Substrats alternierend zu beiden Seiten der Membran zugänglich ist, ohne jedoch jemals den Substratweg innerhalb des Proteins vollständig zu öffnen. Dieser Mechanismus wurde als “alternating access mechanism” beschrieben. Anhand der unterschiedlichen Zustände, in denen einige der Transporter kristallisierten, kann abgeleitet werden, welche Konformationsänderungen erforderlich sind um das Substrat von einer Seiter der Membran auf die andere zu transportieren. Bisher kristallisierten einzelne der sechs Transporter in der nach außen gerichteten offenen Form, der nach außen gerichteten Form, in der die Substratbindestelle jedoch nicht mehr zugänglich ist, in einer Form, die keine Öffnungspräferenz der Substratbindestelle zu einer Seite der Membran hat und in der nach innen gerichteten Form, in der die Substratbindestelle jedoch nicht geöffnet ist. CaiT kristallisierte in der noch fehlenden Konformation, der nach innen gerichteten Form, in der die Substratbindestelle zugänglich ist. Mit dieser noch fehlenend Konformation kann der Transportzyklus des “alternating access mechanism” vollständig beschrieben werden. Alle drei CaiT-Homologe kristallisierten in der nach innen gerichteten, offenen Konformation. Im Gegensatz zur EcCaiT-Struktur kristallisierte PmCaiT in der substratungebundenen Form. In der StCaiT-Struktur konnte aufgrund der niedrigen Auflösung kein Substrat nachgewiesen werden. In der EcCaiT-Struktur sind zwei gamma-Butyrobetain-Moleküle gebunden. Das erste Molekül wurde in der zentralen Substratbindestelle, der sogenannten Tryptophan-Box bestehend aus vier Tryptophanen, im Zentrum des Protein lokalisiert. Das zweite gamma-Butyrobetain-Molekül wurde in einer Vertiefung an der extrazellulären Proteinoberfläche gefunden. Beide Substrate werden hauptsächlich über Kation-Pi-Interaktionen zwischen der positiv geladenen quatären Ammoniumgruppe des Substrats und des Pi-Elektronensystems der Tryptophane in den jeweiligen Bindestellen gebunden. Eine besondere Eigenschaft von CaiT ist der H+- bzw. Na+-unabhängige Substrattransport. Die CaiT-Struktur erklärt warum kein zusätzliches Kation benötigt wird um Substrat zu binden oder zu transportieren. In der EcCaiT-Struktur ist eine wichtige polare nicht-bindende Interaktion zwischen der Carboxylgruppe des gamma-Butyrobetains und dem Schwefelatom eines Methionins in der zentrale Bindestelle zu erkennen. Dieses Methionin ist konserviert in den prokaryotischen CaiTs und in den Na+-unabhängigen eukaryotischen L-Carnitin Transportern (OCTN), jedoch ist es nicht konserviert im Na+-abhängigen verwandten Glycinbetain Transporter BetP. In BetP ist diese Position des Methionins durch ein Valin ersetzt. Die Mutation des Methionins in CaiT zu Valin ermöglicht zwar immernoch die H+- bzw. Na+-unabhängige Bindung des Substrates durch die Tryptophan-Box, jedoch ist der Substrattransport nahezu vollständig zerstört. Eine derart wichtige Substratkoordinierende Funktion des Schwefelatoms eines Methionins wurde bisher nicht beschrieben. Eine weitere Stelle, die in H+- bzw. Na+-abhängigen Transporter mit H+ bzw. Na+ besetzt ist, ist in CaiT von einem positiv geladenen Arginin eingenommen. Eine positive Ladung an dieser Stelle stabilisiert den Bereich im Protein in der Nähe der zentralen Substratbindestelle. Die Mutation des Arginins zu Glutamat in CaiT erzielt eine vollständige Inaktivierung des Substrattansports. Durch Zugabe von Na+ im Transportansatz kann die Substrattransportaktivität der Glutamat-Mutante jedoch teilweise zurückerlangt werden. Diese eben beschriebenen Aminosäurereste in den beiden Stellen des Proteins erklären die Kationenunabhängigkeit von CaiT. Die Aktivierung des Antiportmechanismus in CaiT wurde mit Hilfe von Bindungsstudien an rekonstituiertem Protein ermittelt. Diese Messungen ergaben für das Wildtypprotein ein sigmoidales Substratbindungsverhalten, was auf ein positiv-kooperatives Bindungsverhalten hindeutet. Die beiden Substratbindestellen im Protein sowie die beiden unterschiedlichen Substrate, L-Carnitin und gamma-Butyrobetain, lassen auf einen heterotropen positiv-kooperativen Bindungs- und einen allosterisch regulierten Transportmechanismus schließen. Bei diesem Mechanismus erhöht die Bindung eines Substrats in der regulatorischen Bindestelle durch induzierte Konformationsänderungen die Affinität eines anderen Substrats in einer weiteren Substratbindestelle. Die regulatorische Bindestelle in CaiT befindet sich an der extrazellulären Proteinoberfläche. Eine Schwächung der Substrataffinität in dieser Bindestelle durch Einführung einer Mutation, verstärkt das sigmoidale Substratbindungsverhalten und hat einen negativen Einfluss auf den Substrattransport. Durch die in dieser Arbeit gelösten 3D-Röntgenkristallstrukturen der zwei CaiT-Homologen, PmCaiT und EcCaiT, sowie den durchgeführten funktionellen Studien sowohl an Wildtypprotein wie auch an Mutanten konnte ein L-Carnitin/gamma-Butyrobetain Antiport-Mechanismus für CaiT vorzuschlagen werden.
The single unit doctrine proposes that each one of our percepts and sensations is represented by the activity of specialized high-level cells in the brain. A common criticism applied to this proposal is the one referred to as the "combinatorial problem". We are constantly confronted with unlimited combinations of elements and features, and yet we face no problem in recognizing patterns and objects present in visual scenes. Are there enough neurons in the brain to singly code for each one of our percepts? Or is it the case that perceptions are represented by the distributed activity of different neuronal ensembles? We lack a general theory capable of explaining how distributed information can be efficiently integrated into single percepts. The working hypothesis here is that distributed neuronal ensembles signal relations present in the stimulus by selectively synchronizing their spiking responses. Synchronization is generally associated with oscillatory activity in the brain. Gamma oscillations in particular have been linked to various integrative processes in the visual system. Studies in anesthetized animals have shown a conspicuous increase in power for the gamma frequency band (30 to 60 Hz) in response to visual stimuli. Recently, these observations have been extended to behavioral studies which addressed the role of gamma activity in cognitive processes demanding selective attention. The initial motivation for carrying out this work was to test if the binding-by-synchronization (BBS) hypothesis serves as a neuronal mechanism for perceptual grouping in the visual system. To this aim we used single and superimposed grating stimuli. Superimposed gratings (plaids) are bi-stable stimuli capable of eliciting different percepts depending on their physical characteristics. In this way, plaids can be perceived either as a single moving surface (pattern plaids), or as two segregated surfaces drifting in different directions (component plaids). While testing the BBS hypothesis, we performed various experiments which addressed the role of both stimulus and cortical architecture on the properties of gamma oscillations in the primary visual cortex (V1) of monkeys. Additionally, we investigated whether gamma activity could also be modulated by allocating attention in time. Finally, we report on gamma-phase shifts in area V1, and how they depend on the level of neuronal activation. ...
Apoptotic cell (AC)-derived factors alter the physiology of macrophages (M Phi s) towards a regulatory phenotype that is characterized by enhanced production of anti-inflammatory mediators, an attenuated pro-inflammatory cytokine profile and reduced nitric oxide (NO) formation. Impaired NO production in response to ACs or AC-conditioned medium (CM) is facilitated by arginase II (ARG II) expression, which competes with inducible NO synthase for L-arginine. In this study, I investigated the signaling pathway that allowed CM to upregulate ARG II in M Phi s. A sphingolipid, further identified as sphingosine-1-phosphate (S1P), was required but authentic S1P alone only produced small effects. S1P acted synergistically with a so far unidentified factor to elicit high ARG II expression. S1P signaled through S1P receptor 2 (S1P2), since the S1P2-antagonist JTE013 and siRNA knock-down of S1P2 prevented ARG II upregulation. Further, inhibition and knock-down of extracellular signal-regulated kinase 5 (ERK5) attenuated CM-mediated ARG II protein induction. Exploring ERK5-dependent transcriptional regulation, promoter deletion and luciferase reporter analysis of the murine ARG II promoter (mpARG II) suggested the involvement of cyclic adenosine monophosphate (cAMP) responsive element binding protein (CREB). This was confirmed by EMSA analysis and decoyoligonucleotides scavenging CREB, thereby preventing it from activating target genes and thus, blocking ARG II expression. I concluded that AC-derived S1P binds to S1P2 and acts synergistically with other factors to activate ERK5 and concomitantly CREB. This signaling cascade shapes an anti-inflammatory M Phi phenotype by ARG II induction. Further investigations of ERK5-dependent CREB activation suggested an indirect mechanism implying that ERK5 inhibited phosphodiesterase 4 (PDE4) and thus, prevented hydrolysis of cAMP. Since S1P-dependent ERK5 activation presumably inhibited PDE4, subsequent cAMP accumulation led to enhanced PKA activity and CREB-mediated transcription. The unidentified factor(s) besides S1P probably provoked the required elevation of cAMP production in M Phi s. Indeed, pharmacological inhibition of cAMP-producing adenylyl cyclase with SQ22536 as well as cAMP-dependent protein kinase A (PKA) with KT5720 suggested cAMP to be involved in CM-mediated ARG II up-regulation. Furthermore, forskolin-dependent activation of adenyly cyclase and simultaneous rolipram-mediated inhibition of PDE4 mimicked CM-induced ARG II expression. Considering these findings, I propose that one or several unidentified factors in CM provoke cAMP production in M Phi s. In parallel, AC-derived S1P activates ERK5, which inhibits PDE4-dependent cAMP hydrolysis, further raising intracellular cAMP levels. Thus, unrestricted continuous cAMP signaling via PKA/CREB, results in a time-dependent and sustained ARG II induction.
Type 1 diabetes (T1D) is a chronic T cell-mediated autoimmune disorder that results in the destruction of insulin-producing pancreatic ß cells leading to life-long dependence on exogenous insulin. Attraction, activation and transmigration of inflammatory cells to the site of ß-cell injury depend on two major molecular interactions. First, interactions between chemokines and their receptors expressed on leukocytes result in the recruitment of circulating inflammatory cells to the site of injury. In this context, it has been demonstrated in various studies that the interaction of the chemokine CXCL10 with its receptor CXCR3 expressed on circulating cells plays a key role in the development of T1D. Second, once arrived at the site of inflammation adhesion molecules promote the extravasation of arrested cells through the endothelial cell layer to penetrate the site of injury. Here, the junctional adhesion molecule (JAM) JAM-C expressed on endothelial cells is involved in the process of leukocyte diabedesis. It was recently demonstrated that blocking of JAM-C efficiently attenuated cerulein-induced pancreatitis in mice. In my thesis I studied the influence of the CXCL10/CXCR3 interaction on the one hand, and of the adhesion molecule JAM-C on the other hand, on trafficking and transmigration of antigen-specific, autoaggressive T cells in the RIP-LCMV mouse model. RIP-LCMV mice express the glycoprotein (GP) or the nucleoprotein (NP) of the lymphocytic choriomeningitis virus (LCMV) as a target autoantigen specifically in the ß cells of the islets of Langerhans and turn diabetic after LCMV-infection. In my first project I found that pharmacologic blockade of CXCR3 during development of virus-induced T1D results in a significant delay but not in an abrogation of overt disease. However, neither the frequency nor the migratory properties of islet-specific T cells was significantly changed during CXCR3 blockade. In the second project I was able to demonstrate that JAM-C was upregulated around the islets in RIP-LCMV mice after LCMV infection and its expression correlated with islet infiltration and functional ß-cell impairment. Blockade with a neutralizing anti-JAM-C antibody slightly reduced T1D incidence, whereas overexpression of JAM-C on endothelial cells did not accelerate virus-induced diabetes. In summary, our data suggest that both CXCR3 as well as JAM-C are involved in trafficking and transmigration of antigen-specific autoaggressive T cells to the islets of Langerhans. However, the detection of only a moderate influence on the onset of clinical disease during CXCR3 or JAM-C blockade reflects the complex pathogenesis of T1D and indicates that several different inflammatory factors need to be neutralized in order to achieve a stable and persistent protection from disease.
The glycine receptor (GlyR) is the major inhibitory neurotransmitter receptor in spinal cord and brainstem. Heteropentameric GlyRs are clustered and anchored at inhibitory postsynaptic sites by the binding of the large intracellular loop between transmembrane domains 3 and 4 of the GlyRbeta subunit (GlyRbeta-loop) to the cytoplasmic scaffolding protein gephyrin. GlyRs are also cotransported with gephyrin along microtubules in the anterograde and retrograde direction due to the binding of gephyrin to microtubule-associated motor proteins. Additionally, GlyRs undergo lateral diffusion in the plasma membrane from extrasynaptic to synaptic sites and vice versa. Since its discovery, gephyrin has remained for many years the only binding partner interacting directly with the GlyRbeta subunit. In an attempt to elucidate further mechanisms involved in GlyR function and regulation at inhibitory postsynaptic sites, a proteomic screen for putative binding partners to the GlyRbeta loop was performed. Three proteins were identified as putative interactors. In this thesis, the interaction between these putative binding proteins and the GlyRbeta subunit was analyzed and characterized. Binding studies with glutathione-S-transferase fusion proteins revealed that all putative binding proteins, Syndapin (Sdp), Vacuolar Protein Sorting 35 (Vps35) and Neurobeachin (Nbea), interact specifically with the GlyRbeta loop. The Sdp family of proteins are F-BAR and SH3 domain containing proteins. Inmmunocytochemical experiments showed that SdpI as well as the isoforms SdpII-S and SdpIIL colocalize with the full-length GlyRbeta subunit in a mammalian cell expression system. In cultured spinal cord neurons, a partial colocalization of endogenous SdpI with several excitatory and inhibitory synaptic markers was demonstrated. Mapping experiments using deletion mutants narrowed the SdpI binding site down to 22 amino acids. Peptide competition experiments confirmed the specificity of the interaction between SdpI and this sequence of the GlyRbeta subunit. Point mutation analysis revealed a SH3-proline rich domain dependent interaction between SdpI and the GlyRbeta subunit, respectively. In addition, binding studies in mammalian cells showed that both splice variants of SdpII as well as SdpI interact with the GlyR scaffolding protein gephyrin. Although the SdpI and gephyrin binding sites do not overlap, protein competition studies revealed that interaction of the E-domain of gephyrin with the GlyRbeta loop interferes with SdpI binding. Since SdpI is a dynamin binding protein involved in vesicle endocytosis and recycling pathways, a possible function of SdpI in the regulation of GlyR synaptic distribution was investigated. Co-immunoprecipitation experiments confirmed a SdpI-GlyR association in the vesicle-enriched fraction of rat spinal cord tissue. Immunocytochemical studies of SdpI knock out mice showed that the clustering and distribution of GlyRs in the brain stem is unchanged. However, acute down-regulation of SdpI in rat spinal cord neurons by viral shRNA expression led to a reduction in the number and size of GlyR clusters, an effect that could be rescued upon shRNA-resistant SdpI overexpression. Further immunocytochemical analysis of the localization of gephyrin, the gamma2 subunit of the type A gamma-aminobutyric acid receptor (GABAARgamma2 subunit) and the vesicular inhibitory amino acid transporter (VIAAT) under SdpI knock-down conditions showed that both the number and average size of the gamma2-subunit containing GABAA receptor clusters were significantly reduced in spinal cord neurons. In contrast to GlyR and GABAARgamma2 immunoreactivity, the number and average size of gephyrin and VIAAT clusters were barely reduced upon SdpI downregulation. These results suggest that SdpI has a role in GlyR trafficking that can be compensated by other syndapin isoforms or other trafficking pathways. Furthermore, SdpI might be required for the clusters of GlyRs and gamma2-subunit containing GABAARs in spinal cord and brainstem. Vps35 is the core protein of the retromer complex, which mediates the endosome to Golgi apparatus retrieval of different types of receptors in mammals and yeast. Here, protein-protein interaction assays revealed for the first time that Vps35 interacts directly with the GlyRbeta loop as well as with gephyrin. The generation of specific Vps35 antibodies allowed to determine the distribution of this protein in the central nervous system. Immunocytochemical analyses revealed the presence of Vps35 in the somata and neurites of spinal cord neurons, suggesting a possible interaction of Vps35 with the GlyR under physiological conditions. Nbea is a BEACH domain containing, neuron-specific protein. Binding studies revealed a direct interaction between two regions of Nbea and the GlyRbeta loop. Immunocytochemical experiments confirmed a somatic and synaptic distribution of Nbea in primary cultures. In spinal cord neurons, a partial colocalization of Nbea with excitatory and inhibitory synaptic markers suggests a possible interaction of Nbea with the GlyR at inhibitory synaptic sites.
European pea crabs - taxonomy, morphology, and host-ecology (Crustacea: Brachyura: Pinnotheridae)
(2010)
Pinnotherids are small crabs symbiotic to a variety of invertebrates. The European species infest bivalves and sea squirts. Their way of life is parasitic and poses a threat to commercially exploited bivalves. While juveniles of both sexes still look very similar - being agile swimmers and partially free living - a metamorphosis takes place in the female after mating and results in a conspicuous sexual dimorphism. Thereafter, the female settles in its host definitely and is morphologically strongly adapted to the parasitic life phase. A very high reproductive output was demonstrated among several pea crab species infesting bivalves. Despite from that, hardly any information is present in the literature on the pinnotherids’ reproductive biology and the underlying morphology.
Due to their cryptic way of life, the sexual dimorphism, and the different morphotypes of the female, the taxonomy of the Pinnotheridae is a serious challenge. Two widely accepted species are recognized on European coasts: Pinnotheres pisum and Nepinnotheres pinnotheres. Pinnotheres pectunculi was so far only known from the bivalve Glycymeris glycymeris in its type locality Roscoff (France), while Pinnotheres ascidicola and Pinnotheres marioni were described as living exclusively in ascidians without careful comparison with the previously described species. In order to produce standardized comparative descriptions, pea crabs were collected and studied from different hosts and localities in the Northeast Atlantic and in the Mediterranean. Nepinnotheres pinnotheres and Pinnotheres pisum were redescribed with consideration to characters of female and male. According to our morphological analysis, Pinnotheres ascidicola and Pinnotheres marioni are junior synonyms of Nepinnotheres pinnotheres, whereas the status of Pinnotheres pectunculi as a valid species was ascertained. Important characters are the mouthparts, the male gonopods, and especially chelipeds that showed consistent characteristics among different crab stages of both sexes.
Based on our sampling, we estimated the host-range of the European species. Nepinnotheres pinnotheres lives in ascidians and in the pen shell Pinna nobilis. Pinnotheres pisum infests numerous bivalve species - Pinna nobilis included. For Pinnotheres pectunculi novel host records are presented, all from the bivalve family Veneridae. Furthermore, feeding of the Pinnotheres-species was observed. They use a setae comb ventrally on the claw to brush mucus (and the accumulated food particles) from the bivalve gills. Feeding strategies and host-ecology will be thoroughly discussed in consideration to other Pinnotheridae.
We investigated the reproductive systems of European pinnotherids by histological methods, scanning and transmission electron microscopy, and confocal laser scanning microscopy.
The Eubrachyura have internal fertilization: paired vaginas enlarge into storage structures, the spermathecae, which are connected to the ovaries by oviducts. Sperm is stored until the oocytes are mature and transported into the spermathecae, where fertilization takes place. In the investigated pinnotherids, the vagina is of the ‘concave pattern’. Musculature is attached alongside flexible parts of the vagina-wall to control the dimension of its lumen. The genital opening is closed by a muscular mobile operculum.
The spermatheca can be divided into two distinct regions by function and morphology. The ventral part includes the connection with vagina and oviduct and is regarded as the zone where fertilization takes place. It is lined with cuticle except where the oviduct enters the spermatheca by the ‘holocrine transfer tissue’. At ovulation, the oocytes have to pass through this multi-layered glandular epithelium, which has a holocrine mode secretion. The dorsal part of the spermatheca is lined by a highly secretory apocrine glandular epithelium, which was to date only found in fiddler crabs of the genus Uca.
The male internal reproductive system consists of paired testes and corresponding vasa deferentia. The sperm morphology of pinnotherids conforms to other thoracotremes, with slight differences between Nepinnotheres pinnotheres and Pinnotheres pisum. Spermatozoa become enveloped into spermatophores in the secretory proximal vas deferens. The medial vas deferens is strongly enlarged and stores spermatophores embedded in seminal plasma. The distal vas deferens holds tubular appendices, which extend into the ventral cephalothorax and slightly into the pleon. These appendices produce and store vast quantities of seminal plasma. The copulatory system of the Brachyura is formed by paired penes and two pairs of gonopods, which function in sperm transfer. In pinnotherids, the long first gonopods transfers the sperm mass to the female. It holds the ejaculatory canal inside, which opens proximally and distally. The second gonopod is solid, short and conical. During copulation, the penis and the second gonopod are inserted into the base of the tubular first gonopod. The second gonopod functions in the transport of the sperm mass inside the ejaculatory canal towards its distal opening. The specific shape of the second gonopod is strongly adapted for a sealing of the tubular first gonopod with longitudinal cuticle foldings that interlock inside the first gonopod. The presented results are discussed concerning their function in reproduction and in respect of the systematic account.
The role of secretion in sperm transfer, storage and fertilization among the Brachyura is still under debate. It is notable that structure and function of secretion are more complex in pinnotherids and probably more efficient than in other brachyuran crabs, which will be discussed, in view of the parasitic way of life and the high fecundity of pinnotherids.