967 resultados para Maltose-binding Protein Htlv-1 Gp21 Chimera
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Abstract Introduction The primary function of the contractile vascular smooth muscle cells (cVSMCs) is the regulation of the vascular contractility which means the adaptation of the vascular tonus in response to the modulation of the blood pressure and blood flow. The cVSMCs are essentially quiescent, and therefore their synthesis rate is very limited. They are characterized by the expression of contractile proteins specific to the muscular tissue including myosin, h-‐caldesmon and <-‐smooth muscle actin (〈-‐SMA). These contractile cells are strongly represented in the media layer of the arterial wall and, in a smaller proportion, of the vein wall. Their typical stretched-‐out morphology allows recognizing them by a histological analysis. They do not produce any extracellular matrix (ECM), and do not migrate through the different layers of the vessel wall, and are not directly involved in the development of intimal hyperplasia (IH). Neointimal formation occurs after endothelial disruption leading to complex molecular and biological mechanisms. The de-‐differentiation of cVSMCs into synthetic VSMCs (sVSMCs) is mentioned as a key element. These non mature cells are able to proliferate and produce ECM. The characterization of the vascular smooth muscle cells (VSMCs) from healthy and stenosed vascular tissues will contribue to the understanding of the different biological processes leading to IH and will be useful for the development of new therapies to interfere with the cVSMCs growth and migration. The aim of our research was to quantify the proportion of cVSMCs and sVSMCs into the healthy and pathologic human blood vessel wall and to characterize their phenotype. Methods We selected 23 specimens of arterial and venous segments from 18 patients. All these specimens were stored in the biobank from the thoracic and vascular surgery departement. 4 groups were designed (group 1 :arteries without lesions (n=3) ;group 2 : veins without lesions (n=1); group 3: arteries with stenosis (n=9); group 4: veins with stenosis (n=10)). Histology: 5µm-‐sections were made from each sample embedded in paraffin wax and further stained with hematoxylin & eosin (HE), Van Gieson's stain (VGEL) and Masson's Trichrome (TMB). Pathologic tissues were defined using the label that was given to the macroscopic samples by the surgeon and also, based on the histological analysis with HE and VGEL evaluating the presence of a thickened intima. The same was done to the control samples evaluating the absence of thickening. Immunohistochemistry : The primary antibodies were used :〈-‐SMA, vimentin, h-‐ caldesmon, calponin, smooth muscle-myosin heavy chain (SM-‐MHC), tropomyosin-‐4, retinol binding protein-‐1 (RBP-‐1), nonmuscle-‐myosin heavy chain-‐B (NM-‐MHC-‐B), Von Willebrand factor (VWF). A semi-‐quantitative assessment of the intensity of each sample stained was performed. Western Blot : Segments of arteries and veins were analyzed using the following primary antibodies :〈-‐SMA, Calponin, SM-‐MHC, NM-‐MHC-‐B. The given results were then normalized with tubulin. Results Our data showed that, when using immunohistochemistry analysis we found that〈-‐SMA was mostly expressed in control arteries, whereas NM-‐MHC-‐B in the pathologic ones. Using SM-‐MHC, calponin, vimentin and caldesmon we found no significative differences in the expression of these proteins in the control and in the pathologic samples. Western Blot analysis showed an inverse correlation between healthy and pathological samples as <-‐ SMA was more expressed in the pathological samples, while NM-‐MHC-‐B in the control group; SM-‐MHC and calponin were mostly expressed in the pathologic samples. Conclusion Our study showed no clear differences between stenotic and control arterial and venous segments using semi-‐quantitative assessement by immunohistochemistry. Western Blot showed a significant increased expression of 〈-‐SMA, calponin and SM-‐MHC in the arteries with stenosis, while NM-‐MHC-‐B was mostly expressed in the arteries without lesions. Further studies are needed to track the lineage of VSMCs to understand the mechanisms leading toIH.
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SUMMARY: Iron is an essential element for nearly all organisms but it is poorly available in most environments and not sufficient to support microbial growth. Bacteria have evolved a range of strategies to acquire this important metal, the most common of these being siderophore-mediated iron uptake. Siderophores are high-affinity iron chelators which are released to the extracellular environment where they complex iron and deliver it to the bacterial cell, via specific uptake systems. The Gram-negative bacterium Pseudomonas aeruginosa produces two siderophores, pyoverdine and pyochelin, which both contribute to the virulence of this opportunistic human pathogen. The genes responsible for pyochelin-mediated iron uptake are grouped in the P. aeruginosa chromosome. The pyochelin biosynthetic genes are organized in two divergent operons, pchDCBA and pchEFGHI, which flank the regulatory gene pchR. The fptA gene, encoding the ferric pyochelin outer membrane receptor, occurs immediately downstream of the pchEFGHI genes. The biosynthesis of the siderophore and its receptor is subjected to dual regulation enabling P. aeruginosa to respond not only to the intracellular iron level but also to the presence of the siderophore in the extracellular environment. Negative regulation is mediated by the widespread Fur protein which employs ferrous iron as a corepressor and binds to a consensus sequence in the promoter region of iron-regulated genes. Positive regulation occurs during iron starvation and requires the AraC-type transcriptional regulator PchR. This regulator, together with pyochelin, induces the expression of pyochelin biosynthesis and uptake genes via a mechanism which was partly unraveled during this thesis. A 32-bp conserved sequence element (PchR-box) was identified in promoter regions of pyochelin-controlled genes. The PchR-box in the pchR-pchDCBA intergenic region was found to be essential for the induction of the pchDCBA operon and for the repression of the divergently transcribed pchR gene. PchR was purified as a fusion with maltose-binding protein (MBP). Mobility shift assays demonstrated specific binding of MBP-PchR to the PchR-box in the presence, but not in the absence of pyochelin. PchR-box mutations which interfered with pyochelin-dependent regulation in vivo, also affected pyochelin-dependent PchR-box recognition in vitro. These results show that pyochelin is the intracellular effector required for PchR-mediated regulation. The fact that extracellular pyochelin triggers this regulation implies that the siderophore can enter the cytoplasm. This conclusion was corroborated by analysing the importance of known and putative pyochelin uptake genes for pyochelin-dependent gene regulation. The pyochelin receptor gene fptA is followed by three genes, fptB, fptC, and fptX, which were shown here to be co-transcribed with fPtA. While fPtX encodes an inner membrane pen-I-lease, the functions of FptB and FptC are currently unknown. FptA and FptX, which are both required for pyochelin-mediated iron uptake, were found to be also needed for pyochelin-dependent gene regulation. FptB and FptC however, were not required and their role, if any, in the uptake of the PchR effector pyochelin remains elusive. RESUME Le fer est un élément essentiel pour la quasi-totalité des organismes, mais dans la plupart des environnements, il est difficilement accessible et insuffisant à la croissance microbienne. Les bactéries ont développé de multiples stratégies pour acquérir ce précieux métal, la plus commune étant l'acquisition au moyen de sidérophores. Les sidérophores sont des petites molécules dotées d'une forte affinité pour le fer qui, une fois relâchées dans l'environnement extracellulaire, vont complexer le fer et le délivrer à la cellule bactérienne par l'intermédiaire de systèmes d'acquisition spécifiques. La bactérie Gram-négative Pseudomonas aeruginosa produit deux sidérophores, la pyoverdine et la pyochéline, qui contribuent également à la virulence de ce pathogène opportuniste. Les gènes impliqués dans l'acquisition du fer à l'aide de la pyochéline sont regroupés sur t. le chromosome de P. aeruginosa. Les gènes de biosynthèse de la pyochéline sont organisés en deux opérons divergents, pchDCBA et pchEFGHI, qui flanquent le gène régulateur pchR. Le gène fptA, codant pour le récepteur de la pyochéline dans la membrane externe, est situé immédiatement en aval des gènes pchEFGHL La biosynthèse du sidérophore et de son récepteur est soumise à une double régulation permettant à P. aeruginosa de réagir non seulement à la quantité de fer intracellulaire, mais également à la présence du sidérophore dans le milieu extracellulaire. La répression se fait par l'intermédiaire de la protéine Fur, qui nécessite le fer ferreux comme co-répresseur et se lie à une séquence consensus dans la région promotrice des gènes régulés par le fer. L'induction se produit lorsque le fer est limitant, et requiert PchR, un régulateur transcriptionnel de la famille AraC. En présence de pyochéline, ce régulateur induit l'expression des gènes de biosynthèse et du récepteur de la pyochéline par l'intermédiaire d'un mécanisme partiellement résolu dans ce travail. Une séquence conservée (PchR-box) a été identifiée dans la région promotrice des gènes régulés par la pyochéline. La PchR-box située dans la région intergénique pchR-pchDCBA s'est révélée être importante pour l'induction de l'opéron pchDCBA et la répression du gène divergent pchR. PchR a été purifiée en tant que protéine de fusion avec une protéine liant le maltose (MBP). Des expériences de gel retard ont démontré la liaison spécifique de la protéine MBP-PchR sur la PchR-box en présence, mais non en absence de pyochéline. Les mutations de la PchR-box qui ont affecté la régulation pyochéline-dépendante in vivo, ont également eu un effet sur la liaison de la protéine in vitro. Ces résultats démontrent que la pyochéline est l'effecteur intracellulaire nécessaire à la régulation par PchR. Le fait que la pyochéline extracellulaire soit capable d'activer cette régulation implique que le sidérophore entre dans le cytoplasme. Cette conclusion a été corroborée par l'évaluation du rôle des gènes connus ou putatifs de l'incorporation du fer via la pyochéline sur la régulation pyochéline-dépendente. Le gène fPtA, codant pour le récepteur de la pyochéline, est suivi de trois gènes, fptB,fptC, et fptX, co-transcrits avec,ffitA. Si sffitX code pour une perméase de la membrane interne, la fonction de FptB et FptC reste obscure. FptA et FptX, nécessaires à l'acquisition du fer par l'intermédiaire de la pyochéline, se sont également révélés être requis pour la régulation pyochéline-dépendante des gènes pchDCBA, pchEFGHI et fptABCX. FptB et FptC n'ont quant à eux vraisemblablement pas de rôle majeur à jouer, si ce n'est aucun, dans l'incorporation de la pyochéline.
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The ability to regulate specific genes of energy metabolism in response to fasting and feeding is an important adaptation allowing survival of intermittent food supplies. However, little is known about transcription factors involved in such responses in higher organisms. We show here that gene expression in adipose tissue for adipocyte determination differentiation dependent factor (ADD) 1/sterol regulatory element binding protein (SREBP) 1, a basic-helix-loop-helix protein that has a dual DNA-binding specificity, is reduced dramatically upon fasting and elevated upon refeeding; this parallels closely the regulation of two adipose cell genes that are crucial in energy homeostasis, fatty acid synthetase (FAS) and leptin. This elevation of ADD1/SREBP1, leptin, and FAS that is induced by feeding in vivo is mimicked by exposure of cultured adipocytes to insulin, the classic hormone of the fed state. We also show that the promoters for both leptin and FAS are transactivated by ADD1/SREBP1. A mutation in the basic domain of ADD1/SREBP1 that allows E-box binding but destroys sterol regulatory element-1 binding prevents leptin gene transactivation but has no effect on the increase in FAS promoter function. Molecular dissection of the FAS promoter shows that most if not all of this action of ADD1/SREBP1 is through an E-box motif at -64 to -59, contained with a sequence identified previously as the major insulin response element of this gene. These results indicate that ADD1/SREBP1 is a key transcription factor linking changes in nutritional status and insulin levels to the expression of certain genes that regulate systemic energy metabolism.
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Under iron limitation, the opportunistic human pathogen Pseudomonas aeruginosa produces the siderophore pyochelin. When secreted into the extracellular environment, pyochelin complexes ferric ions and delivers them, via the outer membrane receptor FptA, to the bacterial cytoplasm. Extracellular pyochelin also acts as a signalling molecule, inducing the expression of pyochelin biosynthesis and uptake genes by a mechanism involving the AraC-type regulator PchR. We have identified a 32 bp conserved sequence element (PchR-box) in promoter regions of pyochelin-controlled genes and we show that the PchR-box in the pchR-pchDCBA intergenic region is essential for the induction of the pyochelin biosynthetic operon pchDCBA and the repression of the divergently transcribed pchR gene. PchR was purified as a fusion with maltose-binding protein (MBP). Mobility shift assays demonstrated specific binding of MBP-PchR to the PchR-box in the presence, but not in the absence of pyochelin and iron. PchR-box mutations that interfered with pyochelin-dependent regulation in vivo, also affected pyochelin-dependent PchR-box recognition in vitro. We conclude that pyochelin, probably in its iron-loaded state, is the intracellular effector required for PchR-mediated regulation. The fact that extracellular pyochelin triggers this regulation suggests that the siderophore can enter the cytoplasm.
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Abstract : The principal focus of this work was to study the molecular changes leading to the development of diabetic peripheral neuropathy (DPN). DPN is the most common complication associated with both type I and II diabetes mellitus (DM). This pathology is the leading cause of non-traumatic amputations. Even though the pathological and morphological changes underlying DPN are relatively well described, the implicated molecular mechanisms remain poorly understood. The following two approaches were developed to study the development of DPN in a rodent model of DM type I. As a first approach, we studied the implication of lipid metabolism in DPN phenotype, concentrating on Sterol Response Element Binding Protein (SREBP)-lc which is the key regulator of storage lipid metabolism. We showed that SREBP-1c was expressed in peripheral nerves and that its expression profile followed the expression of genes involved in storage lipid metabolism. In addition, the expression of SREBP-1c in the endoneurium of peripheral nerves was dependant upon nutritional status and this expression was also perturbed in type I diabetes. In line with this, we showed that insulin elevated the expression of SREBP-1c in primary cultured Schwann cells by activating the SREBP-1c promoter. Taken together, these findings reveal that SREBP-1c expression in Schwann cells responds to metabolic stimuli including insulin and that this response is affected in type I diabetes mellitus. This suggests that disturbed SREBP-1c regulated lipid metabolism may contribute to the pathophysiology of DPN. As a second approach, we performed a comprehensive analysis of the molecular changes associated with DPN in the Akital~1~+ mouse which is a model of spontaneous early-onset type I diabetes mellitus. This mouse expresses a mutated non-functional isoform of insulin, leading to hypoinsulinemia and hyperglycaemia. To determine the onset of DPN, weight, blood glucose and motor nerve conduction velocity (MNCV) were measured in Akital+/+ mice during the first three months of life. A decrease in MNCV was evident akeady one week after the onset of hyperglycemia. To explore the molecular changes associated with the development of DPN in these mice, we performed gene expression profiling using sciatic nerve endoneurium and dorsal root ganglia (DRG) isolated from early diabetic male Akita+/+ mice and sex-matched littermate controls. No major transcriptional changes were detected either in the DRG or in the sciatic nerve endoneurium. This experiment indicates that the phenotypic changes observed during the development of DPN are not correlated with major transcriptional alterations, but mainly with alterations at the protein level. Résumé Lors ce travail, nous nous sommes intéressés aux changements moléculaires aboutissant aux neuropathies périphériques dues au diabète (NPD). Les NPD sont la complication la plus commune du diabète de type I et de type II. Cette pathologie est une cause majeure d'amputations. Même si les changements pathologiques et morphologiques associés aux NPD sont relativement bien décrits, les mécanismes moléculaires provoquant cette pathologie sont mal connus. Deux approches ont principalement été utilisées pour étudier le développement des NPD dans des modèles murins du diabète de type I. Nous avons d'abord étudié l'impact du métabolisme des lipides sur le développement des NPD en nous concentrant sur Sterol Response Element Binding Protein (SREBP)-1 c qui est un régulateur clé des lipides de stockage. Nous avons montré que SREBP-1 c est exprimé dans les nerfs périphériques et que son profil d'expression suit celui de gènes impliqués dans le métabolisme des lipides de stockage. De plus, l'expression de SREBP-1c dans l'endoneurium des nerfs périphériques est dépendante du statut nutritionnel et est dérégulée lors de diabète de type I. Nous avons également pu montrer que l'insuline augmente l'expression de SREBP-1c dans des cultures primaires de cellules de Schwann en activant le promoteur de SREBP-1c. Ses résultats démontrent que l'expression de SREBP-1c dans les cellules de Schwann est contrôlée par des stimuli métaboliques comme l'insuline et que cette réponse est affectée dans le cas d'un diabète de type I. Ces données suggèrent que la dérégulation de l'expression de SREBP-1c lors du diabète pourrait affecter le métabolisme des lipides et ainsi contribuer à la pathophysiologie des NPD. Comme seconde approche, nous avons réalisé une analyse globale des changements moléculaires associés au développement des NPD chez les souris Akita+/+, un modèle de diabète de type I. Cette souris exprime une forme mutée et non fonctionnelle de l'insuline provoquant une hypoinsulinémie et une hyperglycémie. Afin de déterminer le début du développement de la NPD, le poids, le niveau de glucose sanguin et la vitesse de conduction nerveuse (VCN) ont été mesurés durant les 3 premiers mois de vie. Une diminution de la VCN a été détectée une semaine seulement après le développement de l'hyperglycémie. Pour explorer les changements moléculaires associés avec le développement des NPD, nous avons réalisé un profil d'expression de l'endoneurium du nerf sciatique et des ganglions spinaux isolés à partir de souris Akital+/+ et de souris contrôles Akita+/+. Aucune altération transcriptionnelle majeure n'a été détectée dans nos échantillons. Cette expérience suggère que les changements phénotypiques observés durant le développement des NPD ne sont pas corrélés avec des changements importants au niveau transcriptionnel, mais plutôt avec des altérations au niveau protéique. Résumé : Lors ce travail, nous nous sommes intéressés aux changements moléculaires aboutissant aux neuropathies périphériques dues au diabète (NPD). Les NPD sont la complication la plus commune du diabète de type I et de type II. Cette pathologie est une cause majeure d'amputations. Même si les changements pathologiques et morphologiques associés aux NPD sont relativement bien décrits, les mécanismes moléculaires provoquant cette pathologie sont mal connus. Deux approches ont principalement été utilisées pour étudier le développement des NPD dans des modèles murins du diabète de type I. Nous avons d'abord étudié l'impact du métabolisme des lipides sur le développement des NPD en nous concentrant sur Sterol Response Element Binding Protein (SREBP)-1c qui est un régulateur clé des lipides de stockage. Nous avons montré que SREBP-1 c est exprimé dans les nerfs périphériques et que son profil d'expression suit celui de gènes impliqués dans le métabolisme des lipides de stockage. De plus, l'expression de SREBP-1c dans l'endoneurium des nerfs périphériques est dépendante du statut nutritionnel et est dérégulée lors de diabète de type I. Nous avons également pu montrer que l'insuline augmente l'expression de SREBP-1c dans des cultures primaires de cellules de Schwann en activant le promoteur de SREBP-1c. Ses résultats démontrent que l'expression de SREBP-1c dans les cellules de Schwann est contrôlée par des stimuli métaboliques comme l'insuline et que cette réponse est affectée dans le cas d'un diabète de type I. Ces données suggèrent que la dérégulation de l'expression de SREBP-1c lors du diabète pourrait affecter le métabolisme des lipides et ainsi contribuer à la pathophysiologie des NPD. Comme seconde approche, nous avons réalisé une analyse globale des changements moléculaires associés au développement des NPD chez les souris Akita~~Z~+, un modèle de diabète de type I. Cette souris exprime une forme mutée et non fonctionnelle de l'insuline provoquant une hypoinsulinémie et une hyperglycémie. Afin de déterminer le début du développement de la NPD, le poids, le niveau de glucose sanguin et la vitesse de conduction nerveuse (VCN) ont été mesurés durant les 3 premiers mois de vie. Une diminution de la VCN a été détectée une semaine seulement après le développement de l'hyperglycémie. Pour explorer les changements moléculaires associés avec le développement des NPD, nous avons réalisé un profil d'expression de l'endoneurium du nerf sciatique et des ganglions spinaux isolés à partir de souris Akital+/+ et de souris contrôles Akita+/+. Aucune altération transcriptionnelle majeure n'a été détectée dans nos échantillons. Cette expérience suggère que les changements phénotypiques observés durant le développement des NPD ne sont pas corrélés avec des changements importants au niveau transcriptionnel, mais plutôt avec des altérations au niveau protéique.
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Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.
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Während der Spermatogenese von Drosophila werden viele mRNAs zwar vor der Meiose transkribiert, dann aber durch Komplexbildung mit Proteinen stillgelegt und erst am Ende der Spermienentwicklung durch Veränderung desselben für die Translation freigegeben. Ein Beispiel hierfür ist die Mst87F mRNA. Während das cis-agierende Sequenzelement in der RNA seit langem bekannt ist, gestaltete sich die Suche nach den trans-agierenden RNA-bindenden Proteinen schwierig. In meiner Diplomarbeit (Stinski, 2007) waren mithilfe von präparativen Shift-Experimenten (Auftrennung von RNP-Komplexen im elektrischen Feld) zwei vielversprechende Kandidaten identifiziert worden, die Proteine Exuperantia (Exu) und Purity of Essence (Poe). Ziel der vorliegenden Dissertation war zum einen die Aufklärung der Funktion dieser Kandidatenproteine und zum anderen die Identifizierung weiterer Kandidaten, die an der Komplexbildung und damit an der Regulation beteiligt sind. Dabei war die Hoffnung, sowohl Proteine zu finden, die die Repression vermitteln, als auch solche, die am Ende die Aktivierung ermöglichen. Durch eine Affinitätsreinigung, in der Mst87F-RNA mit einem ms2-Tag versehen über das MS2-Maltose binding protein an eine Amylose-Matrix gebunden und schließlich die Komplexe mit Maltose wieder eluiert wurden, ließen sich erneut das Exu-Protein und drei neue Kandidaten identifizieren: CG3213, CG12470 und CG1898. Das Protein Exu hat eindeutig eine Funktion bei der Translationskontrolle: seine Abwesenheit führt zum Abbau der kontrollierten mRNAs. Die Inkubation mit exu-defizientem Protein-Extrakt (aus Hoden) unterstützt keine RNP-Komplexbildung und aufgereinigtes Exu-His Fusionsprotein kann auch nicht direkt an die Mst87F mRNA binden. Ein exu-defizienter Proteinextrakt lässt sich aber durch die Zugabe von rekombinantem Exu-His komplettieren und es entsteht wieder ein starker mRNP-Komplex. Dies beweist, dass das Experiment im Prinzip korrekt verläuft und dass Exu für die Komplexbildung entscheidend ist. Darüber hinaus konnten durch eine Co-Immunpräzipitation mit dem Exu-GFP Fusionsprotein sowohl interagierende Proteine als auch in die RNP-Komplexe einbezogene mRNAs nachgewiesen werden. Vielversprechende Kandidatenproteine stammen von den Genen CG3213, dfmr1 und CG12470. Die durch cDNA-Synthese in den Komplexen nachgewiesenen mRNAs sind in aller Regel solche, die der Translationskontrolle unterworfen sind. Damit ist gezeigt, dass Exu Teil eines großen Proteinkomplexes ist oder zumindest mit ihm assoziiert ist, der auf viele translationskontrollierte Transkripte Einfluss nimmt. Die Mst87F mRNA wird zum Zeitpunkt der Translationsaktivierung sekundär polyadenyliert, das heißt ihre Länge wird größer und heterogen. In einer Mutante für das Kandidatengen poe wurde diese sekundäre Polyadenylierung plötzlich nicht mehr beobachtet und die RNA blieb auch bei Translationsaktivierung so groß wie in den frühen Stadien. So ergab sich die Möglichkeit, endlich zu prüfen, ob die sekundäre Polyadenylierung für die Translationsaktivierung von essentieller Bedeutung ist. Eine Serie von Fusionskonstrukten mit funktionstüchtigem TCE verhielten sich alle gleich. Die sekundäre Polyadenylierung fand nicht statt, aber das Transkript des Fusionsgens wurde zum richtigen Zeitpunkt translatiert. Somit ist dieser Prozess zumindest nicht generell für eine Translation zu diesem späten Zeitpunkt in der Spermiogenese notwendig. Ein quantitativer Effekt kann allerdings nicht ausgeschlossen werden. Des Weiteren konnten mit antisense Konstrukten mutante Phänotypen erzeugt werden. Solche Männchen waren ausnahmslos steril, was die Wichtigkeit des Proteins Poe für den Prozess der Spermienreifung belegt. Die Defekte zeigen sich spät während der Individualisierung, was mit der vermuteten Funktion übereinstimmen würde. Das Kandidatenprotein dFMR1 bindet allein an die Mst87F RNA und trägt zur Stärke des beobachtbaren Komplexes bei. Die Komplexbildung zeigt Salzabhängigkeit, wie sie für dFMR1 in anderen Zusammenhängen dokumentiert wurde. Dies unterstützt die obige Aussage und suggeriert, dass dFMR1 die Basis für den Komplexaufbau bildet. Das CPEB-homologe Kandidatenprotein Orb2 bindet ebenfalls allein an die Mst87F mRNA, hat aber keinen Einfluss auf die Repression oder die sekundäre Polyadenylierung. Eine Beteiligung an der Regulation wäre demnach eindeutig unterschiedlich zu der in anderen Fällen dokumentierten Rolle. Die Expression der Kandidatengene CG1898, CG3213 und CG12470 ist konform mit einer unterschiedlichen Beteiligung an der Translationskontrolle. Das erste Protein ist nur in prämeiotischen Stadien, das zweite durchgängig und das dritte nur in postmeiotischen Stadien nachzuweisen, was einer Funktion bei der Stillegung, während der gesamten inaktiven Phase bzw. bei der Aktivierung entsprechen könnte. Die verschiedenen Experimente identifizieren in mehreren Fällen die gleichen Kandidatenproteine und untermauern damit deren Bedeutung. Sie lassen vielfach konkrete Schlüsse auf die Art der Interaktionen zu, welche in einem Schema zusammengefasst werden.
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The expression of proteins using recombinant baculoviruses is a mature and widely used technology. However, some aspects of the technology continue to detract from high throughput use and the basis of the final observed expression level is poorly understood. Here, we describe the design and use of a set of vectors developed around a unified cloning strategy that allow parallel expression of target proteins in the baculovirus system as N-terminal or C-terminal fusions. Using several protein kinases as tests we found that amino-terminal fusion to maltose binding protein rescued expression of the poorly expressed human kinase Cot but had only a marginal effect on expression of a well-expressed kinase IKK-2. In addition, MBP fusion proteins were found to be secreted from the expressing cell. Use of a carboxyl-terminal GFP tagging vector showed that fluorescence measurement paralleled expression level and was a convenient readout in the context of insect cell expression, an observation that was further supported with additional non-kinase targets. The expression of the target proteins using the same vectors in vitro showed that differences in expression level were wholly dependent on the environment of the expressing cell and an investigation of the time course of expression showed it could affect substantially the observed expression level for poorly but not well-expressed proteins. Our vector suite approach shows that rapid expression survey can be achieved within the baculovirus system and in addition, goes some way to identifying the underlying basis of the expression level obtained. (c) 2006 Elsevier Inc. All rights reserved.
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Oculopharyngeal muscular dystrophy (OPMD) is an adult-onset disorder characterized by ptosis, dysphagia and proximal limb weakness. Autosomal-dominant OPMD is caused by a short (GCG)8–13 expansions within the first exon of the poly(A)-binding protein nuclear 1 gene (PABPN1), leading to an expanded polyalanine tract in the mutated protein. Expanded PABPN1 forms insoluble aggregates in the nuclei of skeletal muscle fibres. In order to gain insight into the different physiological processes affected in OPMD muscles, we have used a transgenic mouse model of OPMD (A17.1) and performed transcriptomic studies combined with a detailed phenotypic characterization of this model at three time points. The transcriptomic analysis revealed a massive gene deregulation in the A17.1 mice, among which we identified a significant deregulation of pathways associated with muscle atrophy. Using a mathematical model for progression, we have identified that one-third of the progressive genes were also associated with muscle atrophy. Functional and histological analysis of the skeletal muscle of this mouse model confirmed a severe and progressive muscular atrophy associated with a reduction in muscle strength. Moreover, muscle atrophy in the A17.1 mice was restricted to fast glycolytic fibres, containing a large number of intranuclear inclusions (INIs). The soleus muscle and, in particular, oxidative fibres were spared, even though they contained INIs albeit to a lesser degree. These results demonstrate a fibre-type specificity of muscle atrophy in this OPMD model. This study improves our understanding of the biological pathways modified in OPMD to identify potential biomarkers and new therapeutic targets.
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The AFN1 gene is transiently expressed in germinating oat grains. As AFN1 is not expressed in dormant oat grains during imbibition, we hypothesize that AFN1 may be involved in stimulating the germination process. Sequence analysis of an AFN1 cDNA clone indicates that the AFN1 polypeptide is similar to a previously identified abscisic acid (ABA) glucosyl transferase. This suggests that AFN1 may be acting to glucosylate ABA, thereby inactivating it. As the hormone ABA is known to inhibit germination, ABA glucosylation/inactivation could lead to germination in grains expressing AFN1. To test this hypothesis, we have constructed an expression plasmid that encodes an MBP::AFN1 (maltose binding protein) fusion protein. E. coli cells carrying the expression plasmid were found to produce the MBP::AFN1 fusion protein as a substantial fraction of total protein. We are currently in the process of purifying the MBP::AFN1 fusion protein by affinity chromatography, so that it can be assayed for ABA glucosyl transferase activity. We also wish to test the effect of AFN1 gene expression during grain imbibition on the germination behavior of the grains. To this end, we have constructed plasmids for the overexpression and RNAi-based suppression of AFN1 in transgenic plants. These plasmids have been introduced into oat cells by particle bombardment and we are in the process of regenerating transgenic plants for study.
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The quassinoid analogue NBT-272 has been reported to inhibit MYC, thus warranting a further effort 7to better understand its preclinical properties in models of embryonal tumors (ET), a family of childhood malignancies sharing relevant biological and genetic features such as deregulated expression of MYC oncogenes. In our study, NBT-272 displayed a strong antiproliferative activity in vitro that resulted from the combination of diverse biological effects, ranging from G(1)/S arrest of the cell cycle to apoptosis and autophagy. The compound prevented the full activation of both eukaryotic translation initiation factor 4E (eIF4E) and its binding protein 4EBP-1, regulating cap-dependent protein translation. Interestingly, all responses induced by NBT-272 in ET could be attributed to interference with 2 main proproliferative signaling pathways, that is, the AKT and the MEK/extracellular signal-regulated kinase pathways. These findings also suggested that the depleting effect of NBT-272 on MYC protein expression occurred via indirect mechanisms, rather than selective inhibition. Finally, the ability of NBT-272 to arrest tumor growth in a xenograft model of neuroblastoma plays a role in the strong antitumor activity of this compound, both in vitro and in vivo, with its potential to target cell-survival pathways that are relevant for the development and progression of ET.
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The human insulin gene enhancer-binding protein islet-1 (ISL1) is a transcription factor involved in the differentiation of the neuroendocrine pancreatic cells. Recent studies identified ISL1 as a marker for pancreatic well-differentiated neuroendocrine neoplasms. However, little is known about ISL1 expression in pancreatic poorly differentiated and in extrapancreatic well and poorly differentiated neuroendocrine neoplasms. We studied the immunohistochemical expression of ISL1 in 124 neuroendocrine neoplasms. Among pancreatic neuroendocrine neoplasms, 12/13 with poor differentiation were negative, whereas 5/7 with good differentiation but a Ki67 >20% were positive. In extrapancreatic neuroendocrine neoplasms, strong positivity was found in Merkel cell carcinomas (25/25), pulmonary small cell neuroendocrine carcinomas (21/23), medullary thyroid carcinomas (9/9), paragangliomas/pheochromocytomas (6/6), adrenal neuroblastomas (8/8) and head and neck neuroendocrine carcinomas (4/5), whereas no or only weak staining was recorded in pulmonary carcinoids (3/15), olfactory neuroblastomas (1/4) and basaloid head and neck squamous cell carcinomas (0/15). ISL1 stained the neuroendocrine carcinoma component of 5/8 composite carcinomas and also normal neuroendocrine cells in the thyroid, adrenal medulla, stomach and colorectum. Poorly differentiated neuroendocrine neoplasms, regardless of their ISL1 expression, were usually TP53 positive. Our results show the almost ubiquitous expression of ISL1 in extrapancreatic poorly differentiated neuroendocrine neoplasms and neuroblastic malignancies and its common loss in pancreatic poorly differentiated neuroendocrine neoplasms. These findings modify the role of ISL1 as a marker for pancreatic neuroendocrine neoplasms and suggest that ISL1 has a broader involvement in differentiation and growth of neuroendocrine neoplasms than has so far been assumed.
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Previous studies have demonstrated that presecretory proteins such as maltose binding protein (MBP) and outer membrane protein A (OmpA) are targeted to the Escherichia coli inner membrane by the molecular chaperone SecB, but that integral membrane proteins are targeted by the signal recognition particle (SRP). In vitro studies have suggested that trigger factor binds to a sequence near the N terminus of the mature region of OmpA and shunts the protein into the SecB pathway by blocking an interaction between SRP and the signal peptide. By contrast, we have found that the targeting pathway of a protein under physiological conditions is dictated by the composition of its targeting signal. Replacement of the MBP or OmpA signal peptide with the first transmembrane segment of AcrB abolished the dependence on SecB for transport and rerouted both proteins into the SRP targeting pathway. More modest alterations of the MBP signal peptide that simply increase its hydrophobicity also promoted SRP binding. Furthermore, we obtained evidence that SRP has a low affinity for typical signal peptides in vivo. These results imply that different classes of E. coli proteins are targeted by distinct pathways because bacterial SRP binds to a more restricted range of targeting signals than its eukaryotic counterpart.
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We describe the construction of a soluble protein carrying the N-terminal extracellular domain (ECD) of the α7 subunit of the nicotinic acetylcholine receptor. The approach was to fuse the α7 ECD at the C and N termini of several monomeric and pentameric soluble carrier proteins and to investigate the soluble expression of the product in Escherichia coli. An initial screening of six carrier proteins resulted in the selection of a fusion protein comprising, from the N to the C terminus, the maltose binding protein, a 17-aa linker containing an enterokinase binding site, and the α7 ECD. This protein is soluble upon expression in bacteria and is purified by affinity chromatography. It binds the competitive nicotinic antagonist α-bungarotoxin with 2.5 μM affinity and displays a CD spectrum corresponding to a folded protein. The method might be suitable to produce large quantities of protein for crystallization and immunochemical experiments.
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The assembly of functional proteins from fragments in vivo has been recently described for several proteins, including the secreted maltose binding protein in Escherichia coli. Here we demonstrate for the first time that split gene products can function within the eukaryotic secretory system. Saccharomyces cerevisiae strains able to use sucrose produce the enzyme invertase, which is targeted by a signal peptide to the central secretory pathway and the periplasmic space. Using this enzyme as a model we find the following: (i) Polypeptide fragments of invertase, each containing a signal peptide, are independently translocated into the endoplasmic reticulum (ER) are modified by glycosylation, and travel the entire secretory pathway reaching the yeast periplasm. (ii) Simultaneous expression of independently translated and translocated overlapping fragments of invertase leads to the formation of an enzymatically active complex, whereas individually expressed fragments exhibit no activity. (iii) An active invertase complex is assembled in the ER, is targeted to the yeast periplasm, and is biologically functional, as judged by its ability to facilitate growth on sucrose as a single carbon source. These observation are discussed in relation to protein folding and assembly in the ER and to the trafficking of proteins through the secretory pathway.
