62 resultados para Gastrulation
Resumo:
神经嵴(neural crest)是一类脊椎动物特有的多潜能迁移细胞。这一类细胞历经“表皮—间充质”转换(EMT),与神经管背侧的其它细胞分离,经由不同路线迁移,定位于胚胎外周各处,后分化为不同的细胞类型包括外周神经系统、颅面骨骼系统及色素细胞等。神经嵴的发育是一个多途径多步骤的过程,受多种信号通路及转录因子调控。这些调控因子相互调节形成精密网络,可被划分为三个主要层次类群:分泌性信号分子(BMP、Wnt、FGF、Delta)、神经板边界特异基因(Msx、Pax3/7、 Zic1、Dlx3/5)、神经嵴特异基因(Snail/Slug、AP-2、FoxD3、Twist、Id、cMyc、Sox9/10)。本文第一章主要概述不同组织来源的各种分泌信号在神经嵴诱导中的作用以及他们之间的整合调控。 Nkx6家族蛋白是一类进化上保守的转录因子,在脊椎动物中枢神经系统(CNS)的图式形成和胰腺的发育中有重要作用。在第二章,我们描述了非洲爪蟾中Nkx6家族基因的克隆及其表达图式。与小鼠和鸡中的同源基因类似,爪蟾的Nkx6家族基因在胚胎发育过程中主要表达于中枢神经系统和前部内胚层组织。其中Nkx6.1和Nkx6.2在神经胚期神经板表达重合,晚期都表达于后脑和脊髓的腹侧。Nkx6.3从卵裂期到神经胚早期都表达于非神经外胚层,而尾芽期表达于后脑后部和腮弓。在内胚层中,Nkx6.2在尾芽期表达于底索。在蝌蚪期,Nkx6家族的三个基因分别表达于前部内胚层的衍生物,包括胰腺、胃、食道和肺。 Nkx6.3是最近发现的Nkx6家族新成员,它在爪蟾中的表达与Nkx6.1和Nkx6.2有了较大分歧。在第三章,我们通过功能获得及功能缺失实验来探讨Nkx6.3在爪蟾早期发育中的功能。我们发现原肠期前过量或抑制Nkx6.3表达都会影响胚胎原肠运动的正常进行。我们通过动物帽延伸实验证明Nkx6.3参与了细胞运动。半定量RT-PCR结果显示,Nkx6.3可以调控一些粘附分子的表达。以上结果说明Nkx6.3通过调控粘附分子的转录而参与细胞运动的调控。我们还发神经嵴(neural crest)是一类脊椎动物特有的多潜能迁移细胞。这一类细胞历经“表皮—间充质”转换(EMT),与神经管背侧的其它细胞分离,经由不同路线迁移,定位于胚胎外周各处,后分化为不同的细胞类型包括外周神经系统、颅面骨骼系统及色素细胞等。神经嵴的发育是一个多途径多步骤的过程,受多种信号通路及转录因子调控。这些调控因子相互调节形成精密网络,可被划分为三个主要层次类群:分泌性信号分子(BMP、Wnt、FGF、Delta)、神经板边界特异基因(Msx、Pax3/7、 Zic1、Dlx3/5)、神经嵴特异基因(Snail/Slug、AP-2、FoxD3、Twist、Id、cMyc、Sox9/10)。本文第一章主要概述不同组织来源的各种分泌信号在神经嵴诱导中的作用以及他们之间的整合调控。 Nkx6家族蛋白是一类进化上保守的转录因子,在脊椎动物中枢神经系统(CNS)的图式形成和胰腺的发育中有重要作用。在第二章,我们描述了非洲爪蟾中Nkx6家族基因的克隆及其表达图式。与小鼠和鸡中的同源基因类似,爪蟾的Nkx6家族基因在胚胎发育过程中主要表达于中枢神经系统和前部内胚层组织。其中Nkx6.1和Nkx6.2在神经胚期神经板表达重合,晚期都表达于后脑和脊髓的腹侧。Nkx6.3从卵裂期到神经胚早期都表达于非神经外胚层,而尾芽期表达于后脑后部和腮弓。在内胚层中,Nkx6.2在尾芽期表达于底索。在蝌蚪期,Nkx6家族的三个基因分别表达于前部内胚层的衍生物,包括胰腺、胃、食道和肺。 Nkx6.3是最近发现的Nkx6家族新成员,它在爪蟾中的表达与Nkx6.1和Nkx6.2有了较大分歧。在第三章,我们通过功能获得及功能缺失实验来探讨Nkx6.3在爪蟾早期发育中的功能。我们发现原肠期前过量或抑制Nkx6.3表达都会影响胚胎原肠运动的正常进行。我们通过动物帽延伸实验证明Nkx6.3参与了细胞运动。半定量RT-PCR结果显示,Nkx6.3可以调控一些粘附分子的表达。以上结果说明Nkx6.3通过调控粘附分子的转录而参与细胞运动的调控。我们还发现,在爪蟾胚胎中Nkx6.3的过表达或抑制表达都导致神经嵴标记基因表达降低。进一步研究发现,32细胞期在不同部位注射Nkx6.3 mRNA可以异位诱导或抑制Slug的表达。动物帽实验显示,Nkx6.3单独过表达可以诱导神经嵴发生,而迄今为止转录因子中只有Snail1具有这一单独诱导能力。在爪蟾胚胎及动物帽中,过表达Nkx6.3都可以诱导Fgf8、Wnt8而抑制BMP4的转录,而且Nkx6.3对这些分泌因子的调控方式是不同的。4细胞期过表达Nkx6.3的胚胎,在促进Fgf8和Wnt8而抑制BMP4的同时,却抑制神经板边界特异基因Msx1、Pax3和神经嵴特异基因Slug的表达,说明Nkx6.3对神经嵴的诱导调控在神经板边界基因层次还存在抑制作用。32细胞过表达Nkx6.3会细胞自主性抑制以及细胞非自主诱导Msx1、Pax3、Slug的表达。Nkx6.3异位诱导Dlx5却抑制Dlx3的表达,说明Dlx5可能是Nkx6.3负调控的直接靶基因。由此,我们提出Nkx6.3的神经嵴诱导调控分为两个层次:分泌信号分子水平的正调控和神经板边界决定水平的负调控。在脊椎动物的神经发生过程中,神经管背腹不同层次形成不同的神经元。这些神经元细胞的命运由背腹起源的多种形态发生素决定。形态发生素通过浓度梯度确定了一组转录因子在神经管背腹不同层次的特异表达,这些基因的组合调控决定了神经前体细胞的命运。然而,这些转录因子是如何解读形态发生素梯度信号的还不是很清楚。第四章,我们通过对神经管腹侧特异表达的转录因子的调控区进行预测,确定了可能调控这些基因表达的保守区段。此外,我们改进了爪蟾转基因操作,并用这一技术确证了Nkx6.2的调控区域。Dbx1、Nkx2.2及Pax6的转录调控区已在小鼠或爪蟾中报道过。由此我们得到了两对在神经管背腹图式中相互作用的转录因子的调控区域:Nkx6.2和Dbx1、Nkx2.2和Pax6。通过对Nkx6.2和Dbx1的调控保守区的转录因子结合位点的预测,我们发现这四个基因以及Wnt信号之间存在大量的相互调控。然而在这两个基因的调控区,我们没有发现Gli的调控位点,暗示这两个基因可能不受Shh的直接调控。我们还克隆了Dbx家族的两个基因,并检测了它们的时空特异性表达,发现Dbx2是母源性表达的,而Dbx1是合子型基因。这两个基因的表达图式相似,都在神经板中线两侧成线状表达,尾芽期在神经管中部表达。过表达Dbx2抑制神经元的初级分化,说明它可能与Dbx1一样具有维持神经板细胞未分化状态的功能。Dbx2的过表达还抑制Nkx6.2及Dbx1的表达,说明它们可能一起参与了神经管腹侧图式的调控。
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Amphioxus Bblhx3 was identified as a LIM-homeobox gene expressed in gastrulae. Structural analysis suggested that it is a member of lhx3 but not of lhx1 gene group. Whole mount in situ hybridization revealed, that expression of Bblhx3 was initiated at the early gastrula stage and continued at least until 10-day larvae. Expression of Bblhx3 first appeared in the vegetal and future dorsal area in initial gastrulae and became restricted to the endoderm during gastrulation. In neurulae and early larvae, Bblhx3 was expressed in the developing neural tube, the notochord and preoral pit lineage. In 10-day larvae, Bblhx3 was expressed only in the preoral pit. This expression pattern is apparently distinct from that of vertebrate lhx3 genes that are not expressed during gastrulation. (C) 2002 Elsevier Science Ireland Ltd. All rights reserved.
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The lancelet (amphioxus) embryo develops from a miolecithal egg and starts gastrulation when it is approximately 400 cells in size, in a fashion similar to that of some non-chordate deuterostomes. Throughout this type of gastrulation, the embryo develops characteristics such as the notochord and hollow nerve cord that commonly appear in chordates. beta-Catenin is an important factor in initiating body patterning. The behavior and developmental pattern of this protein in early lancelet development was examined in this study. Cytoplasmic beta-catenin was localized to the animal pole after fertilization and then was incorporated asymmetrically into the blastomeres during the first cleavage. Asymmetric distribution was observed at least until the 32-cell stage. The first nuclear localization was at the 64-cell stage, and involved all of the cells. At the initial gastrula stage, however, concentrated beta-catenin was found on the dorsal side. LiCl treatment affected the asymmetric pattern of beta-catenin during the first cleavage. LiCl also changed distribution of nuclear beta-catenin at the initial gastrula stage: distribution extended to cells on the animal side. Apparently associated with this change, expression domains of goosecoid, lhx3 and otx also changed to a radially symmetric pattern centered at the animal pole. However, LiCl-treated embryos were able to establish embryonic polarity. The present study suggests that in the lancelet embryo, polarity determination is independent of dorsal morphogenesis.
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MSTN, also known as growth and differentiation factor 8 (GDF8), and GDF11 are members of the transforming growth factor-beta (TGF-beta) subfamily. They have been thought to be derived from one ancestral gene. In the present study, we report the isolation and characterization of an invertebrate GDF8/11 homolog from the amphioxus (Branchiostoma belcheri tsingtauense). The amphioxus GDF8/11 gene consists of five exons flanked by four introns, which have two more exons and introns than that of other species. In intron III, a possible transposable element was identified. This suggested that this intron might be derived from transposon. The amphioxus GDF8/11 cDNA encodes a polypeptide of 419 amino acid residues. Phologenetic analysis shows that the GDF8/11 is at the base of vertebrate MSTNs and GDF11s. This result might prove that the GDF8/11 derived from one ancestral gene and the amphioxus GDF8/11 may be the common ancestral gene, and also the gene duplication event generating MSTN and GDF11 occurred before the divergence of vertebrates and after or at the divergence of amphioxus from vertebrates. Reverse transcriptase polymerase chain reaction results showed that the GDF8/11 gene was expressed in new fertilized cell, early gastrulation, and knife-shaped embryo, which was different from that in mammals. It suggested that the GDF8/11 gene might possess additional functions other than regulating muscle growth in amphioxus.
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Marsupial mammals are born in an embryonic state, as compared with their eutherian counterparts, yet certain features are accelerated. The most conspicuous of these features are the precocial forelimbs, which the newborns use to climb unaided from the opening of the birth canal to the teat. The developmental mechanisms that produce this acceleration are unknown. Here we show that heterochronic and heterotopic changes early in limb development contribute to forelimb acceleration. Using Tbx5 and Tbx4 as fore- and hindlimb field markers, respectively, we have found that, compared with mouse, both limb fields arise notably early during opossum development. Patterning of the forelimb buds is also accelerated, as Shh expression appears early relative to the outgrowth of the bud itself. In addition, the forelimb fields and forelimb myocyte allocation are increased in size and number, respectively, and migration of the spinal nerves into the forelimb bud has been modified. This shift in the extent of the forelimb field is accompanied by shifts in Hox gene expression along the anterior-posterior axis. Furthermore, we found that both fore- and hindlimb fields arise gradually during gastrulation and extension of the embryonic axis, in contrast to the appearance of the limb fields in their entirety in all other known cases. Our results show a surprising evolutionary flexibility in the early limb development program of amniotes and rule out the induction of the limb fields by mature structures such as the somites or mesonephros.
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Bone morphogenetic proteins (BMPs) are secreted extracellular matrix (ECM)-associated proteins that regulate a wide range of developmental processes, including limb and kidney formation. A critical element of BMP regulation is the presence of secreted antagonists that bind and inhibit BMP binding to their cognate Ser/Thr kinase receptors at the plasma membrane. Antagonists such as Noggin, Chordin, Gremlin (Grem1), and twisted gastrulation-1 (Twsg1) have been shown to inhibit BMP action in a range of different cell types and developmental stage-specific contexts. Here we review new developments in the field of BMP and BMP antagonist biology during mammalian development and suggest strategies for targeting these proteins in human disease.
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Background: Interindividual epigenetic variation that occurs systemically must be established prior to gastrulation in the very early embryo and, because it is systemic, can be assessed in easily biopsiable tissues. We employ two independent genome-wide approaches to search for such variants.
Results: First, we screen for metastable epialleles by performing genomewide bisulfite sequencing in peripheral blood lymphocyte (PBL) and hair follicle DNA from two Caucasian adults. Second, we conduct a genomewide screen for genomic regions at which PBL DNA methylation is affected by season of conception in rural Gambia. Remarkably, both approaches identify the genomically imprinted VTRNA2-1 as a top environmentally responsive epiallele. We demonstrate systemic and stochastic interindividual variation in DNA methylation at the VTRNA2-1 differentially methylated region in healthy Caucasian and Asian adults and show, in rural Gambians, that periconceptional environment affects offspring VTRNA2-1 epigenotype, which is stable over at least 10 years. This unbiased screen also identifies over 100 additional candidate metastable epialleles, and shows that these are associated with cis genomic features including transposable elements.
Conclusions: The non-coding VTRNA2-1 transcript (also called nc886) is a putative tumor suppressor and modulator of innate immunity. Thus, these data indicating environmentally induced loss of imprinting at VTRNA2-1 constitute a plausible causal pathway linking early embryonic environment, epigenetic alteration, and human disease. More broadly, the list of candidate metastable epialleles provides a resource for future studies of epigenetic variation and human disease.
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La voie de la polarité planaire cellulaire (PCP), aussi connue sous le nom de la voie non-canonique du Frizzled/Dishevelled, contrôle le processus morphogénétique de l'extension convergente (CE) qui est essentiel pour la gastrulation et la formation du tube neural pendant l'embryogenèse. La signalisation du PCP a été récemment associée avec des anomalies du tube neural (ATN) dans des modèles animaux et chez l'humain. Prickle1 est une protéine centrale de la voie PCP, exprimée dans la ligne primitive et le mésoderme pendant l'embryogenèse de la souris. La perte ou le gain de fonction de Prickle1 mène à des mouvements de CE fautifs chez le poisson zèbre et la grenouille. PRICKLE1 interagit directement avec deux autres membres de la voie PCP, Dishevelled et Strabismus/Vang. Dans notre étude, nous avons investigué le rôle de PRICKLE1 dans l'étiologie des ATN dans une cohorte de 810 patients par le re-séquençage de son cadre de lecture et des jonctions exon-intron. Le potentiel pathogénique des mutations ainsi identifiées a été évalué par des méthodes bioinformatiques, suivi par une validation fonctionnelle in vivo dans un système poisson zèbre. Nous avons identifié dans notre cohorte un total de 9 nouvelles mutations dont sept: p.Ile69Thr, p.Asn81His, p.Thr275Met, p.Arg682Cys et p.Ser739Phe, p.Val550Met et p.Asp771Asn qui affectent des acides aminés conservés. Ces mutations ont été prédites in silico d’affecter la fonction de la protéine et sont absentes dans une large cohorte de contrôles de même origine ethnique. La co-injection de ces variantes avec le gène prickle1a de type sauvage chez l’embryon de poisson zèbre a démontré qu’une mutation, p.Arg682Cys, modifie dans un sens négatif le phénotype du défaut de la CE produit par pk1 de type sauvage. Notre étude démontre que PK1 peut agir comme facteur prédisposant pour les ATN chez l’humain et élargit encore plus nos connaissances sur le rôle des gènes de la PCP dans la pathogenèse de ces malformations.
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Les anomalies du tube neural (ATN), incluant l'anencéphalie et le spina-bifida, représentent un groupe de malformations congénitales très fréquentes chez l'homme. Ces anomalies sont causées par un défaut partiel ou complet de la fermeture du tube neurale au cours de l'embryogenèse. Les ATN ont une étiologie complexe et multifactorielle impliquant des facteurs environnementaux et génétiques. La voie de signalisation non-canonique du Frizzled (Fz)/Dishevelled (Dvl) contrôle la polarité cellulaire planaire (PCP) et le processus morphogénétique appelé l’extension convergente qui est essentiel pour la gastrulation et la fermeture du tube neural. Très important, des mutations des gènes de cette voie étaient fortement associées aux ATN chez la souris et l’humain. Scribble est un gène de la voie PCP qui cause une sévère ATN chez la souris Circletail. Notre étude vise à analyser le rôle de SCRIBBLE1 dans les ATN humains par des analyses de séquence de son cadre de lecture et ses jonctions exon-introns. Notre étude comporte 396 patients recrutés au Centre Spina Bifida de l’hôpital Gaslini en Gènes, Italie et 83 patients recrutés au Centre Spina Bifida de l’hôpital Sainte Justine. Les patients sont affectés par plusieurs formes d’ATN. Nous avons identifié neuf mutations rares et non synonymes chez 10 patients, p.Asp93Ala (c. 435G>A), p.Gly145Arg (c. 278A>C), p.Gly263Ser (c. 786C>A), p.Gly469Ser (c. 1405G>A), p.Pro649His (c. 1946C>A), p.Gln808His (c. 2424G>T), p.Val1066Met (c. 3196G>A), p.Arg1150Gln (c. 3480G>A) et p.Thr1422Met (c. 4266C>T). Cinque mutations, p.Gly263Ser, p.Pro649His, p.Gln808His, p.Arg1150Gln, p.Thr1422Met, étaient absentes dans les contrôles analysés et prédites d’être pathogéniques in silico. Cette étude montre que des mutations rares dans SCRIB1 pourraient augmenter le risque des ATN dans une fraction des patients. L’identification des gènes prédisposant aux ATN nous aidera à mieux comprendre les mécanismes pathogéniques impliqués dans ces maladies.
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Many aspects of early embryonic development in the horse are unusual or unique; this is of scientific interest and, in some cases, considerable practical significance. During early development the number of different cell types increases rapidly and the organization of these increasingly differentiated cells becomes increasingly intricate as a result of various inter-related processes that occur step-wise or simultaneously in different parts of the conceptus (i.e., the embryo proper and its associated membranes and fluid). Equine conceptus development is of practical interest for many reasons. Most significantly, following a high rate of successful fertilization (71-96%) (Ball, 1988), as many as 30-40% of developing embryos fail to survive beyond the first two weeks of gestation (Ball, 1988), the time at which gastrulation begins. Indeed, despite considerable progress in the development of treatments for common causes of sub-fertility and of assisted reproductive techniques to enhance reproductive efficiency, the need to monitor and rebreed mares that lose a pregnancy or the failure to produce a foal, remain sources of considerable economic loss to the equine breeding industry. Of course, the potential causes of early embryonic death are numerous and varied (e.g. persistent mating induced endometritis, endometrial gland insufficiency, cervical incompetence, corpus luteum (CL) failure, chromosomal, genetic and other unknown factors (LeBlanc, 2004). However, the problem is especially acute in aged mares with a history of poor fertility in which the incidence of embryonic loss between days 2 and 14 after ovulation has been reported to reach 62-73%, and in which embryonic death is due primarily to embryonic defects rather than to uterine pathology (Ball et al., 1989; Carnevale & Ginther, 1995; Ball, 2000).
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The vertebrate Zic gene family encodes C2H2 zinc finger transcription factors closely related to the Gli proteins. Zic genes are expressed in multiple areas of developing vertebrate embryos, including the dorsal neural tube where they act as potent neural crest inducers. Here we describe the characterization of a Zic ortholog from the amphioxus Branchiostoma floridae and further describe the expression of a Zic ortholog from the ascidian Ciona intestinalis. Molecular phylogenetic analysis and sequence comparisons suggest the gene duplications that formed the vertebrate Zic family were specific to the vertebrate lineage. In Ciona maternal CiZic/Ci-macho1 transcripts are localized during cleavage stages by asymmetric cell division, whereas zygotic expression by neural plate cells commences during neurulation. The amphioxus Zic ortholog AmphiZic is expressed in dorsal mesoderm and ectoderm during gastrulation, before being eliminated first from midline cells and then from all neurectoderm during neurulation. After neurulation, expression is reactivated in the dorsal neural tube and dorsolateral somite. Comparison of CiZic and AmphiZic expression with vertebrate Zic expression leads to two main conclusions. First, Zic expression allows us to define homologous compartments between vertebrate and amphioxus somites, showing primitive subdivision of vertebrate segmented mesoderm. Second, we show that neural Zic expression is a chordate synapomorphy, whereas the precise pattern of neural expression has evolved differently on the different chordate lineages. Based on these observations we suggest that a change in Zic regulation, specifically the evolution of a dorsal neural expression domain in vertebrate neurulae, was an important step in the evolution of the neural crest.
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Epithelial invagination in many model systems is driven by apical cell constriction, mediated by actin and myosin II contraction regulated by GTPase activity. Here we investigate apical constriction during chick lens placode invagination. Inhibition of actin polymerization and myosin II activity by cytochalasin D or blebbistatin prevents lens invagination. To further verify if lens placode invaginate through apical constriction, we analyzed the role of Rho-ROCK pathway. Rho GTPases expression at the apical portion of the lens placode occurs with the same dynamics as that of the cytoskeleton. Overexpression of the pan-Rho inhibitor C3 exotoxin abolished invagination and had a strong effect on apical myosin II enrichment and a mild effect on apical actin localization. In contrast, pharmacological inhibition of ROCK activity interfered significantly with apical enrichment of both actin and myosin. These results suggest that apical constriction in lens invagination involves ROCK but apical concentration of actin and myosin are regulated through different pathways upstream of ROCK. genesis 49: 368-379, 2011. (C) 2011 Wiley-Liss, Inc.
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Glypican-3 (GPC3) is a proteoglycan involved in migration, proliferation and cell survival modulation in several tissues. There are many reports demonstrating a downregulation of GPC3 expression in some human tumors, including mesothelioma, ovarian and breast cancer. Previously, we determined that GPC3 reexpression in the murine mammary adenocarcinoma LM3 cells induced an impairment of their in vivo invasive and metastatic capacities together with a higher susceptibility to in vitro apoptosis. Currently, the signaling mechanism of GPC3 is not clear. First, it was speculated that GPC3 regulates the insulin-like growth factor (IGF) signaling system. This hypothesis, however, has been strongly challenged. Recently, several reports indicated that at least in some cell types GPC3 serves as a selective regulator of Wnt signaling. Here we provide new data demonstrating that GPC3 regulates Wnt pathway in the metastatic adenocarcinoma mammary LM3 cell line. We found that GPC3 is able to inhibit canonical Wnt signals involved in cell proliferation and survival, as well as it is able to activate non canonical pathway, which directs cell morphology and migration. This is the first report indicating that breast tumor cell malignant properties can be reverted, at least in part, by GPC3 modulation of Wnt signaling. Our results are consistent with the potential role of GPC3 as a metastasis suppressor.
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Pós-graduação em Biologia Animal - IBILCE
Resumo:
Tetraspan vesicle membrane proteins (TVPs) sind ubiquitäre Komponenten von Transportvesikeln. Bei den Säugetieren unterscheidet man drei Familien, die Physine, Gyrine und SCAMPs (secretory carrier-associated membrane proteins). Ihre Funktion ist weitgehend unbekannt, es wird jedoch vermutet, dass sie eine Rolle bei der Vesikelbildung und der Vesikelrezirkulierung spielen. In Caenorhabditis elegans existiert von jeder Familie jeweils nur ein einziges Polypeptid: für die Physine Synaptophysin (SPH-1), für die Gyrine Synaptogyrin (SNG-1) und für die SCAMPs SCAMP (SCM-1). Ziel der Arbeit war es die Verteilung der C. elegans TVPs zu untersuchen und ihre Funktion unter besonderer Berücksichtigung der vesikelvermittelten synaptischen Kopplung zu bestimmen. Wenn die C. elegans TVPs in humanen Epithelzellen synthetisiert werden, lokalisieren sie in zytoplasmatischen Vesikeln. In Kotransfektionsexperimenten wurde gezeigt, dass sie größtenteils in den gleichen Strukturen enthalten sind. In C. elegans synthetisierte TVP-Reporterkonstrukte können in unterschiedlichen Geweben nachgewiesen werden. Dabei ist SNG-1 fast ausschließlich in Neuronen zu finden. SPH-1 und SCM-1 hingegen weisen komplexe und teilweise überlappende Verteilungsmuster auf. Während für SPH-1 eine starke Fluoreszenz im Pharynx, auf der apikalen Seite der Darmzellen oberhalb des sog. terminal webs und in adluminalen Regionen von exkretorischen Geweben gefunden wurde, war SCM-1 stark in der Muskulatur und den Coelomozyten vertreten. Die Expression von SCM-1 in Pharynx und Darm war deutlich schwächer. Die C. elegans TVPs werden früh in der Entwicklung ab der Gastrulation (SPH-1 und SCM-1) bzw. ab der Neurulation im sog. Komma-Stadium (SNG-1) produziert. Um die Funktion der TVPs in C. elegans zu untersuchen, wurden TVP-Mutanten analysiert. Durch Kombination aller drei TVP-Gen-Mutanten wurden TVP-Dreifachmutanten generiert. Diese wiesen keinen offensichtlichen Defekt im Bewegungsmuster auf, entwickelten sich normal und bildeten ein normales Nervensystem aus. Auch auf unterschiedliche chemische und physikalische Reize in sensorischen Tests reagierten die TVP-Dreifachmutanten in gleicher Weise wie Wildtyptiere. Ebenso zeigen die TVP-Dreifachmutanten elektrophysiologisch unter normalen Bedingungen keine anormalen Reaktionsmuster. In ultrastrukturellen Untersuchungen wurde lediglich eine signifikant erhöhte Anzahl Clathrin-ummantelter Vesikel in cholinergen Synapsen gefunden. Erst unter Stressbedingungen, hervorgerufen durch den GABA-Antagonisten Pentylentetrazol (PTZ), wiesen sowohl die TVP-Dreifach- als auch die TVP-Einzelmutanten eine deutlich erhöhte Krampfbereitschaft auf. Zusammengenommen zeigen die Analysen, dass TVPs zwar für grundlegende neuronale Prozesse nicht notwendig sind, dass sie aber auf der anderen Seite vermutlich an alternativen redundanten Wegen der Neurotransmitterfreisetzung beteiligt sind.
