Rôle de l'Annexine-A5 dans la réparation membranaire du muscle strié squelettique et du placenta humains / Role of Annexin-A5 in cell membrane repair in human skeletal muscle and placenta

Carmeille, Romain

27 November 2015

La membrane plasmique est un assemblage supramoléculaire qui délimite la cellule. C’est une structure fine, complexe et dynamique assurant des fonctions multiples et vitales pour la cellule. Sa rupture est un évènement physiologique pour les cellules soumises à des stress mécaniques fréquents et/ou importants, comme les cellules épithéliales, les cellules endothéliales ou les cellules musculaires. Dans des conditions physiopathologiques, la membrane plasmique peut également être endommagée par l’insertion de toxines bactériennes formant des pores (PFTs, pour « pore forming toxins »). Le processus de réparation membranaire et la machinerie protéique associée sont encore mal connus. Connaître les partenaires protéiques et comprendre les mécanismes mis en jeu durant le processus de réparation de la membrane plasmique sont deux enjeux fondamentaux majeurs. En effet, il a été établi qu’une défaillance du processus de réparation membranaire pour les fibres musculaires est la cause principale de certaines dystrophies musculaires. La machinerie protéique de réparation comprend des protéines comme la dysferline, la cavéoline-3 et certaines Annexines (Anx). Les Anx appartiennent à une superfamille de protéines répandue chez la plupart des eucaryotes, qui ont la propriété commune de se lier aux membranes biologiques en présence de calcium (Ca2+). Certaines Anx, comme l’AnxA5, une fois liées aux membranes biologiques s’auto-assemblent spontanément en réseau-2D. Lors de ce travail de thèse, nous avons étudié le rôle de l’AnxA5 dans la réparation membranaire des trophoblastes placentaires et des cellules du muscle squelettique humain. Pour les deux types cellulaires, nous avons montré que l’AnxA5 est un acteur indispensable du processus de réparation membranaire dans le cas de ruptures mécaniques. En associant des approches de microscopie de fluorescence et de microscopie électronique à transmission (MET), nous avons mis en évidence que dans ces cellules, le mécanisme de réparation est principalement basé sur la formation d’un « patch » lipidique. Dans les cellules musculaires, les expériences de MET ont mis en évidence qu’un pool d’AnxA5 endogène se lie aux bords du site de rupture quelques secondes après la lésion du sarcolemme. Ceci suggère qu’après rupture de la membrane plasmique, l’augmentation locale de la concentration calcique intracellulaire provoque la liaison de l’AnxA5 spécifiquement aux bords de la région membranaire lésée où elle forme un réseau-2D. Le réseau-2D stabiliserait localement la membrane et préviendrait sa déchirure, induite par les forces de tensions exercées par le cytosquelette cortical. Nous avons également montré que l’AnxA5 ne semble pas impliquée dans la réparation de la membrane plasmique après insertion de PFTs. Ceci suggère que différents mécanismes de réparation existent et que leur mise en place dépend probablement du type ou de l’importance des dommages. Finalement nous avons étendu notre étude à des lignées cellulaires établies à partir de patients diagnostiqués comme souffrant de dystrophies des ceintures de type 2B (déficience en dysferline) et 1C (déficience en cavéoline-3), respectivement. Nous avons montré, pour ces lignées, que la déficience en dysferline ou cavéoline-3 provoque un défaut de réparation dans le cas des ruptures mécaniques de la membrane plasmique. Dans ces cellules musculaires pathologiques intactes ou endommagées, l’AnxA5 a le même comportement, ce qui suggère que l’action de l’AnxA5 est indépendante de ces protéines. A la différence des cellules déficientes en dysferline, nous avons observé que les cellules déficientes en cavéoline-3 sont capables de réparer efficacement des lésions créées par l’insertion de PFTs dans le sarcolemme. Ce résultat supporte l’hypothèse de l’existence de plusieurs mécanismes de réparation. En conclusion, ce travail montre que l’AnxA5 est un composant clé de la machinerie de réparation dans le cas des ruptures mécaniques. / Plasma membrane is the supramolecular assembly that delimits the cell. It is a thin, dynamic and complex structure, ensuring multiple and vital cell functions. Its disruption is a physiological event occurring in cells submitted to frequent mechanical stresses, such as endothelial cells, epithelial cells and muscle cells. It is also a physiological event for cells exposed to pore forming bacterial toxins (PFTs). Membrane repair mechanisms and associated protein machinery are still poorly understood. This knowledge is, however, essential for obvious physiopathological issues. Indeed, a defect of membrane repair in muscle cells leads to some muscular dystrophies. Membrane repair machinery includes proteins such as dysferlin, MG-53, caveolin-3 and some Annexins (Anx). Anx belong to a superfamily of proteins widely spread in most of eukaryotes, which share the property of binding to biological membranes in the presence of calcium (Ca2+). Here, we investigated the role of AnxA5 in cell membrane repair of human trophoblastic and skeletal muscle cells. We showed that AnxA5 is required for membrane repair of mechanical damages in the two cell types. By combining fluorescence and transmission electron microscopy approaches, we evidenced that membrane repair mechanism in these cells is based on the formation of a lipid “patch”. In human muscle cells, TEM experiments revealed that a pool of endogenous AnxA5 binds to the edges of the torn sarcolemma as soon as a few seconds after membrane disruption. Our results suggest the following mechanism: triggered by the local increase in Ca2+ concentration, AnxA5 molecules bind to PS exposed at the edges of the torn membrane, where they self-assemble into 2D arrays. The formation of 2D arrays strengthens the damaged sarcolemma, counteracts the tensions exerted by the cortical cytoskeleton and thus prevents the expansion of the tear. We showed also that a pool of endogenous AnxA5 binds to intracellular vesicles that obstruct the wounding site. It is likely these vesicles, once associated one to each other, ensure membrane resealing. Our results suggest that sarcolemma repair of damages caused by PFTs is independent of AnxA5. Therefore, different membrane repair mechanisms may exist, their occurrence probably depending on the type and/or the size of damages. Finally, we performed studies on muscle cells established from patients diagnosed with limb girdle muscular dystrophies type 2B (dysferlin-deficient) and 1C (caveolin-3-deficient), respectively. We found that dysferlin or caveolin-3 deficiency leads to a defect of membrane repair, in the case of mechanical damages. AnxA5 behaved similarly in these damaged cells and wild-type cells, suggesting that its function is independent of dysferlin or caveolin-3. Unlike dysferlin-deficient cells, damages created by PFTs are efficiently repaired in caveolin- 3-deficient cells. This result supports the hypothesis that different mechanisms occur in muscle cells, depending on the type of damage. In conclusion, this work indicates that AnxA5 is a key component of the membrane repair machinery, in the case of mechanical disruptions. Our results enable to propose a detailed mode of action for AnxA5.

Annexine-A5

Réparation membranaire

Muscle strié squelettique humain

Trophoblastes humains

Dystrophies musculaires

Annexin-A5

Cell membrane repair

Human skeletal muscle

Human trophoblasts

Muscular dystrophies

Functional Differentiation Of The Human Placenta : Insights From The Expression Of Two Developmentally - Regulated Genes

Rao, M Rekha

11 1900

Placenta is a transient association of the fetal and maternal tissues, that develops during pregnancy, in most viviparous animals. The evolution of placenta ensured the development of the fetus inside the womb of the mother, providing a protected environment for the development of the fetus, and preventing the loss of progeny due to unfavorable environmental conditions. Because it is strategically poised at the maternal and fetal interface, the placenta is ideally suited to carry out alimentary, respiratory and excretory functions for the developing fetus. In addition, it serves as an immunological barrier preventing the rejection of the fetal semi-allograft, by the maternal immune system. Furthermore, the placenta elaborates a variety of protein, polypeptide and steroid hormones. These include growth factors, growth factor receptors, neuropeptides, opioids, progesterone and estrogen, whose secretion is dependent on the gestational age of the placenta and its differentiation status. The human placenta, adapts itself remarkably to cater to the changing requirements of the developing fetus. For instance, during the first trimester of pregnancy, the placenta is an actively dividing, a highly invasive and a rapidly differentiating organ; while near term, it represents a fully differentiated and a non-invasive unit. Furthermore, the placenta of the first trimester and that at term differ in their hormone profiles, extents of apoptosis, expression of several transcription factors, etc. This dramatic change in the phenotype of the human placenta can be considered to be the outcome of an intrinsically programmed pattern of differentiation, which may be referred to as the functional differentiation of the placenta. It may be hypothesized therefore, that this functional differentiation could be brought about by the differential expression of genes in the first trimester and the term placenta. The objectives of the present study were: 1. To gain an insight into this process of " functional differentiation” by investigating the differential expression of genes in the two developmentally distinct stages during gestation, viz. during the first trimester and at term. 2. To understand the functional relevance of the differentially expressed genes. A general introduction of the human placenta, describing the importance of differential expression in modulating placental function, is discussed in chapter 1. The functions of the human placenta along with a brief description of its development and differentiation are also briefly described. A Differential Display RT-PCR-based (DD RT-PCR) approach, using total RNA from the first-trimester and term placental villi, was employed to display the differentially expressed genes in the first trimester and the term placenta. The display so generated was used to identify a few differentially expressed cDNAs. This study was aimed at understanding the functional significance of the transcripts which were identified from the display, rather than just concentrate on documenting the differences in the gene expression patterns in the first trimester and the term placental tissue. A detailed description of the methodology adopted for performing DD-PCR using placental tissue, discussing the advantages and disadvantages of using differential display PCR, is described in chapter2. The use of DD-PCR for studying differential gene expression in the human placenta was validated by the finding that one of the cDNAs that was differentially expressed in the first trimester placental tissue, is a fragment of β-hCG cDNA. It is well documented that the differential expression of the β-subunit of hCG (human chorionic gondatrophin) during the first eight weeks of gestation is the rate limiting step in the synthesis and secretion of the functional hormone, which comprises the α and the β-subunits. Furthermore, the use of the model system viz., the first trimester and term placental tissue, was also validated for carrying out DD-PCR by ensuring that all placental samples used for DD analysis were free of endometrial contamination. A detailed description of optimization and validation of DD-PCR in human placental tissues is given in chapter 2. Cloning and sequencing of yet another cDNA from the first trimester differential display revealed that it is T-Plastin. T-Plastin is a member of a family of proteins that are involved in actin-bundling. Northern blot analysis and immunohistochemical studies using an antibody generated to a peptide corresponding to human T-Plastin, confirmed its differential expression and localization in the first trimester placenta. Considering the fact that several carcinomas show enhanced expression of T-Plastin, we tested the hypothesis that its differential expression is correlated with the proliferative potential of the first-trimester placenta It was observed that the first-trimester tissue expressed high levels of beta-actin as compared to the term placental tissue. This is in agreement with the up-regulation of beta-actin following mitogenic stimulation/proliferation and during neoplastic transformation or transformation-associated invasive behaviour of cells, two characteristic features shared by the early placenta with cancerous tissues. Based on our studies and available information in the literature, it is proposed that T-Plastin expression in the first trimester placenta is a growth-associated phenomenon which is partially responsible for the tumor-like phenotype of the first trimester tissue. Studies carried out with the partial T-Plastin cDNA clone that was isolated from the first trimester differential display, are presented in chapter 3. Sequencing of yet another cDNA clone identified from the term placental differential display, T-18 revealed that it had no homology to any known sequence in the nucleotide or est databases. The sequence corresponding to this clone was submitted to the GenBank and was assigned an accession number- AF089811. The differential expression of T-18 was confirmed by Northern blot analysis and RT-PCR analysis. Attempts were made to isolate the full-length cDNA corresponding to T-18 from a commercially available library from Clontech. However, repeated trials to identify the clone corresponding to T-18 did not yield any positive results. However, a genome database search revealed that T-18 was a portion of a large contig contained in chromosome 15. Analysis of the annotated gene sequences in and around the region in which T-18 is located in chromosome 15, revealed that there are very few ests reported in this contig and quite a few repeat sequences reported. Interestingly, it was observed that 6 kb downstream of the region in which T-18 is located, there was an est that had homology to a Bcl-2 precursor protein (an evolutionarily conserved, anti-apoptotic protein, capable of conferring protection against death-inducing signals) and the death adaptor protein, CRADD {Caspase and RIP adapter with death domain). Further updating of the ests in the database might probably be of help in the identification of the full-length cDNA corresponding to T-18 and confirm as to whether T-18 is a part of the gene/gene cluster that comprises the afore-mentioned est. An account of the identification and cloning of T-18 from the term placenta and the attempts to isolate the full-length cDNA clone corresponding to T-18 from a term placental cDNA library, is described in chapter 4. In the absence of any information on the identity of T-18, a study to understand the functional significance of T-18 expression was carried out. Since it was not possible to carry out studies pertaining to the temporal expression of T-18 throughout gestation on the human placenta for ethical reasons, alternate animal/organ models were employed to study T-18 expression. Rat placenta and rat Corpus Luteum (CL) were chosen as alternate models for studying T-18 expression as these two organs/tissues underwent dynamic changes in their function throughout pregnancy. For instance, it is well known that CL is the primary source of progesterone for maintaining pregnancy in the rat and that the progesterone secreting capacity of the luteal cells peak on day 16 of gestation and decline thereafter. Interestingly, a common feature among all the tissues that were chosen for investigating the regulation of T-18 expression, is the fact that they underwent apoptosis with increase in gestational age. The expression of T-18, in tissues exhibiting increased incidence of apoptosis suggested that T-18 maybe an apoptosis-associated gene. Using an explant culture model it was demonstrated that placental villi when cultured in vitro underwent spontaneous apoptosis and that the levels of T-18 message increased, under these conditions. Furthermore, this spontaneous induction of apoptosis in explant cultures could be blocked when villi were cultured in the presence of superoxide dismutase, a free radical scavenging enzyme. In addition, the expression of T-18 was shown to be modulated following treatment with SOD, or in response to oxidative stress. These studies clearly indicate a role for T-18 in placental apoptosis and moreover, implicate the usefulness of explant culture to examine the molecular mechanisms involved in placental apoptosis. Furthermore, the expression of the anti- and pro-apoptotic genes, bcl-x and bax respectively, were investigated, in an attempt to elucidate the signalling pathway(s) that led to the activation of an important downstream protease, caspase-3, in placental apoptosis. The present study revealed that induction of apoptosis in the placenta in vitro involved a bcl/bax independent, caspase-3 dependant pathway. The validation of an explant culture model for studying placental apoptosis and data pertaining to the role of T-18, bcl-x, bax and CPP32 in placental apoptosis, in response to oxidative stress, are presented in chapter 5. The last section titled general discussion summarizes the work carried out in this study and proposes a model for the apoptotic mechanism(s) that may be operating in placenta In conclusion, the present study has led to the identification of two developmentally-regulated factors, T-Plastin and T-18 in the first trimester and term placenta, respectively. The differential expression of these genes, in addition to several other molecular players, is proposed to be responsible for the overall functional differentiation of the placenta through the course of gestation.

Human Physiology

Placenta

Human Placental Syncytiotrophoblasts

Trophoblast Differentiation

Placental Protein

Human Placental Growth

Human Trophoblasts

T-Plastin

T-18

Placental Apoptosis

Novel Gene