SDF 1-alpha (CXCL12) triggers glutamate exocytosis from astrocytes on a millisecond time scale: Imaging analysis at the single-vesicle level with TIRF microscopy

Chemokines are small chemotactic molecules widely expressed throughout the central nervous system. A number of papers, during the past few years, have suggested that they have physiological functions in addition to their roles in neuroinflammatory diseases. In this context, the best evidence concerns the CXC-chemokine stromal cell-derived factor (SDF-1alpha or CXCL12) and its receptor CXCR4, whose signalling cascade is also implicated in the glutamate release process from astrocytes. Recently, astrocytic synaptic like microvesicles (SLMVs) that express vesicular glutamate transporters (VGLUTs) and are able to release glutamate by Ca(2+)-dependent regulated exocytosis, have been described both in tissue and in cultured astrocytes. Here, in order to elucidate whether SDF-1alpha/CXCR4 system can participate to the brain fast communication systems, we investigated whether the activation of CXCR4 receptor triggers glutamate exocytosis in astrocytes. By using total internal reflection (TIRF) microscopy and the membrane-fluorescent styryl dye FM4-64, we adapted an imaging methodology recently developed to measure exocytosis and recycling in synaptic terminals, and monitored the CXCR4-mediated exocytosis of SLMVs in astrocytes. We analyzed the co-localization of VGLUT with the FM dye at single-vesicle level, and observed the kinetics of the FM dye release during single fusion events. We found that the activation of CXCR4 receptors triggered a burst of exocytosis on a millisecond time scale that involved the release of Ca(2+) from internal stores. These results support the idea that astrocytes can respond to external stimuli and communicate with the neighboring cells via fast release of glutamate.

Calcium Microdomains Control Exo-Endocytosis of Synaptic-Like Microvesicles in Astrocytes

During the last decade, the discovery that astrocytes possess a nonelectrical form of excitability (Ca21-excitability) that leads to the release of chemical transmitters, an activity called ''gliotransmission'', indicates that these cells may have additional important roles in brain function. Elucidating the stimulus-secretion coupling leading to the exocytic release of chemical transmitters (such as glutamate, Bezzi et al., Nature Neurosci, 2004) may therefore clarify i) whether astrocytes represent in full a new class of secretory cells in the brain and ii) whether they can participate to the fast brain signaling in the brain. Here by using a recently developed approach for studying vesicle recycling dynamics at synapses (Voglmaier et al., Neuron, 2006; Balaji and Ryan, PNAS, 2007) combined with epifluorescence and total internal reflection fluorescence (TIRF) imaging, we investigated the spatiotemporal characteristics of stimulus-secretion coupling leading glutamate exocytosis of synaptic-like microvesicles (SLMVs) in astrocytes. We performed the analysis at both the whole-cell and single-vesicle levels providing the first system for comparing exo-endocytic processes in astrocytes with those in neurons. Both the time course and modalities of secretion in astrocytes present more similarities to neurons then previously expected. We found that 1. the G-protein-coupled receptor (GPCR)-evoked exocytosis reached the maximum on a ms time scale and that 2. ER tubuli formed sub-micrometer domains beneath the plasma membrane in close proximity to exocytic vesicles, where fusion events were spatiotemporally correlated with fast Ca21 events.

Tumor-host interactions Part 1: Stromal signatures of breast and prostate cancer Part 2: GLG1 and the control of the secretory pathway in tumor cells

Tumor-host interaction is a key determinant during cancer progression, from primary tumor growth to metastatic dissemination. At each step, tumor cells have to adapt to and subvert different types of microenvironment, leading to major phenotypic and genotypic alterations that affect both tumor and surrounding stromal compartments. Understanding the molecular mechanisms that govern tumor-host interplay may be essential for better comprehension of tumorigenesis in an effort to improve current anti-cancer therapies. The present work is composed of two projects that address tumor-host interactions from two different perspectives, the first focusing on the characterization of tumor-associated stroma and the second on membrane trafficking in tumor cells. Part 1. To selectively address stromal gene expression changes during cancer progression, oligonucleotide-based Affymetrix microarray technology was used to analyze the transcriptomes of laser-microdissected stromal cells derived from invasive human breast and prostate carcinoma. Comparison showed that invasive breast and prostate cancer elicit distinct, tumor-specific stromal responses, with a limited panel of shared induced and/or repressed genes. Both breast and prostate tumor-specific deregulated stromal gene sets displayed statistically significant survival-predictive ability for their respective tumor type. By contrast, a stromal gene signature common to both tumor types did not display prognostic value, although expression of two individual genes within this common signature was found to be associated with patient survival. Part 2. GLG1 is known as an E-selectin ligand and an intracellular FGF receptor, depending on cell type and context. Immunohistochemical and immunofluorescence analyses showed that GLG1 is primarily localized in the Golgi of human tumor cells, a central location in the biosynthetic/secretory pathways. GLG1 has been shown to interact with and to recruit the ARF GEF BIGI to the Golgi membrane. Depletion of GLG1 or BIGI markedly reduced ARF3 membrane localization and activation, and altered the Golgi structure. Interestingly, these perturbations did not impair constitutive secretion in general, but rather seemed to impair secretion of a specific subset of proteins that includes MMP-9. Thus, GLG1 coordinates ARF3 activation by recruiting BIGI to the Golgi membrane, thereby affecting secretion of specific molecules. - Les interactions tumeur-hôte constituent un élément essentiel à la progression tumorale, de la croissance de la tumeur primaire à la dissémination des métastases. A chaque étape, les cellules tumorales doivent s'adapter à différents types de microenvironnement et les détourner à leur propre avantage, donnant lieu à des altérations phénotypiques et génotypiques majeures qui affectent aussi bien la tumeur elle-même que le compartiment stromal environnant. L'étude des mécanismes moléculaires qui régissent les interactions tumeur-hôte constitue une étape essentielle pour une meilleure compréhension du processus de tumorigenèse dans le but d'améliorer les thérapies anti cancer existantes. Le travail présenté ici est composé de deux projets qui abordent la problématique des interactions tumeur-hôte selon différentes perspectives, le premier se concentrant sur la caractérisation du stroma tumoral et le second sur le trafic intracellulaire des cellules tumorales. Partie 1. Pour examiner les changements d'expression des gènes dans le stroma en réponse à la progression du cancer, des puces à ADN Affymetrix ont été utilisées afin d'analyser les transcriptomes des cellules stromales issues de carcinomes invasifs du sein et de la prostate et collectées par microdissection au laser. L'analyse comparative a montré que les cancers invasifs du sein et de la prostate provoquent des réponses stromales spécifiques à chaque type de tumeur, et présentent peu de gènes induits ou réprimés de façon similaire. L'ensemble des gènes dérégulés dans le stroma associé au cancer du sein, ou à celui de la prostate, présente une valeur pronostique pour les patients atteints d'un cancer du sein, respectivement de la prostate. En revanche, la signature stromale commune aux deux types de cancer n'a aucune valeur prédictive, malgré le fait que l'expression de deux gènes présents dans cette liste soit liée à la survie des patients. Partie 2. GLG1 est connu comme un ligand des sélectines E ainsi que comme récepteur intracellulaire pour des facteurs de croissances FGFs selon le type de cellule dans lequel il est exprimé. Des analyses immunohistochimiques et d'immunofluorescence ont montré que dans les cellules tumorales, GLG1 est principalement localisé au niveau de l'appareil de Golgi, une place centrale dans la voie biosynthétique et sécrétoire. Nous avons montré que GLG1 interagit avec la protéine BIGI et participe à son recrutement à la membrane du Golgi. L'absence de GLG1 ou de BIGI réduit drastiquement le pool d'ARF3 associé aux membranes ainsi que la quantité d'ARF3 activés, et modifie la structure de l'appareil de Golgi. Il est particulièrement intéressant de constater que ces perturbations n'ont pas d'effet sur la sécrétion constitutive en général, mais semblent plutôt affecter la sécrétion spécifique d'un sous-groupe défini de protéines comprenant MMP-9. GLG1 coordonne donc l'activation de ARF3 en recrutant BIGI à la membrane du Golgi, agissant par ce moyen sur la sécrétion de molécules spécifiques.

Antigen binding to secretory immunoglobulin A results in decreased sensitivity to intestinal proteases and increased binding to cellular Fc receptors.

In intestinal secretions, secretory IgA (SIgA) plays an important sentinel and protective role in the recognition and clearance of enteric pathogens. In addition to serving as a first line of defense, SIgA and SIgA x antigen immune complexes are selectively transported across Peyer's patches to underlying dendritic cells in the mucosa-associated lymphoid tissue, contributing to immune surveillance and immunomodulation. To explain the unexpected transport of immune complexes in face of the large excess of free SIgA in secretions, we postulated that SIgA experiences structural modifications upon antigen binding. To address this issue, we associated specific polymeric IgA and SIgA with antigens of various sizes and complexity (protein toxin, virus, bacterium). Compared with free antibody, we found modified sensitivity of the three antigens assayed after exposure to proteases from intestinal washes. Antigen binding further impacted on the immunoreactivity toward polyclonal antisera specific for the heavy and light chains of the antibody, as a function of the antigen size. These conformational changes promoted binding of the SIgA-based immune complex compared with the free antibody to cellular receptors (Fc alphaRI and polymeric immunoglobulin receptor) expressed on the surface of premyelocytic and epithelial cell lines. These data reveal that antigen recognition by SIgA triggers structural changes that confer to the antibody enhanced receptor binding properties. This identifies immune complexes as particular structural entities integrating the presence of bound antigens and adds to the known function of immune exclusion and mucus anchoring by SIgA.

N-Glycans on secretory component: mediators of the interaction between secretory IgA and gram-positive commensals sustaining intestinal homeostasis.

Human beings live in symbiosis with billions of microorganisms colonizing mucosal surfaces. The understanding of the mechanisms underlying this fine-tuned intestinal balance has made significant processes during the last decades. We have recently demonstrated that the interaction of SIgA with Gram-positive bacteria is essentially based on Fab-independent, glycan-mediated recognition. Results obtained using mouse hybridoma- and colostrum-derived secretory IgA (SIgA) consistently show that N-glycans present on secretory component (SC) play a crucial role in the process. Natural coating may involve specific Gram-positive cell wall components, which may explain selective recognition at the molecular level. More widely, the existence of these complexes is involved in the modulation of intestinal epithelial cell (IEC) responses in vitro and the formation of intestinal biofilms. Thus, SIgA may act as one of the pillars in homeostatic maintenance of the microbiota in the gut, adding yet another facet to its multiple roles in the mucosal environment.

In vitro combination of human and bovine free secretory component with IgA of various species.

The free form of the secretory component usually associated with secretory IgA can be isolated from human and bovine milk. These free secretory components of different origin combine in vitro with human polymeric myeloma IgA, with mouse myeloma IgA, and with the serum IgA of nine different mammalian species.

Role of homer 1 proteins in the calcium signaling pathway(s) underlying exo-endocytosis processes of glutamatergic slmvs in astrocytes

The discovery that astrocytes possess a nonelectrical form of excitability (calcium excitability) that leads to the release of chemical transmitters, an activity called gliotransmission, indicates that these cells may have additional important roles in brain function. Elucidating the stimulussecretion coupling leading to the exocytic release of chemical transmitters (such as glutamate, Bezzi et al., Nature Neurosci, 2004) may therefore clarify i) whether astrocytes represent in full a new class of secretory cells in the brain and ii) whether they can participate to the fast brain signaling in the brain. We have recently discovered the existence in astrocytes of functional sub-membrane microdomains of calcium release from the internal stores in response to mGluR5 activation (Marchaland et al., J of Neurosci., 2008). Such sub-plasma membrane calcium microdomains control exocytosis of astrocytic glutamate signaling to neurons. Homer proteins are scaffold proteins controlling calcium signaling in different cellular microdomains, including dendritic spines in neurons (Sala et al., J of Neurosci., 2005). Thus, similarly to dendritic pines, Homer1 could be implicated in the coupling between astrocytic mGluR5 and IP3Rs on the ER. Here, by using a recently developed approach for studying vesicle recycling dynamics at synapses (Voglmaier et al., Neuron, 2006; Balaji and Ryan, PNAS, 2007) combined with epifluorescence and total internal reflection fluorescence (TIRF) imaging, we investigated the involvement of Homer1 proteins in the calcium dependent stimulus-secretion coupling leading glutamate exocytosis of synaptic-like microvesicles (SLMVs) in astrocytes.

Storage and uptake of D-serine into astrocytic synaptic-like vesicles specify gliotransmission.

Glial cells are increasingly recognized as active players that profoundly influence neuronal synaptic transmission by specialized signaling pathways. In particular, astrocytes have been shown recently to release small molecules, such as the amino acids l-glutamate and d-serine as "gliotransmitters," which directly control the efficacy of adjacent synapses. However, it is still controversial whether gliotransmitters are released from a cytosolic pool or by Ca(2+)-dependent exocytosis from secretory vesicles, i.e., by a mechanism similar to the release of synaptic vesicles in synapses. Here we report that rat cortical astrocytes contain storage vesicles that display morphological and biochemical features similar to neuronal synaptic vesicles. These vesicles share some, but not all, membrane proteins with synaptic vesicles, including the SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) synaptobrevin 2, and contain both l-glutamate and d-serine. Furthermore, they show uptake of l-glutamate and d-serine that is driven by a proton electrochemical gradient. d-Serine uptake is associated with vesicle acidification and is dependent on chloride. Whereas l-serine is not transported, serine racemase, the synthesizing enzyme for d-serine, is anchored to the membrane of the vesicles, allowing local generation of d-serine. Finally, we reveal a previously unexpected mutual vesicular synergy between d-serine and l-glutamate filling in glia vesicles. We conclude that astrocytes contain vesicles capable of storing and releasing d-serine, l-glutamate, and most likely other neuromodulators in an activity-dependent manner.

Secretory IgA, a major immunoglobulin in most bovine external secretions.

Bovine secretory IgA (SIgA), recently identified in colostrum, was shown to be homologous to human SIgA by immunologic cross-reaction. A quantitative study indicated that bovine SIgA, a minor component of colostrum, is a major immunoglobulin in most other external secretions including saliva, spermatic fluid, lacrimal, nasal and gastrointestinal secretions. SIgA was isolated from saliva. The free form of secretory component was found to be abundant in milk. A normal lactating cow produces about 1.2 g of this protein per day. Two forms of IgA were identified in serum: a normal serum IgA with no secretory antigenic determinant, and a small amount of SIgA. In vitro synthesis of SIgA by the salivary gland was studied by tissue cultures with incorporation of labeled amino acids.

Identification and staining of distinct populations of secretory organelles in astrocytes.

Increasing evidence indicates that astrocytes, the most abundant glial cell type in the brain, respond to an elevation in cytoplasmic calcium concentration ([Ca(2+)]i) by releasing chemical transmitters (also called gliotransmitters) via regulated exocytosis of heterogeneous classes of organelles. By this process, astrocytes exert modulatory influences on neighboring cells and are thought to participate in the control of synaptic circuits and cerebral blood flow. Studying the properties of exocytosis in astrocytes is a challenge, because the cell biological basis of this process is incompletely defined. Astrocytic exocytosis involves multiple populations of secretory vesicles, including synaptic-like microvesicles (SLMVs), dense-core granules (DCGs), and lysosomes. Here we summarize the available information for identifying individual populations of secretory organelles in astrocytes, including DCGs, SLMVs, and lysosomes, and present experimental procedures for specifically staining such populations.

Characterization of the molecular mechanisms of insulin exocytosis and of their adaptation to physiopathological conditions

Résumé large public Le glucose est une source d'énergie essentielle pour notre organisme, indispensable pour le bon fonctionnement des cellules de notre corps. Les cellules β du pancréas sont chargées de réguler l'utilisation du glucose et de maintenir la glycémie (taux de glucose dans le sang) à un niveau constant. Lorsque la glycémie augmente, ces dernières sécrètent l'insuline, une hormone favorisant l'absorption, l'utilisation et le stockage du glucose. Une sécrétion insuffisante d'insuline provoque une élévation anormale du taux de glucose dans le sang (hyperglycémie) et peut mener au développement du diabète sucré. L'insuline est sécrétée dans le sang par un mécanisme particulier appelé exocytose. Une meilleure compréhension de ce mécanisme est nécessaire dans l'espoir de trouver des nouvelles thérapies pour traiter les 170 millions de personnes atteintes de diabète sucré à travers le monde. L'implication de diverses protéines, comme les SNAREs ou Rabs a déjà été démontrée. Cependant leurs mécanismes d'action restent, à ce jour, peu compris. De plus, l'adaptation de la machinerie d'exocytose à des conditions physiopathologiques, comme l'hyperglycémie, est encore à élucider. Le but de mon travail de thèse a été de clarifier le rôle de deux protéines, Noc2 et Tomosyn, dans l'exocytose ; puis de déterminer les effets d'une exposition prolongée à un taux élevé de glucose sur l'ensemble des protéines de la machinerie d'exocytose. Noc2 est un partenaire potentiel de deux Rabs connues pour leur implication dans les dernières étapes de l'exocytose, Rab3 et Rab27. Grâce à l'étude de différents mutants de Noc2, j'ai montré que l'interaction avec Rab27 permet à la protéine de s'associer avec les organelles de la cellule β contenant l'insuline. De plus, en diminuant sélectivement l'expression de Noc2, j'ai déterminé l'importance de cette protéine pour le bon fonctionnement du processus d'exocytose et le relâchement de l'insuline. Quant à Tomosyn, une protéine interagissant avec les protéines SNAREs, j'ai démontré son importance dans la sécrétion d'insuline en diminuant de manière sélective son expression dans les cellules β. Ensuite, grâce à une combinaison d'approches moléculaires et de microscopie, j'ai mis en évidence le rôle de Tomosyn dans les dernières étapes de l'exocytose. Enfin, puisque la sécrétion d'insuline est diminuée lors d'une hyperglycémie prolongée, j'ai analysé l'adaptation de la machinerie d'exocytose à ces conditions. Ceci m'a permis de découvrir que l'expression de quatre protéines essentielles pour le processus d'exocytose, Noc2, Rab3, Rab27 et Granuphilin, est fortement diminuée lors d'une hyperglycémie chronique. L'ensemble de ces données met en évidence l'importance de Noc2 et Tomosyn dans la sécrétion d'insuline. L'inhibition, par un taux élevé de glucose, de l'expression de Noc2 et d'autres protéines indispensables pour l'exocytose suggère que ce phénomène pourrait contribuer au développement du diabète sucré. Résumé L'exocytose d'insuline, en réponse au glucose circulant dans le sang, est la fonction principale de la cellule β. Celle-ci permet de stabiliser le taux de glucose sanguin (glycémie). Le diabète de type 2 est caractérisé par une glycémie élevée due, principalement, à un défaut de sécrétion d'insuline en réponse au glucose. La compréhension des mécanismes qui contrôlent l'exocytose d'insuline est essentielle pour clarifier les causes du diabète sucré. Plusieurs composants impliqués dans ce processus ont été identifiés. Ceux-ci incluent les SNAREs Syntaxin-1, VAMP2 et SNAP25 et les GTPases Rab3 et Rab27 qui jouent un rôle dans les dernières étapes de l'exocytose. Pendant mon travail de thèse, j'ai étudié le rôle de Noc2, un des partenaires de Rab3 et Rab27, dans l'exocytose d'insuline. Nous avons déterminé que Noc2 s'associe aux granules de sécrétion d'insuline grâce à son interaction avec Rab27. La diminution de l'expression de Noc2 dans la lignée cellulaire β INS-1E, par ARN interférence, influence négativement la sécrétion d'insuline stimulée par différents sécrétagogues et prouve que cette protéine Noc2 est essentielle pour l'exocytose d'insuline. L'interaction avec Munc13, une protéine impliquée dans l'arrimage des vésicules, suggère que Noc2 participe au recrutement des granules d'insuline à la membrane plasmique. Ensuite, j'ai analysé l'adaptation de la machinerie d'exocytose à des concentrations supraphysiologiques de glucose. Le niveau d'expression de Rab3 et Rab27 et de leurs effecteurs Granuphilin/S1p4 et Noc2 est fortement diminué par une exposition prolongée des cellules β à haut glucose. L'effet observé est en relation avec l'induction de l'expression de ICER, un facteur de transcription surexprimé dans des conditions d'hyperglycémie et également dans des modèles génétiques de diabète de type 2. La surexpression de ICER dans des cellules INS-1E diminue l'expression de Rab3, Rab27, Granuphilin/Slp4 et Noc2 et par conséquent l'exocytose d'insuline. Ainsi, l'induction de ICER, après une exposition prolongée à haut glucose, régule négativement l'expression de protéines essentielles pour l'exocytose et altère la sécrétion d'insuline. Ce mécanisme pourrait contribuer au dysfonctionnement de l'exocytose d'insuline dans le diabète de type 2. Dans la dernière partie de ma thèse, j'ai investigué le rôle de la protéine Tomosyn-1 dans la formation du complexe SNARE. Cette protéine a une forte affinité pour Syntaxin-1 et contient un domaine SNARE. Tomosyn-1 est concentrée dans les régions cellulaires enrichies en granules de sécrétion. La diminution sélective de l'expression de Tomosyn-1 induit une réduction de l'exocytose stimulée par différents sécrétagogues. Cet effet est dû à un défaut de fusion des granules avec la membrane plasmique. Ceci nous indique que Tomosyn-1 intervient dans une phase importante de la préparation des vésicules à la fusion, qui est nécessaire à l'exocytose. Abstract: Insulin exocytosis from pancreatic β-cells plays a central role in blood glucose homeostasis. Diabetes mellitus is a complex metabolic disorder characterized by secretory dysfunctions in pancreatic β-cells and release of amounts of insulin that are inappropriate to maintain blood glucose concentration within normal physiological ranges. To define the causes of β-cell failure a basic understanding of the molecular mechanisms that control insulin exocytosis is essential. Some of the molecular components involved in this process have been identified, including the SNARE proteins VAMP2, Syntaxin-1 and SNAP25 and the two GTPases, Rab3 and Rab27, that regulate the final steps of insulin secretion. I first investigated the role of Noc2, a potential Rab3 and Rab27 partner, in insulin secretion. I found that Noc2 associates with Rab27 and is recruited by this GTPase on insulin- containing granules. Silencing of the Noc2 gene by RNA interference led to a strong impairment in the capacity of the β-cell line INS-1E to respond to secretagogues, indicating that appropriate levels of the protein are essential for insulin exocytosis. I also showed that Noc2 interacts with Munc13, a protein that controls vesicle priming, suggesting a possible involvement of Noc2 in the recruitment of secretory granules at the plasma membrane. In the second part of my thesis, I investigated the adaptation of the molecular machinery of exocytosis to physiopathological conditions. I found that the expression of Rab3, Rab27 and of their effectors Granuphilin/Slp4 and Noc2 is dramatically decreased by chronic exposure of β-ce1ls to supraphysiological glucose levels. The observed glucotoxic effect is a consequence of the induction of ICER, a transcriptional repressor that is increased by prolonged hyperglycemia and in genetic models of type 2 diabetes. Overexpression of ICER reduced Granuphilin, Noc2, Rab3 and Rab27 levels and inhibited exocytosis. These results suggest that the presence of inappropriate levels of ICER diminishes the expression of a group of proteins essential for exocytosis and contributes to defective insulin release in type 2 diabetes. In the last part of my thesis, I focused my attention on the role of Tomosyn-1, a Syntaxin-1 binding protein possessing a SNARE-like motif, in the control of SNARE complex assembly. I found that Tomosyn-1 is concentrated in cellular compartments enriched in insulin-containing secretory granules. Silencing of Tomosyn-1 did not affect the number of secretory granules docked at the plasma membrane but decreased their release probability, resulting in a reduction in stimulus-induced insulin exocytosis. These findings suggest that Tomosyn-1 is involved in a post-docking event that prepares secretory granules for fusion and is necessary to sustain exocytosis in response to insulin secretagogues.

Functional Microdomains Control Glutamate Exocytosis from Astrocytes

The discovery that astrocytes possess a non-electrical form of excitability (Ca21-excitability) that leads to the release of chemical transmitters, an activity called ''gliotransmission'', indicates that these cells may have additional important roles in brain function. Elucidating the stimulus-secretion coupling leading to the exocytic release of chemical transmitters (such as glutamate, Bezzi et al., Nature Neurosci, 2004) may therefore clarify i) whether astrocytes represent in full a new class of secretory cells in the brain and ii) whether they can participate to the fast brain signaling in the brain. We have recently discovered the existence in astrocytes of functional sub-membrane microdomains of Ca21 release from the internal stores in response to mGluR5 activation (Marchaland et al., J of Neurosci., 2008). Such Ca21 microdomains control exocytosis of astrocytic glutamate signalling to neurons. Homer proteins are scaffold proteins controlling Ca21 signalling in different cellular microdomains, including dendritic spines in neurons (Sala et al., J of Neurosci., 2005). Thus, similarly to dendritic pines, Homer1 could be implicated in the coupling between astrocytic mGluR5 and IP3Rs on the ER. Here, by using a recently developed approach for studying vesicle recycling dynamics at synapses (Voglmaier et al., Neuron, 2006; Balaji and Ryan, PNAS, 2007) combined with epifluorescence and total internal reflection fluorescence (TIRF) imaging, we have investigated the involvement of Homer1 proteins in the Ca21-dependent stimulus-secretion coupling leading glutamate exocytosis of synaptic-like microvesicles (SLMVs) in astrocytes.

Cab45 is required for Ca(2+)-dependent secretory cargo sorting at the trans-Golgi network

Ca(2+) import into the lumen of the trans-Golgi network (TGN) by the secretory pathway calcium ATPase1 (SPCA1) is required for the sorting of secretory cargo. How is Ca(2+) retained in the lumen of the Golgi, and what is its role in cargo sorting? We show here that a soluble, lumenal Golgi resident protein, Cab45, is required for SPCA1-dependent Ca(2+) import into the TGN; it binds secretory cargo in a Ca(2+)-dependent reaction and is required for its sorting at the TGN.

Recognition of Gram-positive Intestinal Bacteria by Hybridoma- and Colostrum-derived Secretory Immunoglobulin A Is Mediated by Carbohydrates.

Humans live in symbiosis with 10(14) commensal bacteria among which >99% resides in their gastrointestinal tract. The molecular bases pertaining to the interaction between mucosal secretory IgA (SIgA) and bacteria residing in the intestine are not known. Previous studies have demonstrated that commensals are naturally coated by SIgA in the gut lumen. Thus, understanding how natural SIgA interacts with commensal bacteria can provide new clues on its multiple functions at mucosal surfaces. Using fluorescently labeled, nonspecific SIgA or secretory component (SC), we visualized by confocal microscopy the interaction with various commensal bacteria, including Lactobacillus, Bifidobacteria, Escherichia coli, and Bacteroides strains. These experiments revealed that the interaction between SIgA and commensal bacteria involves Fab- and Fc-independent structural motifs, featuring SC as a crucial partner. Removal of glycans present on free SC or bound in SIgA resulted in a drastic drop in the interaction with Gram-positive bacteria, indicating the essential role of carbohydrates in the process. In contrast, poor binding of Gram-positive bacteria by control IgG was observed. The interaction with Gram-negative bacteria was preserved whatever the molecular form of protein partner used, suggesting the involvement of different binding motifs. Purified SIgA and SC from either mouse hybridoma cells or human colostrum exhibited identical patterns of recognition for Gram-positive bacteria, emphasizing conserved plasticity between species. Thus, sugar-mediated binding of commensals by SIgA highlights the currently underappreciated role of glycans in mediating the interaction between a highly diverse microbiota and the mucosal immune system.

Secretory IgA: an actor of the interplay between the commensal flora and the intestinal immune system?

In the gastro-intestinal tract,Peyers patches have been describedas a major inductive site for mucosalsecretory IgA (SIgA) responses directedagainst pathogens. The classicalview is that SIgAserves as the firstline of defense against microorganismsby agglutining potential invadersand faciliting their clearance byperistaltic and mucociliary movements,a mechanism called immuneexclusion. Our laboratory has shownthat SIgA is not only able to be"retrotransported" into Peyers patchesvia the associated M cells, but also todeliver sizeable cargos in the form ofSIgA-based immune complexes, resultingin the onset of non-inflammatorytype of responses. Such a novelfunction raises the question of thepossible role of mucosal SIgA in theinterplay with commensal bacteriaand the contribution of the antibody inbacterial homeostasis. To address thisquestion, Lactobacillus rhamnosus(LPR) was administered into a mouseligated loop comprising a Peyerspatch, in association or not with SIgA.The fate of fluorescently labelled bacteriawas followed by laser scanningconfocal microscopy at different incubationtimes. After 2 hours of incubationin the loop, LPR bacteria arefound more abundantly in thesubepithelial dome (SED) regionwhen they are coated with SIgA thanLPR administered alone despite theyare absent from neighboring villi.Herein, it is shown that this mechanismof entry involves M cells inPeyers pathes. After their sampling byM cells, bacteria are engulfed by thedendritic cells of the subjacent SEDregion. Interestingly, LPR bacteriaare found coated by the endogenousnatural SIgA present in mice intestinalsecretions, confirming the requirementof SIgA for this type of entry.The subsequent effect on the maturationof dendritic cells after interactionwith LPR was investigated in vitroin presence or not of SIgA by measuringthe expression of CD40, CD80and CD86 surface markers with flowcytometry analyses. Results show thatDCs respond in the same way in presenceof SIgA than with LPR bacteriaalone, indicating that SIgA does notmodulate the interaction betweenDCs and bacteria in this context. Thiswork gives new evidences about theinvolvement of SIgA in the mechanismby which the intestinal immunesystem permanently checks the contentof the intestine.