La Société de Biologie de Strasbourg : 100 ans au service de la science et de la société.

Founded in 1919, the Society of Biology of Strasbourg (SBS) is a learned society whose purpose is the dissemination and promotion of scientific knowledge in biology. Subsidiary of the Society of Biology, the SBS celebrated its Centenary on Wednesday, the 16th of October 2019 on the Strasbourg University campus and at the Strasbourg City Hall. This day allowed retracing the various milestones of the SBS, through its main strengths, its difficulties and its permanent goal to meet scientific and societal challenges. The common thread of this day was the transmission of knowledge related to the past, the present, but also the future. At the start of the 21st century, the SBS must continue to reinvent itself to pursue its objective of transmitting scientific knowledge in biology and beyond. Scientific talks performed by senior scientists and former SBS thesis prizes awardees, a round table, and informal discussions reflected the history and the dynamism of the SBS association. All SBS Centennial participants have set the first milestone for the SBS Bicentennial.

TITLE: La Société de Biologie de Strasbourg : 100 ans au service de la science et de la société. ABSTRACT: Filiale de la Société de Biologie, la Société de Biologie de Strasbourg (SBS) est une société savante qui a pour objet la diffusion et la promotion du savoir scientifique en biologie et en médecine. Fondée en 1919, La SBS a célébré son Centenaire le mercredi 16 octobre 2019. Cette journée a permis de retracer les différents jalons de la SBS, à travers ses lignes de forces, ses difficultés et sa volonté permanente de mettre en exergue les défis scientifiques et sociétaux auxquels participent les recherches strasbourgeoises. Le fil rouge de cette journée a été la transmission d'un savoir en lien avec le passé, le présent, mais également le futur. En ce début du 21e siècle, la SBS se doit de continuer de se réinventer pour poursuivre son objectif de transmission des connaissances scientifiques en biologie et au-delà. L'ensemble des participants du Centenaire de la SBS a ainsi posé la première pierre du Bicentenaire de la SBS.

Diltiazem-induced neuroprotection in glutamate excitotoxicity and ischemic insult of retinal neurons.

PURPOSE: Cell death is often related to an abnormal increase in Ca(2+) flux. In the retina, Ca(2+) channels are mainly from the L-type that do not inactivate with time. Under excitotoxic and ischemic conditions, their continuous activation may therefore contribute significantly to the lethal Ca(2+) influx. To assess this hypothesis, the Ca(2+) channel blocker, diltiazem, was applied in excitotoxic and ischemic conditions. METHODS: To induce excitotoxicity, retinal cell cultures from newborn rats were incubated with glutamate. The toxicity of glutamate was quantified by neuronal immunostaining with an antibody directed against the neuron specific enolase. Glutamate receptor function in vitro was assessed in pig retinal cell cultures by patch clamp recording. Retinal ischemia was induced by raising the intraocular pressure in adult rats. Retinal cell loss was quantified on retinal sections by measuring nuclear cell densities. RESULTS: In retinal cell culture, glutamate application induced a major cell loss. This cell loss was attributed to glutamate excitotoxicity because glutamate receptor blockers like MK-801 and CNQX increased significantly neuronal survival. MK-801 and CNQX, which block NMDA and AMPA/Kainate receptors, respectively, had additive effects. Expression of AMPA/Kainate glutamate receptors in mixed adult retinal cell cultures was attested by patch clamp recording. In newborn rat retinal culture, glutamate excitotoxicity was significantly reduced by addition of the L-type Ca(2+) channel blocker, diltiazem. In in vivo experiments, the increase in ocular pressure induced a decrease in cell number in the inner nuclear and ganglion cell layers. When animals received diltiazem injections, the ischemic treatment induced a less severe reduction in retinal cells; this neuroprotection was statistically significant in the ganglion cell layer. CONCLUSION: These results are consistent with previous studies suggesting that Ca(2+) channel activation contributes to retinal cell death following either glutamate excitotoxicity or retinal ischemia. Under both conditions, the L-type Ca(2+) channel blocker, diltiazem, can limit cell death. These results extend the potential application of diltiazem in retinal neuroprotection to retinal pathologies involving glutamate excitotoxicity and ischemia.

Cellular localization of the vesicular inhibitory amino acid transporter in the mouse and human retina.

Horizontal cells are classically thought to mediate lateral inhibition by gamma-aminobutyric acid (GABA)-transporter mediated release. In the mammalian retina, however, GABA uptake and cloned GABA transporter were not detected in horizontal cells. Furthermore, the vesicular inhibitory amino acid transporter (VIAAT or VGAT) that loads GABA and glycine into synaptic vesicles was reported recently to be expressed in horizontal cells. To further assess synaptic transmission in mammalian horizontal cells, we examined the subcellular distribution of VIAAT in mouse and human retina by confocal microscopy with specific cell markers. VIAAT was observed in the mouse outer plexiform layer as punctate structures that localized in calbindin-positive horizontal cells. These structures were in close apposition with synaptophysin-, PSD-95-, dystrophin-, and bassoon-immunopositive photoreceptor terminals, suggesting that VIAAT is localized in horizontal cell tips at photoreceptor terminals. VIAAT-positive puncta were also in apposition to lectin-labeled cone terminals or dendrites of PKCalpha-immunopositive rod bipolar cells, indicating that VIAAT is expressed in horizontal cell tips at both rod and cone terminals. By contrast, only a very few puncta were observed in the human outer plexiform layer, whereas the inner plexiform layer remained labeled as in the mouse retina. When using adult human retinal cells in culture, horizontal cells identified by parvalbumin immunostaining were found to contain VIAAT, either at their terminals or throughout the entire cell similarly as in syntaxin-immunopositive cells. These differences between human retinal tissue and cultured cells were attributed to VIAAT degradation in postmortem retinal tissue. VIAAT localization in mouse and human horizontal cells further support the role of inhibitory transmitters in lateral inhibition at the photoreceptor terminals.