Single-fluorophore blinking events were detected at the end of th

Single-fluorophore blinking events were detected at the end of the movie (typically GDC-0199 molecular weight in frames 5,000–10,000), and their mean intensity, I, was measured for each cluster. The total fluorophore number, N, of the cluster was then calculated according to the formula: N = A / (I × τw). For dual-color quantification, decay recordings were acquired first for mRFP followed by Dendra2, since excitation at 561 nm did not affect the nonconverted form of Dendra2. The calculated fluorophore numbers of individual gephyrin clusters (from the pulsed photoconversion or the fluorescence

decay method) were equated to the fluorescence intensity of the same clusters in images taken with the mercury lamp (background-corrected integrated cluster intensity). This resulted in a conversion factor ϕ (fluorescence intensity/molecule) that could be applied to any structure

visualized in conventional fluorescence images, provided that identical imaging conditions were maintained. The authors thank Alain Bessis, Yasmine Cantaut-Belarif, and Andréa Dumoulin (Institut de Biologie de l’Ecole Normale Supérieure) as well as Christophe Zimmer and Mickaël Lelek (Institut Pasteur) for technical help. This project was funded by the Fondation Pierre-Gilles de Gennes through a research contract with Nikon France, the Institut pour la Recherche sur la Moelle Épinière et l’Encéphale, and by grants TRIDIMIC buy Dabrafenib and MorphoSynDiff from the Agence Nationale pour la Recherche. C.G.S. acknowledges grant Lamonica, and I.I. acknowledges the Netherlands Organisation for Scientific Research for financial support. P.C.R. was supported by a Marie Curie International

Incoming Fellowship within the 7th European Community Framework Programme. C.G.S., I.I., M.D., and A.T. designed the experiments; C.G.S., isometheptene I.I., P.C.R., P.R., and M.E.B. conducted the experiments and analyzed the data; C.G.S. and I.I. wrote the manuscript. “
“Spontaneous neuronal activity pervades the developing nervous system and correlations contained in its patterns guide the synaptic refinement of many immature circuits (Blankenship and Feller, 2010 and Katz and Shatz, 1996). This has best been studied in the developing visual system, where waves of spontaneous activity originate in the retina (Meister et al., 1991) and dictate firing patterns up to primary visual cortex (V1) (Ackman et al., 2012 and Mooney et al., 1996). Across many species, retinal waves mature in three stereotypic stages (I–III) (Blankenship and Feller, 2010 and Wong, 1999). In each stage, distinct mechanisms give rise to unique activity patterns that serve specific functions in organizing visual circuits. During stage III (postnatal day 10–14, P10–P14 mice), the firing patterns of different RGC types diverge (Lee et al., 2002, Liets et al., 2003 and Wong and Oakley, 1996).

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