PlexA is the receptor for transmembrane semaphorin-1a (Sema-1a) a

PlexA is the receptor for transmembrane semaphorin-1a (Sema-1a) and is required for CNS longitudinal tract formation, however only selleck chemicals in the most lateral region of the nerve cord ( Winberg et al., 1998b). The PlexB receptor, in contrast, is specifically required for the organization

of CNS longitudinal tract only in the intermediate region ( Ayoob et al., 2006), however the identity of the PlexB ligand(s) required for this function is still unclear. There are two secreted semaphorins in Drosophila, semaphorin-2a (Sema-2a) and semaphorin-2b (Sema-2b). Sema-2a signals repulsion and contributes in part to PlexB-mediated sensory afferent targeting within the CNS; however, CNS longitudinal projections appear to be less affected in Sema-2a mutants as compared to PlexB mutants ( Zlatic et al., 2009). Here, we show that both Sema-2a and Sema-2b are PlexB ligands during embryonic CNS development and mediate distinct functions. The PlexB receptor integrates both Sema-2a repulsion and Sema-2b attraction to coordinately regulate the assembly of specific CNS longitudinal projections

and select sensory afferent innervation within that same CNS region. Perturbation of PlexB-mediated signaling during the establishment of sensory afferent connectivity within the CNS results in larval sensory-dependent behavioral deficits. These results suggest that a combination of semaphorin cues, acting in concert with the longer-range Slit gradient in the embryonic Drosophila CNS, ensures the fidelity of both CNS interneuron projection organization selleck compound and sensory afferent targeting, both of which are critical for the establishment of a functional neural circuit. In the absence of PlexB, interneuron projections that form a group of longitudinal connectives in the developing Drosophila embryonic CNS are disorganized ( Ayoob et al., 2006). Interestingly, the targeting of ch sensory

afferent projections to the CNS occurs within this same intermediate CNS region, as determined by intracellular labeling of individual ch neurons ( Merritt and Whitington, 1995 and Zlatic et al., 2003). By genetically labeling Carnitine dehydrogenase ch neurons with GFP using the iav-GAL4 driver ( Kwon et al., 2010) and visualizing CNS longitudinal tracts with 1D4 immunohistochemistry ( Figures 1A–1D), we asked whether or not sensory afferent targeting to the CNS also requires PlexB. As previously reported ( Ayoob et al., 2006), in PlexB−/− null mutant (PlexBKG00878) embryos the intermediate 1D4+ longitudinal tract (1D4-i) is severely disorganized (including defasciculation, disorganization, and wandering of axon bundles within this intermediate position); however, the medial and lateral 1D4+ tracts (1D4-m and 1D4-l) appear normal ( Figures 1E and 1F).

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