Regulation of vertebrate nervous system alternative splicing and development by an SR-related protein.

Alternative splicing is a key process underlying the evolution of increased proteomic and functional complexity and is especially prevalent in the mammalian nervous system. However, the factors and mechanisms governing nervous system-specific alternative splicing are not well understood. Through a genome-wide computational and expression profiling strategy, we have identified a tissue- and vertebrate-restricted Ser/Arg (SR) repeat splicing factor, the neural-specific SR-related protein of 100 kDa (nSR100). We show that nSR100 regulates an extensive network of brain-specific alternative exons enriched in genes that function in neural cell differentiation. nSR100 acts by increasing the levels of the neural/brain-enriched polypyrimidine tract binding protein and by interacting with its target transcripts. Disruption of nSR100 prevents neural cell differentiation in cell culture and in the developing zebrafish. Our results thus reveal a critical neural-specific alternative splicing regulator, the evolution of which has contributed to increased complexity in the vertebrate nervous system.

Analysis of maternal-zygotic ugdh mutants reveals divergent roles for HSPGs in vertebrate embryogenesis and provides new insight into the initiation of left-right asymmetry.

Growth factors and morphogens regulate embryonic patterning, cell fate specification, cell migration, and morphogenesis. The activity and behavior of these signaling molecules are regulated in the extracellular space through interactions with proteoglycans (Bernfield et al., 1999; Perrimon and Bernfield 2000; Lander and Selleck 2000; Selleck 2000). Proteoglycans are high molecular-weight proteins consisting of a core protein with covalently linked glycosaminoglycan (GAG) side chains, which are thought to mediate ligand interaction. Drosophila mutant embryos deficient for UDP-glucose dehydrogenase activity (Ugdh, required for GAG synthesis) exhibit abnormal Fgf, Wnt and TGFß signaling and die during gastrulation, indicating a broad and critical role for proteoglycans during early embryonic development (Lin et al., 1999; Lin and Perrimon 2000) (Hacker et al., 1997). Mouse Ugdh mutants also die at gastrulation, however, only Fgf signaling appears disrupted (Garcia-Garcia and Anderson, 2003). These findings suggested a possible divergence in the requirement for proteoglycans during Drosophila and mouse embryogenesis, and that mammals may have evolved alternative means of regulating Wnt and TGFß activity. To further examine the function of proteoglycans in vertebrate development, we have characterized zebrafish mutants devoid of both maternal and zygotic Ugdh/Jekyll activity (MZjekyll). We demonstrate that MZjekyll mutant embryos display abnormal Fgf, Shh, and Wnt signaling activities, with concomitant defects in central nervous system patterning, cardiac ventricular fate specification and axial morphogenesis. Furthermore, we uncover a novel role for proteoglycans in left-right pattern formation. Our findings resolve longstanding questions into the evolutionary conservation of Ugdh function and provide new mechanistic insights into the initiation of left-right asymmetry.

Vangl2 directs the posterior tilting and asymmetric localization of motile primary cilia.

Cilia are microtubule-based organelles that project into the extracellular space, function in the perception and integration of environmental cues, and regulate Hedgehog signal transduction. The emergent association of ciliary defects with diverse and pleiotropic human disorders has fuelled investigations into the molecular genetic regulation of ciliogenesis. Although recent studies implicate planar cell polarity (PCP) in cilia formation, this conclusion is based on analyses of proteins that are not specific to, or downstream effectors of PCP signal transduction. Here we characterize zebrafish embryos devoid of all Vangl2 function, a core and specific component of the PCP signalling pathway. Using Arl13b-GFP as a live marker of the ciliary axoneme, we demonstrate that Vangl2 is not required for ciliogenesis. Instead, Vangl2 controls the posterior tilting of primary motile cilia lining the neurocoel, Kupffer's vesicle and pronephric duct. Furthermore, we show that Vangl2 is required for asymmetric localization of cilia to the posterior apical membrane of neuroepithelial cells. Our results indicate a broad and essential role for PCP in the asymmetric localization and orientation of motile primary cilia, establishing directional fluid flow implicated in normal embryonic development and disease.