Bardet-Biedl syndrome (BBS) is a genetically heterogeneous disorder characterized primarily by retinal dystrophy, obesity, polydactyly, renal malformations and learning disabilities. Although five BBS genes have been cloned, the molecular basis of this syndrome remains elusive. Here we show that BBS is probably caused by a defect at the basal body of ciliated cells. We have cloned a new BBS gene, BBS8, which encodes a protein with a prokaryotic domain, pilF, involved in pilus formation and twitching mobility. In one family, a homozygous null BBS8 mutation leads to BBS with randomization of left-right body axis symmetry, a known defect of the nodal cilium. We have also found that BBS8 localizes specifically to ciliated structures, such as the connecting cilium of the retina and columnar epithelial cells in the lung. In cells, BBS8 localizes to centrosomes and basal bodies and interacts with PCM1, a protein probably involved in ciliogenesis. Finally, we demonstrate that all available Caenorhabditis elegans BBS homologues are expressed exclusively in ciliated neurons, and contain regulatory elements for RFX, a transcription factor that modulates the expression of genes associated with ciliogenesis and intraflagellar transport.
The Caenorhabditis elegans dauer larva is specialized for dispersal without growth and is formed under conditions of overcrowding and limited food. The daf-7 gene, required for transducing environmental cues that support continuous development with plentiful food, encodes a transforming growth factor-beta (TGF-beta) superfamily member. A daf-7 reporter construct is expressed in the ASI chemosensory neurons. Dauer-inducing pheromone inhibits daf-7 expression and promotes dauer formation, whereas food reactivates daf-7 expression and promotes recovery from the dauer state. When the food/pheromone ratio is high, the level of daf-7 mRNA peaks during the L1 larval stage, when commitment to non-dauer development is made.
Bardet-Biedl syndrome (BBS) is a genetically heterogeneous developmental disorder whose molecular basis is largely unknown. Here, we show that mutations in the Caenorhabditis elegans bbs-7 and bbs-8 genes cause structural and functional defects in cilia. C. elegans BBS proteins localize predominantly at the base of cilia, and like proteins involved in intraflagellar transport (IFT), a process necessary for cilia biogenesis and maintenance, move bidirectionally along the ciliary axoneme. Importantly, we demonstrate that BBS-7 and BBS-8 are required for the normal localization/motility of the IFT proteins OSM-5/Polaris and CHE-11, and to a notably lesser extent, CHE-2. We propose that BBS proteins play important, selective roles in the assembly and/or function of IFT particle components. Our findings also suggest that some of the cardinal and secondary symptoms of BBS, such as obesity, diabetes, cardiomyopathy, and learning defects may result from cilia dysfunction.[Keywords: Bardet-Biedl syndrome; BBS proteins; cilia and flagella; Caenorhabditis elegans; basal body; intraflagellar transport] Supplemental material is available at http://www.genesdev.org.
Using DNA sequences 5′ to open reading frames, we have constructed green fluorescent protein (GFP) fusions and generated spatial and temporal tissue expression profiles for 1,886 specific genes in the nematode Caenorhabditis elegans. This effort encompasses about 10% of all genes identified in this organism. GFP-expressing wild-type animals were analyzed at each stage of development from embryo to adult. We have identified 5′ DNA regions regulating expression at all developmental stages and in 38 different cell and tissue types in this organism. Among the regulatory regions identified are sequences that regulate expression in all cells, in specific tissues, in combinations of tissues, and in single cells. Most of the genes we have examined in C. elegans have human orthologs. All the images and expression pattern data generated by this project are available at WormAtlas (http://gfpweb.aecom.yu.edu/index) and through WormBase (http://www.wormbase.org).
Completion of the DNA sequences of the human genome and that of the nematode Caenorhabditis elegans allows the large-scale identification and analysis of orthologs of human genes in an organism amenable to detailed genetic and molecular analyses. We are determining gene expression profiles in specific cells, tissues, and developmental stages in C. elegans. Our ultimate goal is not only to describe detailed gene expression profiles, but also to gain a greater understanding of the organization of gene regulatory networks and to determine how they control cell function during development and differentiation. The use of C. elegans as a platform to investigate the details of gene regulatory networks has several major advantages. Two key advantages are that it is the simplest multicellular organism for which there is a complete sequence (C. elegans Sequencing Consortium 1998), and it is the only multicellular organism for which there is a completely documented cell lineage (Sulston and Horvitz 1977; Sulston et al. 1983). C. elegans is amenable to both forward and reverse genetics (for review, see Riddle et al. 1997). A 2-week life span and generation time of just 3 days for C. elegans allows experimental procedures to be much shorter, more flexible, and more cost-effective compared to the use of mouse or zebrafish models for genomic analyses. Finally, the small size, transparency, and limited cell number of the worm make it possible to observe many complex cellular and developmental processes that cannot easily be observed in more complex organisms. Morphogenesis of organs and tissues can be observed at the level of a single cell (White et al. 1986). As events have shown, investigating the details of C. elegans biology can lead to fundamental observations about human health and biology (Sulston 1976; Hedgecock et al. 1983; Ellis and Horvitz 1986). We are using complementary approaches to examine gene expression in C. elegans. We are constructing transgenic animals containing promoter green fluorescent protein (GFP) fusions of nematode orthologs of human genes. These transgenic animals are examined to determine the time and tissue expression pattern of the promoter::GFP constructs. Concurrently, we are undertaking serial analysis of gene expression (SAGE) on all developmental stages of intact animals and on selected purified cells. Tissues and selected cells are isolated using a fluorescence activated cell sorter (FACS) to sort promoter::GFP marked cell populations. To date we have purified to near homogeneity cell populations for embryonic muscle, gut, and a subset of neurons. The SAGE and promoter::GFP expression data are publicly available at http://elegans.bcgsc.bc.ca.
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