The activity of the DAF-2 insulin-like receptor is required for Caenorhabditis elegans reproductive growth and normal adult life span. Informatic analysis identified 37 C. elegans genes predicted to encode insulin-like peptides. Many of these genes are divergent insulin superfamily members, and many are clustered, indicating recent diversification of the family. The ins genes are primarily expressed in neurons, including sensory neurons, a subset of which are required for reproductive development. Structural predictions and likely C-peptide cleavage sites typical of mammalian insulins suggest that ins-1 is most closely related to insulin. Overexpression of ins-1, or expression of human insulin under the control of ins-1 regulatory sequences, causes partially penetrant arrest at the dauer stage and enhances dauer arrest in weak daf-2 mutants, suggesting that INS-1 and human insulin antagonize DAF-2 insulin-like signaling. A deletion of the ins-1 coding region does not enhance or suppress dauer arrest, indicating a functional redundancy among the 37 ins genes. Of five other ins genes tested, the only other one bearing a predicted C peptide also antagonizes daf-2 signaling, whereas four ins genes without a C peptide do not, indicating functional diversity within the ins family. Insulin and its related proteins define a superfamily of secreted proteins that share a structural motif stabilized by a set of stereotypical disulfide bonds (Blundell and Humbel 1980;Murray-Rust et al. 1992). Insulin superfamily genes are ubiquitous in vertebrates, and have been identified in invertebrates, including insects, molluscs, and the nematode Caenorhabditis elegans (Duret et al. 1998;Gregoire et al. 1998;Smit et al. 1998;Kawano et al. 2000). Seven members of the insulin superfamily have been identified in humans, including insulin (Brown et al. 1955), insulin-like growth factors (IGFs) I and II (Rinderknecht and Humbel 1978a,b), relaxins HI and HII (Bedarkar et al. 1977;Schwabe and McDonald 1977), early placenta insulin-like peptide (EPIL) (Chassin et al. 1995;Koman et al. 1996), and relaxin-like factor (Bullesbach and Schwabe 1995). These hormones mediate diverse functions. Insulin is a metabolic hormone that acts on target tissues to increase glucose uptake and energy storage, IGFs are mitogenic stimulators that control cell survival and proliferation, and relaxin causes dilation of the symphysis pubis before parturition and vasodilation. No function is yet known for either EPIL or relaxin-like factor. Bombyxin in silk moths (Satake et al. 1997), and the neurons that secrete locust and molluscan insulin-related proteins (Smit et al. 1988;Lagueux et al. 1990) regulate metabolism, implicating insulin-like proteins in metabolic control broadly in animal phylogeny. The insulin-like proteins that regulate metabolism, insulin in vertebrates, bombyxin from silk moths, molluscan MIP, and locust LIRP, appear to be processed proteolytically to remove an internal C peptide (Smit et al. 1988;Lagueux et al. 1990;Kondo et al. 1996). This proc...
Two DNA-binding factors from Saccharomyces cerevisiae have been characterized, GRFI (general regulatory factor I) and ABFI (ARS-binding factor I), that recognize specific sequences within diverse genetic elements.GRFI bound to sequences at the negative regulatory elements (silencers) of the silent mating type loci HML E and HMR E and to the upstream activating sequence (UAS) required for transcription of the MAT a genes. A putative conserved UAS located at genes involved in translation (RPG box) was also recognized by GRFI. In addition, GRFI bound with high affinity to sequences within the (Cl_3A)-repeat region at yeast telomeres.Binding sites for GRFI with the highest affinity appeared to be of the form 5'-(A/G)(A/C)ACCCAN NCA(T/C)(T/C)-3', where N is any nucleotide. ABFI-binding sites were located next to autonomously replicating sequences (ARSs) at controlling elements of the silent mating type loci HMR E, HMR 1, and HML I and were associated with ARS1, ARS2, and the 2,um plasmid ARS. Two tandem ABFI binding sites were found between the HIS3 and DEDI genes, several kilobase pairs from any ARS, indicating that ABFI-binding sites are not restricted to ARSs. The sequences recognized by ABFI showed partial dyad-symmetry and appeared to be variations of the consensus 5'-TATCATTNNNNACGA-3'. GRFI and ABFI were both abundant DNA-binding factors and did not appear to be encoded by the SIR genes, whose products are required for repression of the silent mating type loci. Together, these results indicate that both GRFI and ABFI play multiple roles within the cell.Eucaryotic chromosomes appear to be organized in domains governing such processes as gene expression, DNA replication, and chromosome condensation. In an effort to define the biochemical components directing these events, we have been attracted to the features of the mating type loci of Saccharomyces cerevisiae (reviewed in reference 33). Haploid yeast cells of the a or a mating type express different genes at MAT, in the middle of chromosome III (Fig. 1). The alternate forms of this locus, MATa and MA To, encode distinct regulatory factors al and a2 or al and oa2, but have extensive regions of homology, referred to as W, X, and Z (2, 61). There are, in addition, silent copies of genes specifying each mating type stored on the left and right arms of chromosome III at HMLa and HMRa, respectively. In homothallic strains, the mating type of successive generations switches in a tightly regulated manner (29,35,80). Switching is accomplished by gene conversion whereby sequences at MAT are replaced by those at HML or HMR (33,47). This process is initiated with the cleavage of MAT DNA in Z by a specific endonuclease that is the product of the HO gene (49, 50). The silent copies of the mating type loci are controlled by negative regulatory sequences located over 1,000 base pairs (bp) away from the promoters for these genes. Deletion analysis of HML and HMR has revealed cis-acting regulatory elements, E and I, that flank each locus on the left and right sides, respectivel...
The importance of p53 in carcinogenesis stems from its central role in inducing cell cycle arrest or apoptosis in response to cellular stresses. We have identified a Drosophila homolog of p53 ("Dmp53"). Like mammalian p53, Dmp53 binds specifically to human p53 binding sites, and overexpression of Dmp53 induces apoptosis. Importantly, inhibition of Dmp53 function renders cells resistant to X ray-induced apoptosis, suggesting that Dmp53 is required for the apoptotic response to DNA damage. Unlike mammalian p53, Dmp53 appears unable to induce a G1 cell cycle block when overexpressed, and inhibition of Dmp53 activity does not affect X ray-induced cell cycle arrest. These data reveal an ancestral proapoptotic function for p53 and identify Drosophila as an ideal model system for elucidating the p53 apoptotic pathway(s) induced by DNA damage.
General regulatory factor I (GRFI) is a yeast protein that binds in vitro to specific DNA sequences at diverse genetic elements. A strategy was pursued to test whether GRFI functions in vivo at the sequences bound by the factor in vitro. Matches to a consensus sequence for GRFI binding were found in a variety of locations: upstream activating sequences (UASs), silencers, telomeres, and transcribed regions. All occurrences of the consensus sequence bound both crude and purified GRFI in vitro. All binding sites for GRFI, regardless of origin, provided UAS function in test plasmids. Also, GRFI binding sites specifically stimulated transcription in a yeast in vitro system, indicating that GRFI can function as a positive transcription factor. The stimulatory effect of GRFI binding sites at UASs for the PYKI and ENO] genes is significantly enhanced by flanking DNA elements. By contrast, regulatory sequences that flank the GRFI binding site at HMR E convert this region to a transcriptional silencer.
GRF2, an abundant yeast protein of Mr -127,000, binds to the GAL upstream activating sequence (UASc) and creates a nucleosome-free region of -230 bp. Purified GRF2 binds to sequences found in many other UASs, in the 35S rRNA enhancer, at centromeres, and at telomeres. Although GRF2 stimulates transcription only slightly on its own, it combines with a neighboring weak activator to give as much as a 170-fold enhancement. This effect of GRF2 is strongly distance-dependent, declining by 85% when 22 bp is interposed between the GRF2 and neighboring activator sites.
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