snRNP Sm proteins share two evolutionarily conserved sequence motifs which are involved in Sm protein-protein interactions.

The spliceosomal small nuclear ribonucleoproteins (snRNPs) U1, U2, U4/U6 and U5 share eight proteins B', B, D1, D2, D3, E, F and G which form the structural core of the snRNPs. This class of common proteins plays an essential role in the biogenesis of the snRNPs. In addition, these proteins represent the major targets for the so-called anti-Sm auto-antibodies which are diagnostic for systemic lupus erythematosus (SLE). We have characterized the proteins F and G from HeLa cells by cDNA cloning, and, thus, all human Sm protein sequences are now available for comparison. Similar to the D, B/B' and E proteins, the F and G proteins do not possess any of the known RNA binding motifs, suggesting that other types of RNA-protein interactions occur in the snRNP core. Strikingly, the eight human Sm proteins possess mutual homology in two regions, 32 and 14 amino acids long, that we term Sm motifs 1 and 2. The Sm motifs are evolutionarily highly conserved in all of the putative homologues of the human Sm proteins identified in the data base. These results suggest that the Sm proteins may have arisen from a single common ancestor. Several hypothetical proteins, mainly of plant origin, that clearly contain the conserved Sm motifs but exhibit only comparatively low overall homology to one of the human Sm proteins, were identified in the data base. This suggests that the Sm motifs may also be shared by non-spliceosomal proteins. Further, we provide experimental evidence that the Sm motifs are involved, at least in part, in Sm protein-protein interactions. Specifically, we show by co-immunoprecipitation analyses of in vitro translated B' and D3 that the Sm motifs are essential for complex formation between B' and D3. Our finding that the Sm proteins share conserved sequence motifs may help to explain the frequent occurrence in patient sera of anti-Sm antibodies that cross-react with multiple Sm proteins and may ultimately further our understanding of how the snRNPs act as auto-antigens and immunogens in SLE.     

The highly conserved amino-terminal region of the protein encoded by the v-myb oncogene functions as a DNA-binding domain.

The retroviral oncogene v-myb encodes a 45,000 Mr nuclear protein (p45v-myb) that is predominantly associated with the chromatin of transformed cells. It has previously been shown that p45v-myb, when released from chromatin by salt-treatment, binds to DNA. To analyse the biochemical properties of p45v-myb in more detail we have expressed the v-myb coding region in Escherichia coli. Our results demonstrate that bacterially expressed myb protein has an intrinsic DNA-binding activity. Using two alternative strategies, (i) inhibition of DNA-binding by monoclonal antibodies and (ii) analysis of DNA-binding activities of partially deleted forms of the bacterial myb protein, we show that the DNA-binding domain is located in the amino-terminal region of the v-myb protein. This region has been highly conserved between myb genes of different species. Our results are therefore consistent with the hypothesis that DNA-binding is an important aspect of myb protein function.     

Crystal structures of human DJ-1 and Escherichia coli Hsp31, which share an evolutionarily conserved domain

Human DJ-1 and Escherichia coli Hsp31 belong to ThiJ/PfpI family, whose members contain a conserved domain. DJ-1 is associated with autosomal recessive early onset parkinsonism and Hsp31 is a molecular chaperone. Structural comparisons between DJ-1, Hsp31, and an Archaea protease, a member of ThiJ/PfpI family, lead to the identification of the chaperone activity of DJ-1 and the proteolytic activity of Hsp31. Moreover, the comparisons provide insights into how the functional diversity is realized in proteins that share an evolutionarily conserved domain. On the basis of the chaperone activity the possible role of DJ-1 in the pathogenesis of Parkinson's disease is discussed.     

The Drosophila doublesex proteins share a novel zinc finger related DNA binding domain.

The doublesex gene of Drosophila melanogaster is the final member of a well characterized hierarchy of genes that controls somatic sex determination and differentiation. The male-specific and female-specific doublesex polypeptides occupy a terminal position in the hierarchy, and thus regulate those genes responsible for the development of sexually dimorphic characteristics of the fly. To investigate the molecular mechanism by which these two related proteins interact with specific target genes, we have identified and characterized their DNA binding domains. Using gel mobility shift experiments with sequentially deleted polypeptides, site-directed mutagenesis and spectrophotometric assays, we have shown that the two doublesex proteins share a common and novel zinc finger-related DNA binding domain distinct from any reported class of zinc binding proteins. We have further shown that of 10 null dsx alleles, six encode proteins deficient in DNA binding activity, and that three of these alleles are the result of mutations that alter cysteine and histidine residues in the metal binding domain. Our results provide evidence that both the male-specific and female-specific doublesex proteins share and depend upon the same DNA binding domain for function in vivo, suggesting that both proteins bind to, but differentially regulate, a common set of genes in both sexes.     

The HORMA domain: an evolutionarily conserved domain discovered in chromatin-associated proteins,has unanticipated diverse functions

The HORMA domain (for Hop1p, Rev7p and MAD2) was discovered in three chromatin-associated proteins in the budding yeast Saccharomyces cerevisiae. This domain has also been found in proteins with similar functions in organisms including plants, animals and nematodes. The HORMA domain containing proteins are thought to function as adaptors for meiotic checkpoint protein signaling and in the regulation of meiotic recombination. Surprisingly, new work has disclosed completely unanticipated and diverse functions for the HORMA domain containing proteins. A. M. Villeneuve and colleagues (Schvarzstein et al., 2013) show that meiosis-specific HORMA domain containing proteins plays a vital role in preventing centriole disengagement during Caenorhabditis elegans spermatocyte meiosis. Another recent study reveals that S. cerevisiae Atg13 HORMA domain acts as a phosphorylation-dependent conformational switch in the cellular autophagic process.     

The tryptophan cluster: a hypothetical structure of the DNA-binding domain of the myb protooncogene product

In the DNA-binding domain of the c-myb protooncogene product (c-Myb) which consists of three repeats of 51-52 amino acids, there are 3 perfectly conserved tryptophans in each repeat. Site-directed mutagenesis of these tryptophans showed that any single or multiple mutations of tryptophan to hydrophilic residues or alanine abolished or greatly reduced the sequence-specific DNA-binding activity, but mutations to hydrophobic amino acids retained considerable activity. Raman spectroscopic study showed that these tryptophans were buried in the protein core. These 3 tryptophans are proposed to form a cluster in the hydrophobic core in each repeat. This hypothetical structure is referred to as the "tryptophan cluster," and it may represent a characteristic property of a group of DNA-binding proteins including the myb- and ets-related proteins.     

Role of conserved residues of the WRKY domain in the DNA-binding of tobacco WRKY family proteins.

Four cDNA clones of tobacco that could code for polypeptides with two WRKY domains were isolated. Among four NtWRKYs and other WRKY family proteins, sequence similarity was basically limited to the two WRKY domains. Glutathione S-transferase fusion proteins with the C-terminal WRKY domain of four NtWRKYs bound specifically to the W-box (TTGACC), and the N-terminal WRKY domain showed weaker binding activity with the W-box compared to the C-terminal domain. The DNA-binding activity of the WRKY domain was abolished by o-phenanthroline and this inhibition was recovered specifically by Zn2+. Substitution of the conserved cysteine and histidine residues of the plant-specific C2H2-type zinc finger-like motif in the WRKY domain abolished the DNA binding. In addition, mutations in the invariable WRKYGQK sequence at the N-terminal side of the zinc finger-like motif also significantly reduced the DNA-binding activity, suggesting that these residues are required for proper folding of the DNA-binding zinc finger.     

Identification of the Otopetrin Domain,a conserved domain in vertebrate otopetrins and invertebrate otopetrin-like family members

Background  

Otopetrin 1 (Otop1) encodes a multi-transmembrane domain protein with no homology to known transporters, channels, exchangers, or receptors. Otop1 is necessary for the formation of otoconia and otoliths, calcium carbonate biominerals within the inner ear of mammals and teleost fish that are required for the detection of linear acceleration and gravity. Vertebrate Otop1 and its paralogues Otop2 and Otop3 define a new gene family with homology to the invertebrate Domain of Unknown Function 270 genes (DUF270; pfam03189).     

Nucleotide sequence of the Wolinella succinogenes flagellin, which contains in the antigenic domain two conserved regions also present in Campylobacter spp. and Helicobacter pylori.

Wolinella succinogenes possesses one polar flagellum, which shows a characteristic surface pattern of parallel lines along the axis of the filament in electron microscopic images. We determined the gene sequence of the Wolinella flagellin, which is, as in most other bacteria, the only structural component of the filament. Sequence comparison with other members of the Proteobacteria revealed two highly conserved regions in the central part of the flagellin molecule among Campylobacter spp. and Helicobacter pylori, an area that had previously been described as highly variable. Similar surface patterns are found in related polarly flagellated bacteria, but not in Escherichia coli and Bacillus subtilis, which also lack these conserved regions.