Determination of the sequence of an expressible cDNA clone encoding ERp60/calregulin by the use of a novel nested set method

An analysis of the N-terminal sequence of the luminal endoplasmic reticulum protein, ERp60, showed that it was identical to the well-characterized Ca2+-binding protein, calregulin. A full-length, expressible cDNA clone encoding this protein was isolated from a mouse fibroblast cDNA library. A novel nested set strategy for the production of overlapping fragments for DNA sequencing was used to determine the complete nucleotide (nt) sequence of both strands of the ERp60 clone. This method utilizes a series of nonspecific deletion primers in conjunction with a specific site primer to generate the nested set fragments. This procedure possesses several advantages over other nested set techniques, since it does not require (i) the re-cloning of the DNA insert into other vectors, (ii) any prior knowledge of the restriction sites of the nt sequence, or (iii) the transformation and analysis of bacterial subclones. ERp60 has a 17-amino acid (aa) signal sequence and the mature protein contains 399 aa with a calculated M(r) of 46,347.     

Comparative analysis of the Salmonella typhi and Escherichia coli ompC genes

The nucleotide (nt) sequence of the gene encoding the Salmonella typhi OmpC outer membrane protein, and its deduced amino acid (aa) sequence are presented here. The S. typhi ompC gene consists of an open reading frame of 1134 nt, corresponding to a protein of 378 aa; with a 21-aa signal peptide. This protein is 11 aa longer than Escherichia coli OmpC, but it has an identical leader peptide. The mature OmpC sequence shows 79% similarity for both bacteria at the aa level, and 77% similarity at the nt level. Seven main variable regions in the OmpC protein were identified. Five of them correspond to hydrophilic regions and contain aa observed most frequently in turn configurations in soluble proteins. This suggests that these aa stretches could be located on the exterior of the outer membrane. To probe into the genus and species specificity of the main variable regions, we have constructed complementary oligodeoxyribonucleotides. The use of one of them with a small number of DNA samples is illustrated here; no restriction fragment length polymorphism or nt sequence heterogeneity could be found between S. typhi and Salmonella typhimurium.     

Cloning of an activated human ret gene with a novel 5' sequence fused by DNA rearrangement.

By transfecting a high-Mr DNA from human stomach cancer into NIH3T3 cells, a transforming sequence that showed homology with the human ret gene was identified. The transforming sequence was found to be generated by a DNA rearrangement in the human ret proto-oncogene. This rearrangement was suggested to have occurred during the transfection procedure. The nucleotide sequences of cDNAs of the rearranged ret gene and deduced amino acid (aa) sequences revealed that the rearrangement had resulted in recombination of the 3' segment of the ret proto-oncogene with a segment of an unknown human sequence, and that the recombination had generated a novel gene encoding a fusion protein of 435 aa. The rearrangement was presumed to be responsible for activation of the ret gene.     

Molecular cloning and nucleotide sequences of cDNAs specific for rat liver ribosomal proteins S17 and L30

cDNA clones coding for rat liver ribosomal proteins S17 and L30 have been isolated by positive hybridization-translation assay from a cDNA library prepared from 8-9S poly(A)+RNA from free polysomes of regenerating rat liver. The cDNA clone specific for S17 protein (pRS17-2) has a 466-bp insert with the poly(A) tail. The complete amino acid (aa) sequence of S17 protein was deduced from the nucleotide sequence of the cDNA. S17 protein consists of 134 aa residues with an Mr of 15 377. The N-terminal aa sequence of S17 protein determined by automatic Edman degradation is consistent with the sequence data. The aa sequence of S17 shows strong homology (76.9%) to that of yeast ribosomal protein 51 [Teem and Rosbash, Proc. Natl. Acad. Sci. USA 80 (1983) 4403-4407] in the two-thirds N-terminal region. The cDNA clone specific for L30 protein (pRL30) has a 394-bp insert. The aa sequence of L30 protein was deduced from the nucleotide sequence of the cDNA. The protein consists of 114 aa residues with an Mr of 12 652. When compared with the N-terminal aa sequence of rat liver L30 protein [Wool, Annu. Rev. Biochem. 48 (1979) 719-754], pRL30 was found not to contain the initiation codon and 5'-noncoding region. The cDNA showed twelve silent changes in the coding region, one point mutation and one base deletion in the 3'-noncoding region, compared with mouse genomic DNA for L30 protein [Wiedemann and Perry, Mol. Cell Biol. 4 (1984) 2518-2528].     

Human mitochondrial ATP synthase: cloning cDNA for the nuclear-encoded precursor of coupling factor 6

Coupling factor 6 (F6) is a component of mitochondrial ATP synthase which is required for the interactions of the catalytic and proton-translocating segments. A human fetal muscle cDNA clone encoding this protein was isolated by screening a lambda gt10 library with oligodeoxyribonucleotide probes. The 497-bp F6 cDNA included a 96-bp segment that delineated a presequence of 32 amino acids (aa) in the precursor protein, and 140 bp of 3'-untranslated sequence. The remainder of the cDNA sequence coded for a mature human F6 protein of 76 aa. The deduced primary aa sequence showed 81% homology to that of bovine F6, differing in 14 aa. Almost all of these aa substitutions were conservative and comparison of the hydropathy profiles revealed a similar pattern.     

Nucleotide sequence of the alkaline phosphatase gene of Escherichia coli

The nucleotide sequence of the alkaline phosphatase (APase) gene (phoA) of Escherichia coli strain 294 has been determined. Pre-APase has a total of 471 amino acids (aa) including a signal sequence of 21 aa. The derived aa sequence differs from that obtained by protein sequencing by the presence of aspartic acid instead of asparagine at positions 16 and 36, and glutamic acid instead of glutamine at position 197. Two open reading frames (ORF1 and ORF2) located downstream from phoA or upstream from proC have been found. ORF1 encodes a putative presecretory protein of 106 aa with a signal sequence of 21 or 22 aa. If this protein is actually produced, it may be one of the smallest periplasmic proteins in E. coli.     

Human ribosomal protein S3a: cloning of the cDNA and primary structure of the protein.

The amino acid (aa) sequence of human ribosomal protein S3a (hRPS3a) was deduced partially from the nucleotide sequence of the corresponding cDNA and confirmed by direct aa sequencing from the N terminus of the purified hRPS3a protein. The cDNA clone was isolated from a cDNA expression library in the pEX vector using antibodies. The hRPS3a protein has 263 aa and its calculated M(r) is 29 813.     

The primary structure of rat ribosomal protein L9

The amino acid (aa) sequence of rat ribosomal (r) protein L9 was deduced from the nucleotide (nt) sequence in a recombinant cDNA and confirmed from the N-terminal aa sequence of the protein. L9 contains 192 aa and has an Mr of 21879. Hybridization of the cDNA to digests of nuclear DNA suggests that there are 20-23 copies of the L9 gene. The mRNA for the protein is about 800 nt in length. Rat L9 is related to Saccharomyces cerevisiae YL11, Methanococcus vannielii L6, Escherichia coli L6 and other members of the prokaryotic L6 family. The protein contains a possible internal duplication of 11 aa.     

Sequence of a sea urchin hsp70 gene and its 5' flanking region

We report the nucleotide sequence of a 4470-bp fragment derived from a sea urchin genomic clone containing part of a heat-shock protein 70 (Hsp70)-encoding gene. This fragment, named hsp70 gene II, contains 1271 bp of the flanking region and 3299 bp of structural gene sequence interrupted by five introns and encoding the N-terminal 371 amino acids (aa) of the protein. The 5' flanking region contains a putative TATA element, two CCAAT boxes, four heat-shock consensus sequence elements (hse) and one consensus sequence for binding of Sp1. Remarkable homologies were observed for deduced aa sequence and intron-exon organization between hsp70 gene II and rat hsc73 gene.     

Synthesis of an immunopathogenic fusion protein derived from a bovine interphotoreceptor retinoid-binding protein cDNA clone

We have extended the cDNA sequence of bovine interphotoreceptor retinoid-binding protein (IRBP) and subcloned one of the sequenced cDNA fragments into an expression vector. The nucleotide (nt) sequences of four bovine IRBP cDNA clones have been determined. These sequences when assembled cover the 3' proximal 3629 nt of the IRBP mRNA and encode the C-terminal 551 amino acids (aa) of IRBP. This cDNA sequence validates the intron: exon boundaries predicted from the gene. A 2-kb EcoRI insert from lambda IRBP2, one of the clones sequenced, encoding the C-terminal 136 aa of IRBP was subcloned into the expression vector pWR590-1. Escherichia coli carrying this plasmid construction, pXS590-IRBP, produced a fusion protein containing 583 N-terminal aa of beta-galactosidase, three linker aa residues, 136 C-terminal aa of IRBP and possibly a number of additional C-terminal residues due to suppressed termination. This 86-kDa fusion protein, purified by detergent/chaotrope extraction followed by reverse-phase high-performance liquid chromatography, cross-reacted with anti-bovine IRBP on Western blots. This protein induced an experimental autoimmune uveo-retinitis and experimental autoimmune pinealitis in Lewis rats indistinguishable from that induced by authentic bovine IRBP. Thus, it is evident that biological activity of this region of IRBP, as manifested by immuno-pathogenicity, is retained by the fusion protein.     

Isolation and nucleotide sequence of the extracellular acid protease gene (ACP) from the yeast Candida tropicalis

The extracellular acid protease of Candida tropicalis was purified from the supernatant fraction of culture medium containing bovine serum albumin as nitrogen source and the NH2-terminal amino acid (aa) sequence of the protein was determined. The gene for the acid protease (ACP) was isolated using a pool of synthetic oligonucleotides as a probe and a segment of the deduced aa sequence was found to be in agreement with the NH2-terminal aa sequence of the protein. The deduced aa sequence of ACP is similar to the aa sequence of proteases of the pepsin family. The nucleotide sequence of the 5' portion of this gene revealed a coding sequence for a 60 residue propeptide containing two Lys-Arg amino acid pairs that have been identified as sites for peptidase processing of several exported peptides and proteins. The final Lys-Arg site occurs at the junction with the mature extracellular form of the acid protease.     

The human serum amyloid A (SAA)-encoding gene GSAA1: nucleotide sequence and possible autocrine-collagenase-inducer function

We have determined the genomic sequence of the human GSAA1 gene, a member of the family of acute-phase human serum amyloid A (SAA)-encoding genes. This sequence predicts a mature protein of 104 amino acids (aa), several of which differ from residues usually conserved in the sequence of SAA proteins isolated from serum. Despite coding differences, however, the four-exon structure of GSAA1 resembles that of other SAA genes in humans and mice. The N-terminal 25 aa of the mature GSAA1 protein are virtually identical to those of an 'SAA-like' autocrine collagenase inducer produced by rabbit synovial fibroblasts; the latter also differ from the corresponding aa found in SAA in serum. We propose that GSAA1 is the human gene coding for a protein closely related to the SAA, but which is adapted to this important autocrine cytokine function.     

Identification and analysis of novel tandem repeats in the cell surface proteins of archaeal and bacterial genomes using computational tools

We have identified four novel repeats and two domains in cell surface proteins encoded by the Methanosarcina acetivorans genome and in some archaeal and bacterial genomes. The repeats correspond to a certain number of amino acid residues present in tandem in a protein sequence and each repeat is characterized by conserved sequence motifs. These correspond to: (a) a 42 amino acid (aa) residue RIVW repeat; (b) a 45 aa residue LGxL repeat; (c) a 42 aa residue LVIVD repeat; and (d) a 54 aa residue LGFP repeat. The domains correspond to a certain number of aa residues in a protein sequence that do not comprise internal repeats. These correspond to: (a) a 200 aa residue DNRLRE domain; and (b) a 70 aa residue PEGA domain. We discuss the occurrence of these repeats and domains in the different proteins and genomes analysed in this work.     

Biochemical and molecular characterization of the insecticidal fragment of CryV.

Two C-terminal deletion constructs were made to study the effect of such deletions on the biological activity of the CryV protein of Bacillus thuringiensis subsp. kurstaki. The results of feeding on neonatal larvae of Ostrinia nubilalis (European corn borer [ECB]) indicated that the 50% lethal dose of the full-length CryV protein was 3.34 micrograms/g of diet (95% fiducial limits, 2.53 to 4.32 micrograms/g of diet). Removal of 71 amino acids (aa) from the C terminus had little effect on toxicity, whereas deletion of 184 aa abolished the insecticidal activity of the CryV protein completely. Truncations of the full-length CryV protein were also generated with trypsin and the midgut protease of ECB. The proteolytically treated products were characterized by determining their N-terminal amino acid sequences. The CryV protein was found to be cleaved by both proteases through a two-step process. Initially an intermediary form was generated which contained aa 45 of full-length CryV as its N-terminal end. The C-terminal end of this peptide was not experimentally determined. However, analysis of the deduced amino acid sequence of CryV indicated that the C-terminal end of the intermediary form is likely either aa 655 or 659. Further N-terminal processing of the intermediary form resulted in a protease-resistant core form. The core included aa 156 to aa 655 or 659. While the intermediary form retained 100% of the ECB larval toxicity, the core form exhibited only approximately 22% of the toxicity of the full-length protein.     

A second lysine-specific serine protease from Lysobacter sp. strain IB-9374

A second lysyl endopeptidase gene (lepB) was found immediately upstream of the previously isolated lepA gene encoding a highly active lysyl endopeptidase in Lysobacter genomic DNA. The lepB gene consists of 2,034 nucleotides coding for a protein of 678 amino acids. Amino acid sequence alignment between the lepA and lepB gene products (LepA and LepB) revealed that the LepB precursor protein is composed of a prepeptide (20 amino acids [aa]), a propeptide (184 aa), a mature enzyme (274 aa), and a C-terminal extension peptide (200 aa). The mature enzyme region exhibited 72% sequence identity to its LepA counterpart and conserved all essential amino acids constituting the catalytic triad and the primary determining site for lysine specificity. The lepB gene encoding the propeptide and mature-enzyme portions was overexpressed in Escherichia coli, and the inclusion body produced generated active LepB through appropriate refolding and processing. The purified enzyme, a mature 274-aa lysine-specific endopeptidase, was less active and more sensitive to both temperature and denaturation with urea, guanidine hydrochloride, or sodium dodecyl sulfate than LepA. LepA-based modeling implies that LepB can fold into essentially the same three-dimensional structure as LepA by placing a peptide segment, composed of several inserted amino acids found only in LepB, outside the molecule and that the Tyr169 side chain occupies the site in which the indole ring of Trp169, a built-in modulator for unique peptidase functions of LepA, resides. The results suggest that LepB is an isozyme of LepA and probably has a tertiary structure quite similar to it.     

Nucleotide sequence and analysis of the lethal factor gene (lef) from Bacillus anthracis

The nucleotide sequence of the Bacillus anthracis lethal factor (LF) gene (lef) has been determined. LF is part of the tripartite protein exotoxin of B. anthracis along with protective antigen (PA) and edema factor (EF). The apparent ATG start codon, which is located immediately upstream from codons which specify the first 16 amino acids (aa) of the mature secreted LF, is preceded by an AAAGGAG sequence, which is its probable ribosome-binding site. This ATG codon begins a continuous 2427-bp open reading frame which encodes the 809-aa LF-precursor protein with an Mr of 93,798. The mature secreted protein (776 aa; Mr 90,237) was preceded by a 33-aa signal peptide which has characteristics in common with leader peptides for other secreted proteins of the Bacillus species. The codon usage of the LF gene reflects its high (70%) A + T content. The N-terminus of LF (first 300 aa) shared extensive homology with the N-terminus of the anthrax EF protein. Since LF and EF each bind PA at the same site, these homologous regions probably represent their common PA-binding domains.