Primary structure of rat liver mannan-binding protein deduced from its cDNA sequence

cDNA clones encoding rat liver mannan-binding protein (MBP), a lectin specific for mannose and N-acetylglucosamine, were isolated from a rat liver cDNA library carried in lambda gt 11, by screening with affinity purified polyclonal rabbit anti-rat liver MBP antibodies. The nucleotide sequence of the cDNA determined by the dideoxy method revealed the complete amino acid sequence of the MBP (226 residues). The NH2-terminal residue of the MBP, glutamic acid, was preceded by a predominantly hydrophobic stretch of 18 amino acids, which was assumed to be a signal peptide. Near the NH2-terminal, there was a collagen-like domain, which consisted of 19 repeats of the sequence Gly-X-Y. Here, X and Y were frequently proline and lysine. Three proline and lysine residues were hydroxylated, and one of the latter appeared to link to galactose. Computer analysis of several lectins for sequence homology suggested that the COOH-terminal quarter of the MBP is associated with the calcium binding as well as carbohydrate recognition.     

Primary structure of rat liver serine dehydratase deduced from the cDNA sequence

The nucleotide sequence of serine dehydratase mRNA of rat liver has been determined from a recombinant cDNA clone, previously cloned in this laboratory, and from a recombinant cDNA clone screened from a primer-extended cDNA library. The sequence of 1322 nucleotides includes the entire protein coding region and noncoding regions on the 3'- and 5'-sides. The deduced polypeptide consists of 327 amino acid residues with a calculated molecular mass of 34,462 Da. Comparison of the amino acid sequences of the serine dehydratase polypeptide with those of biosynthetic threonine dehydratase of yeast and biodegradative threonine dehydratase of E. coli revealed various extents of homology. A heptapeptide sequence, Gly-Ser-Phe-Lys-Ile-Arg-Gly, which is the pyridoxal-binding site in the yeast and E. coli threonine dehydratases was found as a highly conserved sequence.     

Primary structure of mouse tyrosine hydroxylase deduced from its cDNA.

The cDNAs for tyrosine hydroxylase were cloned from a mouse brain cDNA library by plaque hybridization. Since the longest cDNA clone lacked approximately 150 bp sequence of its N-terminal region, additional 5' region was obtained using polymerase chain reaction. Nucleotide sequence determination of cDNAs revealed that mouse tyrosine hydroxylase m-RNA encodes 498 amino acids with a calculated molecular mass of 55,990. The amino acid sequence of mouse tyrosine hydroxylase is highly homologous to rat (97%) and human (92%) enzymes.     

Primary structure of human proacrosin deduced from its cDNA sequence

cDNA clones encoding proacrosin, the zymogen of acrosin, were isolated from a human testis cDNA library by using a fragment of boar acrosin cDNA as a probe. Nucleotide sequencing of the longest cDNA clone has predicted that human proacrosin is synthesized with a 19-amino-acid signal peptide at the N-terminus. The cleavable signal sequence is followed by a 23-residue segment corresponding to the light chain and then by a 379-residue stretch that constitutes the heavy chain containing the catalytic site of the mature protease. The C-terminal portion of the deduced sequence for the heavy chain is very rich in proline residues, most of which are encoded by a unique repeat of CCCCCA. The active-site residues including histidine, aspartic acid, and serine are also predicted to be located at residues 69, 123, and 221, respectively.     

Primary structure of chicken liver acetyl-CoA carboxylase deduced from cDNA sequence

The complete amino acid sequence of acetyl-CoA carboxylase from chicken liver has been deduced by cloning and sequence analysis of DNA complementary to its messenger RNA. The results were confirmed by Edman degradation of peptide fragments obtained by digestion of the enzyme polypeptide with Achromobacter proteinase I or staphylococcal serine proteinase. Chicken liver acetyl-CoA carboxylase is predicted to be composed of 2,324 amino acid residues, having a calculated molecular weight of 262,706. The biotin carboxyl carrier protein domain is located in the middle region of the enzyme polypeptide. The amino-terminal portion of the acetyl-CoA carboxylase has been found to exhibit a homologous primary structure to that of carbamyl phosphate synthetase. Localization of possible functional domains including biotin carboxylase subsite in the acetyl-CoA carboxylase polypeptide is discussed.     

Primary structure of rat brain prostaglandin D synthetase deduced from cDNA sequence

The amino acid sequence of rat brain prostaglandin D synthetase (Urade, Y., Fujimoto, N., and Hayaishi, O. (1985) J. Biol. Chem. 260, 12410-12415) was determined by a combination of cDNA and protein sequencing. cDNA clones specific for this enzyme were isolated from a lambda gt11 rat brain cDNA expression library. Nucleotide sequence analyses of cloned cDNA inserts revealed that this enzyme consisted of a 564- or 549-base pair open reading frame coding for a 188- or 183-amino acid polypeptide with a Mr of 21,232 or 20,749 starting at the first or second ATG. About 60% of the deduced amino acid sequence was confirmed by partial amino acid sequencing of tryptic peptides of the purified enzyme. The recognition sequence for N-glycosylation was seen at two positions of amino acid residues 51-53 (-Asn-Ser-Ser-) and 78-80 (-Asn-Leu-Thr-) counted from the first Met. Both sites were considered to be glycosylated with carbohydrate chains of Mr 3,000, since two smaller proteins with Mr 23,000 and 20,000 were found during deglycosylation of the purified enzyme (Mr 26,000) with N-glycanase. The prostaglandin D synthetase activity was detected in fusion proteins obtained from lysogens with recombinants coding from 34 and 19 nucleotides upstream and 47 and 77 downstream from the first ATG, indicating that the glycosyl chain and about 20 amino acid residues of N terminus were not essential for the enzyme activity. The amino acid composition of the purified enzyme indicated that about 20 residues of hydrophobic amino acids of the N terminus are post-translationally deleted, probably as a signal peptide. These results, together with the immunocytochemical localization of this enzyme to rough-surfaced endoplasmic reticulum and other nuclear membrane of oligodendrocytes (Urade, Y., Fujimoto, N., Kaneko, T., Konishi, A., Mizuno, N., and Hayaishi, O. (1987) J. Biol. Chem. 262, 15132-15136) suggest that this enzyme is a membrane-associated protein.     

Primary structure of cold-adapted alkaline phosphatase from a Vibrio sp. as deduced from the nucleotide gene sequence

Alkaline phosphatases (AP) are widely distributed in nature, and generally have a dimeric structure. However, there are indications that either monomeric or multimeric bacterial forms may exist. This paper describes the gene sequence of a psychrophilic marine Vibrio AP, previously shown to be particularly heat labile. The kinetic properties were also indicative of cold adaptation. The amino acid sequence of the Vibrio G15-21 AP reveals that the residues involved in the catalytic mechanism, including those ligating the metal ions, have precedence in other characterized APs. Compared with Escherichia coli AP, the two zinc binding sites are identical, whereas the metal binding site, normally occupied by magnesium, is not. Asp-153 and Lys-328 of E. coli AP are His-153 and Trp-328 in Vibrio AP. Two additional stretches of amino acids not present in E. coli AP are found inserted close to the active site of the Vibrio AP. The smaller insert could be accommodated within a dimeric structure, assuming a tertiary structure similar to E. coli AP. In contrast the longer insert would most likely protrude into the interface area, thus preventing dimer formation. This is the first primary structure of a putative monomeric AP, with indications as to the basis for a monomeric existence. Proximity of the large insert loop to the active site may indicate a surrogate role for the second monomer, and may also shape the catalytic as well as stability characteristics of this enzyme.     

Primary structure of sweet potato starch phosphorylase deduced from its cDNA sequence

Sweet potato (Ipomoea batatas) starch phosphorylase cDNA clones were isolated by screening an expression library prepared from the young root poly(A)⁺ RNA successively with an antiserum, a monoclonal antibody, and a specific oligonucleotide probe. One cDNA clone had 3292 nucleotide residues in which was contained an open reading frame coding for 955 amino acids. This sequence was compared with those of potato (916 residues plus 50-residue putative transit peptide) and rabbit muscle (841 residues) phosphorylases. The sweet potato phosphorylase has an overall structural feature highly homologous to that reported for potato phosphorylase, in conformity with the finding that they belong to the same class of plant phosphorylase. High divergencies of the two enzymes are found in the about 70 residue N-termini each including a putative transit peptide, and the midchain 78 residue insert typical of type I plant phosphorylase. We consider that the very high dissimilarity found in the midchain inserts is related to the difference in proteolytic lability of the two plant phosphorylases. Some structural features of the cDNA clone were also discussed.     

Primary structure of a lipoxygenase from barley grain as deduced from its cDNA sequence

A full length cDNA sequence for a barley grain lipoxygenase was obtained. It includes a 5′ untranslated region of 69 nucleotides, an open reading frame of 2586 nucleotides encoding a protein of 862 amino acid residues and a 3′ untranslated region of 142 nucleotides. The molecular mass of the encoded polypeptide was calculated to be 96.392. Its amino acid sequence shows a high homology with that of other plant lipoxygenases identified to date.     

The sexual inducer of Volvox carteri. Primary structure deduced from cDNA sequence

The primary structure of the sexual inducer of Volvox carteri f. nagariensis has been deduced by cloning and sequence analysis of cDNA. The sexual inducer contains 208 amino acids including a signal sequence. A total of six potential N-glycosylation sites are found within the polypeptide chain. At the genomic level, the sexual inducer protein is encoded in five exons.     

Plasma cell membrane glycoprotein PC-1. Primary structure deduced from cDNA clones

The PC-1 protein is a membrane glycoprotein that is selectively expressed on the surface of antibody-secreting cells. Previous work has shown that it consists of two apparently identical disulfide-bonded polypeptides, each of molecular weight approximately 120,000. We now describe the sequence of PC-1 mRNA and protein. The PC-1 protein is shown to consist of 905 amino acids and to have an uncommon transmembrane orientation. The NH2-terminal 58 residues are intracellular and the COOH-terminal 826 residues are extracellular. A cysteine-rich region of 85 amino acids lies adjacent to the extracellular surface of the membrane and appears to have arisen by exon duplication. In common with other membrane glycoproteins with this orientation, there is no obvious signal sequence other than the transmembrane segment. The PC-1 protein therefore has an overall structure and membrane orientation that resembles those of the transferrin receptor, the asialoglycoprotein receptor, and the Ia invariant chain.     

Primary structure of rat pulmonary surfactant protein D. cDNA and deduced amino acid sequence.

Surfactant protein D (SP-D) is a carbohydrate-binding glycoprotein containing a collagen-like domain that is synthesized by alveolar type II epithelial cells. The complete primary structure of rat SP-D has been determined by sequencing of a cloned cDNA. The protein consists of three regions: an NH2-terminal segment of 25 amino acids, a collagen-like domain consisting of 59 Gly-X-Y repeats, and a COOH-terminal carbohydrate recognition domain of 153 amino acids. There are 6 cysteine residues present in rat SP-D: 2 in the NH2-terminal noncollagenous segment and 4 in the COOH-terminal carbohydrate-binding domain. The collagenous domain contains one possible N-glycosylation site. The protein is preceded by a cleaved, NH2-terminal signal peptide. SP-D shares considerable homology with the C-type mammalian lectins. Hybridization analysis demonstrates that rat SP-D is encoded by a 1.3-kilobase mRNA which is abundant in lung and highly enriched in alveolar type II cells. Extensive homology exists between rat SP-D and bovine conglutinin.     

Primary structure of human preangiotensinogen deduced from the cloned cDNA sequence

Cloned cDNA sequences for human preangiotensinogen have been isolated from a human liver cDNA library by hybridization with a restriction fragment derived from a previously cloned cDNA for rat preangiotensinogen. Analyses by nucleotide sequence determination, S1 nuclease mapping, and RNA blot hybridization indicate that human preangiotensinogen is encoded by two mRNAs that differ only in the length of the 3'-untranslated region. The deduced amino acid sequence shows that the mature angiotensinogen consists of 452 amino acid residues with the angiotensin sequence at its amino-terminal portion. Two potential initiation sites have been discussed. These are the methionine codon located at the position exactly corresponding to the initiation site of rat preangiotensinogen mRNA and an additional methionine codon positioned nearest the 5' end of the mRNA. The amino acid sequences starting at either of the initiation sites and preceding the angiotensin sequence constitute a large number of hydrophobic amino acid residues, thus representing the signal peptide characteristic of the secretory proteins. Human and rat preangiotensinogens show that 63.6% of the amino acid positions of the two proteins are identical. However, the amino-terminal portions directly distal to angiotensin I diverge markedly between the two proteins and differ in their possible glycosylation sites. These structural differences may contribute to the known species specificity exhibited by renin.     

Primary structure of sheep prostaglandin endoperoxide synthase deduced from cDNA sequence

The complete amino acid sequence of prostaglandin endoperoxide synthase from sheep vesicular gland has been deduced by cloning and sequence analysis of DNA complementary to its messenger RNA. The results were confirmed by digestion of the enzyme with carboxypeptidase Y and by automated Edman degradation of the intact enzyme polypeptide and peptide fragments obtained by limited proteolysis of the enzyme with Achromobacter proteinase I. Mature sheep prostaglandin endoperoxide synthase is shown to be composed of 576 amino acids with an Mr of 66,175. The precursor peptide is predicted to contain a 24-residue signal peptide. The serine residue susceptible to acetylation by aspirin is found to be located near the C-terminus of the enzyme polypeptide.