Primary structure of three minor isoforms of amphioxus sarcoplasmic calcium-binding proteins.

Previously we reported the amino acid sequences of 4 well-defined sacroplasmic, high-affinity Ca(2+)-binding proteins in the protochordate amphioxus, Branchiostoma lanceolatum [1]. Here we report on the complete amino acid sequence determination of 3 additional minor isoforms. The seven isoforms differ from each other in 9 positions of a contiguous 17-residue-long segment (positions 20-36) and can be classified in a alpha (ASCP I, III and IV) and a beta lineage (ASCP II, V, VI and VII).     

Actin gene family of Caenorhabditis elegans

Four actin genes have been isolated from Caenorhabditis elegans that account for all of the major actin hybridization to total genomic DNA. Actin genes I, II and III are clustered within a 12 X 10(3) base region; gene IV is unlinked to the others. All four genes have been sequenced from at least nucleotide -109 to +250. Genes I and III are identical for the first 307 coding nucleotides. Genes I and II differ in 14 positions within the first 250 coding nucleotides; one difference substitutes an aspartic acid for a glutamic acid at codon 5. Genes I and IV differ in 18 positions within the first 259 coding nucleotides without causing any amino acid differences. Genes I, II and III have introns after the first nucleotide of codon 64 and gene IV has an intron between codons 19 and 20. The four nucleotide sequences thus far define two different amino acid sequences. Both of the amino acid sequences resemble vertebrate cytoplasmic actin more than vertebrate muscle actin. A DNA polymorphism between the Bristol and Bergerac strains has been used as a phenotypic marker in genetic crosses to map the cluster of actin genes within a 2% recombination interval on linkage group V between unc-23 and sma-1 in order to begin a molecular genetic analysis of the actin loci.     

Cloning and cDNA sequence analysis of Lys(49) and Asp(49) basic phospholipase A(2) myotoxin isoforms from Bothrops asper

Snake venom myotoxic phospholipases A(2) contribute to much of the tissue damage observed during envenomation by Bothrops asper, the major cause of snake bites in Central America. Several myotoxic PLA(2)s have been identified, but their mechanism of myotoxicity is still unclear. To aid in the molecular characterization of these venom toxins, the complete open reading frames encoding two Lys(49) and one Asp(49) basic PLA(2) myotoxins from the Central American snake B. asper (terciopelo) were obtained by cDNA cloning from venom gland poly-adenylated RNA. The amino acid sequence deduced from the myotoxins II and III open reading frames corresponded in each case to one of the reported amino acid sequence isoforms. The sequence of a new myotoxin IV-like sequence (MT-IVa) contains conservative Val-->Leu(18) and Ala-->Val(23) substitutions when compared with the reported N-terminus of the native myotoxin IV, suggesting minor isoform variations among specimens of a single species. Sequence alignment studies indicated significant (>75% sequence identity) identities with other crotalid venom Lys(49) PLA(2)s, particularly bothropstoxin I/Ia isoforms of B. jararacussu and myotoxin II of B. asper.     

The primary structure of human plasma high density apolipoprotein glutamine I (ApoA-I). II. The amino acid sequence and alignment of cyanogen bromide fragments IV, III, and I.

Apolipoprotein glutamine I (apoLP-Gln-I or apoA-I) is the major protein constituent of the human plasma high density lipoproteins. Cleavage of this protein with cyanogen bromide yields four fragments, designated in the order of elution from Bio-Gel P-30 as CNBr I, II, III, and IV. In the first paper in this series, the amino acid sequence of the NH2-terminal fragment, CNBr II, is reported. In the present study, CNBr IV, III, and I, containing, respectively, 25, 36, and 94 amino acids were sequenced by conventional means. To establish the alignment of the cyanogen bromide fragments, apoLP-Gln-I was digested with trypsin and two of the three methionine-containing tryptic peptides were isolated. The amino acid sequence of apoLP-Gln-I is as follows: (see article). With the complete amino acid sequence available, a CPK space-filling model of apoLP-Gln-I was constructed. The protein was placed into an alpha helical conformation wherever the primary structure permitted. Thirteen helical regions were identified. These regions account for 70% of the amino acid residues of the protein. Each helix is characterized as having two faces (amphipathic). One is a polar face that occupies approximately 180 degrees of the surface of the helix and the other is a hydrophobic face that occupies the other 180 degrees of the helical surface. Similar amphipathic helices have been identified previously in the other lipoprotein-proteins that have known sequences. It is suggested that the amphipathic helical regions of apoLP-Gln-I are important in the binding of phospholipids in high density lipoproteins.     

Amino acid sequence of a major globin from the sea cucumber Paracaudina chilensis

The sea cucumber Paracaudina chilensis (Echinodermata) contains three major globins I, II and III in coelomic cells. The complete amino acid sequence of globin I has been determined. It is composed of 157 amino acid residues, is acetylated at the N-terminus, and has a characteristic N-terminal extension of 9-10 residues when compared with vertebrate globins. The sequence of Paracaudina globin I showed slightly higher homology with human alpha globin (25%) rather than with the invertebrate Anadara alpha globin (22%). Paracaudina globin I also showed strong homology (59%) with globin D from another sea cucumber, Molpadia arenicola (Mauri, F.C. (1985) Ph.D. dissertation, University of Texas). The globin sequences from the phylum Echinodermata have an important position in the molecular evolution of the globins, because they are the invertebrate group most closely related to the vertebrates.     

Trypsin Inhibitor Polymorphism: Multigene Family Expression and Posttranslational Modification

Trypsin inhibitors from winter pea seeds (c.v. Frilene) have been purified and shown to consist of six protease inhibitors (PSTI I, II, III, IVa, IVb, and V). Based on amino acid composition, molecular mass, and N-terminal sequence, the six inhibitors are closely related to one another and belong to the Bowman–Birk family of inhibitors. To define the relations among them, molecular mass and amino acid composition of peptides obtained from digestion with trypsin were determined. The sequence and the biosynthetic mechanism of the isoform formation have been partially resolved for four major isoforms. Two isoinhibitor forms (PSTI IVa, IVb) in pea seeds are due to expression of two distinct genes; PSTI IVa has four amino acid replacements when its sequence is compared with the sequence of PSTI IVb. Two others (PSTI I, II) result from posttranslational proteolytic cleavage of nine C-terminal residues of forms PSTI IVa and IVb, respectively.     

Complete nucleotide sequence of human phosphoribosyl pyrophosphate synthetase subunit I (PRS I) cDNA and a comparison with human and rat PRPS gene families.

cDNA clones for human phosphoribosyl pyrophosphate synthetase subunit I (PRS I) were isolated from a glioblastoma cell line MGC 1 cDNA library. The longest clone contained 2,075 base pairs (bp) almost covering the 2.3-kb mRNA and the base sequence of the coding region (954 bp) had a 92.0% sequence homology with that of rat PRS I cDNA. The deduced amino acid sequences were identical between human and rat PRS I. This perfect conservation has heretofore not been reported for other enzymes involved in nucleotide metabolism and glycolysis. A comparison with other isoforms of this enzyme, PRS II and PRS III, showed that the human PRS I was 79.9 and 92.2% homologous in the coding sequence and 95.3 and 94.0% in the deduced amino acid sequence to human PRS II and PRS III, respectively. The high value of the synonymous difference between PRS I and PRS II cDNAs places their time of divergence long before that of the radiation of mammals. Based on the evolutionary rate of amino acid substitution, the PRS I and II genes probably diverged about 760 million years ago.     

The amino acid sequence of toxin IV from the Androctonus australis scorpion: differing effects of natural mutations in scorpion alpha-toxins on their antigenic and toxic properties.

The complete amino acid sequence (64 residues) of the AaH IV toxin from the scorpion Androctonus australis Hector was determined by automated Edman degradation and was compared with the sequences of other Androctonus toxins. AaH IV was also tested by radioimmunoassay for binding to antisera raised against other toxins of the same species. The results indicated that AaH IV shares some of the antigenic properties of AaH I and AaH III toxins, but does not cross-react with anti-AaH II antibodies. The structural basis for the observed antigenic relationships can be found in the high degree of homology displayed by AaH IV with regard to AaH I and III, the changes in amino acid residues equally affecting regions included or excluded from the main predicted antigenic sites of AaH IV. The lower biological potency of AaH IV is presumably the result of some of the sequence differences. In particular, substitution affecting the charge and bulkiness of residue 61 could account for the poor receptor binding and consequential weak toxic properties of this molecule.     

Isolation and characterization of multiple forms of rat liver UDP-glucuronate glucuronosyltransferase.

UDP-glucuronosyltransferase (EC 2.4.1.17) activity was solubilized from male Wistar rat liver microsomal fraction in Emulgen 911, and six fractions with the transferase activity were separated by chromatofocusing on PBE 94 (pH 9.4 to 6.0). Fraction I was further separated into Isoforms Ia, Ib and Ic by affinity chromatography on UDP-hexanolamine-Sepharose 4B. UDP-glucuronosyltransferase in Fraction III was further purified by rechromatofocusing (pH 8.7 to 7.5). UDP-glucuronosyltransferases in Fractions IV and V were purified by UDP-hexanolamine-Sepharose chromatography. The transferase isoforms in Fractions II, III, IV and V were finally purified by h.p.l.c. on a TSK G 3000 SW column. Purified UDP-glucuronosyltransferase Isoforms Ia (Mr 51,000), Ib (Mr 52,000), Ic (Mr 56,000), II (Mr 52,000), IV (Mr 53,000) and V (Mr 53,000) revealed single Coomassie Blue-stained bands on sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. Isoform III enzyme showed two bands of Mr 52,000 and 53,000. Comparison of the amino acid compositions by the method of Cornish-Bowden [(1980) Anal. Biochem. 105, 233-238] suggested that all UDP-glucuronosyltransferase isoforms are structurally related. Reverse-phase h.p.l.c. of tryptic peptides of individual isoforms revealed distinct 'maps', indicating differences in primary protein structure. The two bands of Isoform III revealed distinct electrophoretic peptide maps after limited enzymic proteolysis. After reconstitution with phosphatidylcholine liposomes, the purified isoforms exhibited distinct but overlapping substrate specificities. Isoform V was specific for bilirubin glucuronidation, which was not inhibited by other aglycone substrates. Each isoform, except Ia, was identified as a glycoprotein by periodic acid/Schiff staining.     

The primary structure of human plasma high density apolipoprotein glutamine I (ApoA-I). I. The amino acid sequence of cyanogen bromide fragment II.

Apolipoprotein glutamine I (apoLP-Gln-I or apoA-I) is one of the major protein constituents of human plasma high density lipoproteins. The protein has 245 amino acid residues, including 3 residues of methionine, and is lacking isoleucine, cystine, and cysteine. Cleavage of apoLP-Gln-I with cyanogen bromide yields four fragments, designated in their order of elution from Bio-Gel P-30 as CNBr I, II, III, and IV. In the present study, we report the complete amino acid sequence of the NH2-terminal fragment, CNBr II, a peptide that contains 90 amino acid residues.     

The primary structure of histone H3 from the nematode Caenorhabditis elegans

The complete amino acid sequence of histone H3 (135 residues) from the nematode Caenorhabditis elegans has been established. Microheterogeneity occurs at positions 96 and 100 of the chain. The sequences of the nematode H3 isoforms are very similar to the major chain of calf thymus H3 with which they show 4 substitutions in total. The major variant has cysteine in position 96. This is the first report of cysteine in this position in H3 from non-mammalian tissue. An exceptional methylation site has been detected at position 79. Various other sites of secondary modification are of a conservative nature.     

Comparative Study of Kallikrein-Like Serine Proteinases from Rat Submandibular Glands

Abstract

The present investigation describes the comparative properties, particularly the substrate specificity of three kallikrein-like serine proteinases (I, II and III) purified from rat submandibular gland extract (Bedi, G.S., Prep. Biochem. 22, 67–81. 1992). The physico-chemical and immunological properties of three proteinases were compared by Western blot analysis, immunodiffusion, immuno-electrophoresis, amino terminal sequence analysis, molecular weight determination and isoelectric focusing. Detailed substrate specificity of these proteinases was determined using chromogenic substrates, synthetic peptides and native proteins. The chromogenic substrate tosyl-gly-pro-arg-pNA was hydrolyzed preferentially by Proteinase I. The replacement of pro at the P2 position with bulky hydrophobic residues phe and leu completely abolished the hydrolysis by Proteinase I. The hydrolysis of the chromogenic substrates by Proteinase II was also affected by the amino acid residue present at the P2 position in the order of pro>gly>val>leu>phe. Neither Proteinase I nor Proteinase II hydrolyzed substrates in which arg was replaced with lys at the P1 position. Proteinase III was reactive against all the chromogenic substrates with arg or lys at the P1 position. Synthetic polypeptides T-kinin-leu and insulin B chain were resistant to cleavage by both Proteinase I and II and were cleaved specifically at arg-X peptide bond by Proteinase III. Tonin-like activity of Proteinase II was confirmed by cleavage of the angiotensin 1–14 at phe-his linkage to generate two fragments DRVYIHPF and HLLVYS respectively. All three proteinases cleaved human high molecular weight kininogen but only Proteinase III could cleave T-kininogen. Proteinase III was also reactive towards human and bovine fibronectin, fibrinogen and gelatin. Several other salivary and serum proteins were resistant to cleavage by these proteinases. Although the three enzymes are immunologically related, they differ with respect to size, isoelectric point, amino terminal sequence and inhibition profile.     

Comparison of the amino acid sequences of the variable regions of light chains derived from two homogeneous rabbit anti-pneumococcal antibodies

The amino acid sequence of the N-terminal 139 residues of the L (light) chain derived from a homogeneous rabbit antibody to type III pneumococci was determined. This L chain, designated BS-5, exhibits a greater degree of homology with the basic sequence of human kappa chains of subgroup I (72%) than with subgroups II and III. L-chain BS-5 differs from another L chain (BS-1), also derived from an antibody to type III pneumococci (Jaton, 1974), by eight amino acid residues, even though the chains are identical within the N-terminal 30 residues. Six of these eight substitutions are located within the three hypervariable sections of the variable half: Asn/Ser in position 31, Glu/Ala in position 55, Asx/Thr, Thr/Gly, Thr/Gly and Val/Tyr in positions 92, 94, 96 and 97 respectively. The two anti-pneumococcal L chains BS-1 and BS-5 are much more similar to each other than to an anti-azobenzoate L chain (Appella et al., 1973), from which they differ by 30 and 29 residues respectively. Of these interchanges 13-15 are confined to the three hypervariable sections, and 11 occur within the N-terminal 27 positions. The three chains have an identical sequence from residue 98 to residue 139, except for a possible inversion of two residues in positions 130-131 of the anti-azobenzoate chain.     

Purification and characterization of isoforms of beta-galactosidases in mung bean seedlings

Five isoforms of beta-galactosidase (EC 3.2.1.23), designated as beta-galactosidases I-V, were isolated from five-day-old mung bean (Vigna radiata) seedlings. Beta-galactosidases II and III were purified to electrophoretic homogeneity by a procedure involving acid precipitation, ammonium sulfate fractionation, chromatography on diethylaminoethyl-cellulose (DEAE-Cellulose) and con A-Sepharose. and chromatofocusing. Beta-galactosidases I, II and III have the same molecular mass of 87 kDa. comprising two nonidentical subunits with molecular masses of 38 and 48 kDa, while beta-galactosidases IV and V have molecular masses of 45 and 73 kDa, respectively. All the enzymes were active against p-nitrophenyl-beta-D-galactoside, and to a lesser extent, p-nitrophenyl-alpha-L-arabinoside and p-nitrophenyl-beta-D-fucoside. The enzymes were inhibited by D-galactono-1,4-lactone, D-galactose, Hg2+, Ag+ and sodium dodecyl sulfate (SDS). Beta-galactosidases I, II and III were shown to be competitively inhibited by either D-galactono-1, 4-lactone or D-galactose. Isoforms I, II and III have a common optimal pH of 3.6, while isoforms IV and V have pH optima at 3.8 and 4.0, respectively. Isoelectric points of isoforms I, II and III were 7.7, 7.5 and 7.3, respectively. Double immunodiffusion analysis indicated that beta-galactosidases I, II, III and V are immunologically similar to each other, while beta-galactosidase IV shares partially identical antigenic determinants with the other four isoforms. The purified beta-galactosidases II and III were capable of releasing D-galactose residue from the hemicellulose fraction isolated from mung bean seeds.     

Characterization of novel GPCR gene coding locus in amphioxus genome: gene structure, expression, and phylogenetic analysis with implications for its involvement in chemoreception

Chemosensation is the primary sensory modality in almost all metazoans. The vertebrate olfactory receptor genes exist as tandem clusters in the genome, so that identifying their evolutionary origin would be useful for understanding the expansion of the sensory world in relation to a large-scale genomic duplication event in a lineage leading to the vertebrates. In this study, I characterized a novel GPCR (G-protein-coupled receptor) gene-coding locus from the amphioxus genome. The genomic DNA contains an intronless ORF whose deduced amino acid sequence encodes a seven-transmembrane protein with some amino acid residues characteristic of vertebrate olfactory receptors (ORs). Surveying counterparts in the Ciona intestinalis (Asidiacea, Urochordata) genome by querying BLAST programs against the Ciona genomic DNA sequence database resulted in the identification of a remotely related gene. In situ hybridization analysis labeled primary sensory neurons in the rostral epithelium of amphioxus adults. Based on these findings, together with comparison of the developmental gene expression between amphioxus and vertebrates, I postulate that chemoreceptive primary sensory neurons in the rostrum are an ancient cell population traceable at least as far back in phylogeny as the common ancestor of amphioxus and vertebrates.     

Amino acid sequences of three phospholipases A I, III and IV from the venom of the sea snake Laticauda semifasciata.

Amino acid sequences of three phospholipases A, I, III and IV, from the venom of the sea snake Laticauda semifasciata were elucidated. Each protein consisted of a single chain of 118 amino acid residues, including 14 half-cystine residues. They showed high homology among themselves, and with the other snake-venom phospholipases A and with the enzymes from mammalian pancreas. Phospholipases A III and IV were especially similar to each other, with only four differences out of their 118 amino acid residues. Phospholipase A I contained one tryptophan residue at position 64, which was important for enzymic activity, whereas III and IV did not contain tryptophan residues and their corresponding positions were occupied by leucine residues. The substitution by leucine resulted in a decreased, but definite, phospholipase A activity. The substituted enzymes have a more potent neuromuscular blocking activity. Full experimental details and evidence for the amino acid sequences of the proteins have been deposited as Supplementary Publication SUP 50118 (39 pages) at the British Library Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem.J. (1981) 193, 5.     

The multiple RNA-binding domains of the mRNA poly(A)-binding protein have different RNA-binding activities.

The poly(A)-binding protein (PABP) is the major mRNA-binding protein in eukaryotes, and it is essential for viability of the yeast Saccharomyces cerevisiae. The amino acid sequence of the protein indicates that it consists of four ribonucleoprotein consensus sequence-containing RNA-binding domains (RBDs I, II, III, and IV) and a proline-rich auxiliary domain at the carboxyl terminus. We produced different parts of the S. cerevisiae PABP and studied their binding to poly(A) and other ribohomopolymers in vitro. We found that none of the individual RBDs of the protein bind poly(A) specifically or efficiently. Contiguous two-domain combinations were required for efficient RNA binding, and each pairwise combination (I/II, II/III, and III/IV) had a distinct RNA-binding activity. Specific poly(A)-binding activity was found only in the two amino-terminal RBDs (I/II) which, interestingly, are dispensable for viability of yeast cells, whereas the activity that is sufficient to rescue lethality of a PABP-deleted strain is in the carboxyl-terminal RBDs (III/IV). We conclude that the PABP is a multifunctional RNA-binding protein that has at least two distinct and separable activities: RBDs I/II, which most likely function in binding the PABP to mRNA through the poly(A) tail, and RBDs III/IV, which may function through binding either to a different part of the same mRNA molecule or to other RNA(s).