Isolation and nucleotide sequence of a full-length cDNA coding for aldolase B from human liver.

Two recombinant clones, pA2 and pA3, containing cDNA sequences for human aldolase B have been isolated from a full length human liver cDNA library. The larger one, pA3, has been subcloned in M13 phage and completely sequenced with the chain terminator method. The sequence covers 1,600 nucleotides including the whole coding region (1,050 nucleotides), 67 nucleotides from the 5' non-coding region and the whole 3' non-coding region, 440 nucleotides long, down to the poly-A tail. Comparison with rabbit aldolase A and with a partial sequence of rat aldolase B, shows a homology of about 76% for aldolase A and of about 94% for aldolase B, which indicates that the sequenced cDNA codes for the liver isoenzyme. This is the first complete sequence reported for human aldolase B. The pA3 clone strongly hybridizes to 18S mRNA from human adult liver as expected from the size of the isolated cDNA.     

Rat aldolase A messenger RNA: the nucleotide sequence and multiple mRNA species with different 5'-terminal regions

The nucleotide sequence of aldolase A mRNA in rat skeletal muscle was determined using recombinant cDNA clones and a cDNA synthesized by primer extension. The sequence is composed of 1343 nucleotides (nt) except for the poly(A) tail. Based on the sequence analysis we have deduced an open reading frame with 363 amino acids (aa) (Mr 39134). The sequence suggests several nt polymorphisms in the mRNA population, one of which causes an aa change. The determined sequence of rat aldolase A mRNA was compared with the published ones of rabbit aldolase A or rat aldolase B mRNAs. The homology between rat and rabbit aldolase A mRNA sequences is greater than that between rat aldolase A and B mRNA sequences. Multiple aldolase A mRNAs having different Mrs were detected in the various tissues, and appeared to be expressed in a tissue-specific manner. Further analysis suggests that differences in mRNA length are due to differences in the 5'-noncoding terminal region.     

Molecular cloning and sequence analysis of full-length cDNA for rabbit liver NADPH-cytochrome P-450 reductase mRNA

The nucleotide sequence of the mRNA for NADPH-cytochrome P-450 reductase from rabbit liver was determined from a full-length cDNA clone (pFP105). The clone contains 2,269 nucleotides complementary to rabbit liver reductase mRNA. The single open reading frame of 2,037 nucleotides codes for a 679-amino acid polypeptide with a calculated molecular weight of 76,583 daltons. The cloned cDNA contains the complete 3'-noncoding region of 193 nucleotides, including 68 nucleotides of poly(A), and 39 nucleotides of the 5'-noncoding region. The nucleotide sequence in the coding region of cDNA of rabbit reductase (pFP105) showed 85% homology to that of rat reductase (Porter, T.D. & Kasper, C.B. (1985) Proc. Natl. Acad. Sci. U.S. 82, 973-977, and Murakami, H. et al. (1986) DNA 5, 1-10). Rabbit reductase has one more amino acid residue than the rat enzyme, and the amino acid compositions of the two enzymes are similar. The amino acid sequence of the rabbit enzyme showed 91% identity with that of the rat enzyme. The segment related to binding of FMN and FAD was well conserved among rabbit, rat, and pig reductases. The sequence related to AMP moiety-binding was also conserved among these species, and was found in the amino acid sequence of NADH-cytochrome b5 reductase, another flavoenzyme in the microsomal electron transport system.     

Rat aldolase isozyme gene

Rat aldolase B mRNA was partially purified from liver polysomes by an immunochemical technique followed by oligo(dT)-cellulose column chromatography. Double-stranded cDNA, synthesized from this mRNA, was inserted into the PstI site of plasmid pBR322 employing the oligo(dC)-oligo(dG) tailing method. Clones containing aldolase B cDNA inserts were selected by colony hybridization using 32P-labeled purified mRNA as a specific probe. Several recombinant plasmids containing 600 to 1000 base pair inserts were isolated. Hybrid selection-translation experiments showed that they hybridize specifically with aldolase B mRNA. By overlapping restriction maps of several individual cDNA inserts, it was found that they spanned 1200 base pairs, which represented about 70% of the aldolase B mRNA sequence. The nucleotide sequence of the cDNA was then determined and the sequence of 180 amino acids from the COOH terminus and the entire 3' untranslatable nucleotide sequence were clarified. Although the complete amino acid sequence of rat aldolase B has not yet been reported, it was found that several amino acids neighboring the COOH-terminal tyrosine obtained by carboxypeptidase digestion completely coincided with those determined from the cDNA sequence; i.e. -Ser-Leu-Phe-Thr-Ala-Ser-Tyr-Thr-Tyr. Furthermore, a putative active site peptide appeared and is extensively homologous to those of rabbit aldolases A and B.     

Complete nucleotide sequence of ovine alpha-lactalbumin mRNA

The nucleotide sequence of ovine alpha-lactalbumin mRNA has been determined by chemical sequencing of two cDNA recombinant plasmids and a primer extension product. Ovine alpha-lactalbumin mRNA contains 723 nucleotides (excluding the poly(A) tail), with a 5' non-coding region of 26 nucleotides, followed by the 426 nucleotides of the coding region which determines a sequence signal of 19 amino acid residues and the 123 amino acid residues of mature alpha-lactalbumin. The coding region is followed by a 3' untranslated sequence of 271 nucleotides. The derived amino acid sequence of ovine pre-alpha-lactalbumin differs from that of its bovine counterpart by 8 amino acid substitutions, all but one originating from single mutations. Comparison of sequences of guinea pig, rat and human alpha-lactalbumin mRNAs with their ovine and bovine counterparts has revealed that these molecules have rapidly evolved. The highest degree of conservation was observed in the region coding for the mature protein and corresponds essentially to sequences which interact with UDP-galactosyltransferase and Ca2+ ions.     

Tissue-specific expression of rat aldolase A mRNAs. Three molecular species differing only in the 5'-terminal sequences

Three species of aldolase A mRNA (mRNAs I, II, and III) only differing in the structure of the 5'-terminal noncoding region were detected in rat tissues. The cDNA clones for mRNAs II and III were prepared from ascites hepatoma AH60C and sequenced. The mRNA II is 1393 nucleotides long excluding poly(A) tail, while the mRNA III is 1440 nucleotides long, some 50 nucleotides longer than the mRNA II. The mRNAs II and III differ in the sequence between -25 and the 5' termini from the previously reported skeletal muscle aldolase A mRNA (mRNA I, 1343 nucleotides long). By contrast, the residual 5' noncoding sequence (-24 to -1) and the coding and 3' noncoding sequences are common to all the mRNAs. By dot spot hybridization and S1 mapping the distribution of these mRNAs in the various tissues was determined. The mRNA I appears exclusively in a skeletal muscle and some in heart and hepatoma AH60C, whereas the mRNAs II and III appear more or less in all the tissues examined, implying that their appearances are under tissue-specific control. Furthermore, partial nucleotide sequence analysis of the fetal liver aldolase A mRNA supports that aldolase A mRNA that reappeared in hepatoma is really a resurgence of the gene product expressed in the fetus.     

The complete amino acid sequence of the human aldolase C isozyme derived from genomic clones

The complete protein sequence of the human aldolase C isozyme has been determined from recombinant genomic clones. A genomic fragment of 6673 base pairs was isolated and the DNA sequence determined. Aldolase protein sequences, being highly conserved, allowed the derivation of the sequence of this isozyme by comparison of open reading frames in the genomic DNA to the protein sequence of other human aldolase enzymes. The protein sequence of the third aldolase isozyme found in vertebrates, aldolase C, completes the primary structural determination for this family of isozymes. Overall, the aldolase C isozyme shared 81% amino acid homology with aldolase A and 70% homology with aldolase B. The comparisons with other aldolase isozymes revealed several aldolase C-specific residues which could be involved in its function in the brain. The data indicated that the gene structure of aldolase C is the same as other aldolase genes in birds and mammals, having nine exons separated by eight introns, all in precisely the same positions, only the intron sizes being different. Eight of these exons contain the protein coding region comprised of 363 amino acids. The entire gene is approximately 4 kilobases.     

Nucleotide sequence of rat alpha 1-acid glycoprotein messenger RNA

The complete nucleotide sequence of rat alpha 1-acid glycoprotein (alpha 1-AGP) mRNA has been determined from cloned double-stranded cDNA. The coding portion of the mRNA was bounded at the ends by a 5'-untranslated region of 35 nucleotides in length and a 3'-untranslated region of 119 nucleotides in length. The 3'-untranslated region contains the characteristic AAUAAA sequence ending 18 nucleotides from the 3'-terminal poly(A) segment. The 5'-region of the mRNA contains two in-phase AUG codons separated by 12 nucleotides. Comparison with the known NH2-terminal amino acid sequence of serum rat alpha 1-AGP suggests that the primary translation product of the mRNA contains an additional 14 or 18 amino acids that are not present in the mature form of the protein, which contains 187 amino acids. The inferred amino acid sequence of rat alpha 1-AGP and the known amino acid sequence of human alpha 1-AGP have several regions of identity clustered in the NH2-terminal portion of the proteins. The carboxyl-terminal regions show significantly less homology. Six potential asparagine glycosylation sites are found in the rat sequence, and four of these sites are in positions similar to known glycosylation sites in the human protein. Furthermore, three of these potential glycosylation sites are in a region that exhibits extensive amino acid sequence conservation, suggesting that this region may be important for the biological function of alpha 1-AGP.     

Rat liver glutathione S-transferases. Nucleotide sequence analysis of a Yb1 cDNA clone and prediction of the complete amino acid sequence of the Yb1 subunit

We have constructed a nearly full length cDNA clone, pGTA/C44, complementary to the rat liver glutathione S-transferase Yb1 mRNA. The nucleotide sequence of pGTA/C44 has been determined, and the complete amino acid sequence of the Yb1 subunit has been deduced. The cDNA clone contains an open reading frame of 654 nucleotides encoding a polypeptide comprising 218 amino acids with Mr = 25,919. The NH2-terminal sequence deduced from DNA sequence analysis of pGTA/C44 is in agreement with the first 19 amino acids determined for purified glutathione S-transferase A, a Yb1 homodimer, by Frey et al. (Frey, A. B., Friedberg, T., Oesch, F., and Kreibich, G. (1983) J. Biol. Chem. 258, 11321-11325). The DNA sequence of pGTA/C44 shares significant sequence homology with a cDNA clone, pGT55, which is complementary to a mouse liver glutathione S-transferase (Pearson, W. R., Windle, J. J., Morrow, J. F., Benson, A. M., and Talalay, P. (1983) J. Biol. Chem. 258, 2052-2062). We have also determined 37 nucleotides of the 5'-untranslated region and 348 nucleotides of the 3'-untranslated region of the Yb1 mRNA. The Yb1 mRNA and subunit do not share any sequence homology with the rat liver glutathione S-transferase Ya or Yc mRNAs or their corresponding subunits. These data provide the first direct evidence that the Yb1 subunit is derived from a gene or gene family which is distinct from the Ya-Yc gene family.     

Molecular cloning, cDNA structure, and regulation of the regulatory subunit of type II cAMP-dependent protein kinase from rat ovarian granulosa cells

One isoform of the regulatory subunit of type II cAMP-dependent protein kinase (R-II51; Mr = 51,000) and its electrophoretic variants (R-II51.5 and R-II52; Mr = 51,500 and 52,000, respectively) are selectively induced by estradiol and follicle-stimulating hormone (cAMP) in rat ovarian granulosa cells. To ascertain the amino acid sequence of R-II51 and to gain insight into the molecular events regulating the intracellular content of ovarian follicular R-II51, we constructed a lambda gt11 cDNA expression library from poly(A)+ RNA of hormone-primed rat granulosa cells. A 1.5-kilobase (kb) cDNA insert, isolated from a plaque-purified R-II antibody positive bacteriophage clone, selectively bound R-II51 mRNA as demonstrated by analysis of the hybrid-selected translation product. Restriction maps and sequence analyses of the 1.5-kb cDNA insert and of the 1.8- and 2.2-kb cDNA inserts from two additional clones showed overlapping sequences which span a region of 3065 nucleotides in size. The 1.5- and 1.8-kb cDNA inserts each contained poly(A) addition signals (1508 and 1761 nucleotides, respectively), terminal poly(A) sequences, and the entire coding region for R-II51 (1204 nucleotides) except for a small number of nucleotides at the 5' end. The 2.2-kb cDNA insert contained 394 nucleotides of the coding region a long 3' untranslated region and two more poly(A) addition signals (3041 and 3059 nucleotides). An amino acid microsequence surrounding the autophosphorylation site of pure rat ovarian R-II51 agreed with the amino acid sequence deduced from the nucleotide sequence of the cDNA. Northern blot analyses demonstrated two major mRNA species (1.8 and 3.2 kb in size) in hormone-primed rat ovaries which were approximately 10- and 50-fold greater than the R-II mRNA content in rat brain and rat heart, respectively. Southern blot analysis of rat liver DNA indicated that a single gene codes for R-II51 mRNA. Structural differences among rat ovarian R-II51, rat heart R-II54, and the known amino acid sequences of bovine R-II and R-I subunits also indicate that the rat ovarian R-II51 subunit is the product of a distinct gene.     

Sequence analysis and comparison of cDNAs of the zein multigene family .

The nucleotide sequence of two zein cDNAs in hybrid plasmids A20 and B49 have been determined. The insert in A20 is 921 bp long including a 5' non-coding region of 60 nucleotides, preceded by what is believed to be an artifactual sequence of 41 nucleotides, and a 3' non-coding region of 87 nucleotides. The B49 insert is 467 bp long and includes approximately one-half the protein coding sequence as well as a 3' non-coding region of 97 nucleotides. These sequences have been compared with the previously published sequence of another zein clone, A30 . A20 and A30 , both encoding 19 000 mol. wt. zeins , have approximately 85% homology at the nucleotide level. The B49 sequence, corresponding to a 22 000 mol. wt. zein, has approximately 65% homology to either A20 or A30 . All three zeins share common features including nearly identical amino acid compositions. In addition, the tandem repeats of 20 amino acids first seen in A30 are also present in A20 and B49 .     

Glycinin A3B4 mRNA. Cloning and sequencing of double-stranded cDNA complementary to a soybean storage protein

The cDNA clones encoding the precursor form of glycinin A3B4 subunit have been identified from a library of soybean cotyledonary cDNA clones in the plasmid pBR322 by a combination of differential colony hybridizations, and then by immunoprecipitation of hybrid-selected translation product with A3-mono-specific antiserum. A recombinant plasmid, designated pGA3B41425, from one of six clones covering codons for the NH2-terminal region of the subunit was sequenced, and the amino acid sequence was inferred from the nucleotide sequence, which showed that the mRNA codes for a precursor protein of 516 amino acids. Analysis of this cDNA also showed that it contained 1786 nucleotides of mRNA sequence with a 5'-terminal nontranslated region of 46 nucleotides, a signal peptide region corresponding to 24 amino acids, an A3 acidic subunit region corresponding to 320 amino acids followed by a B4 basic subunit region corresponding to 172 amino acids, and a 3'-terminal nontranslated region of 192 nucleotides, which contained two characteristic AAUAAA sequences that ended 110 nucleotides and 26 nucleotides from a 3'-terminal poly(A) segment, respectively. Our results confirm that glycinin is synthesized as precursor polypeptides which undergo post-translational processing to form the nonrandom polypeptide pairs via disulfide bonds. The inferred amino acid sequence of the mature basic subunit, B4, was compared to that of the basic subunit of pea legumin, Leg Beta, which contained 185 amino acids. Using an alignment that permitted a maximum homology of amino acids, it was found that overall 42% of the amino acid positions are identical in both proteins. These results led us to conclude that both storage proteins have a common ancestor.     

Glycinin A5A4B3 mRNA: cDNA cloning and nucleotide sequencing of a splitting storage protein subunit of soybean

The complete nucleotide sequence of a cloned cDNA, designated pGA5A4B3822, corresponding to glycinin A5A4B3 mRNA was determined. Analysis of the cDNA insert revealed that it contained 1899 nucleotides of mRNA sequence with a 5'-terminal non-translated region of 31 nucleotides, a signal peptide region corresponding to 23 amino acids, an acidic subunit region (A5) corresponding to 97 amino acids, an acidic subunit region (A4) corresponding to 257 amino acids followed by a basic subunit region (B3) corresponding to 185 amino acids, and a 3'-terminal non-translated region of 182 nucleotides. These results show that the glycinin A4 subunit, which is not found to be linked to a basic subunit via a disulfide bond, is synthesized as a full-sized precursor, i.e. the A5A4B3 subunit complex, from a single mRNA, followed by post-translational processing to generate an intermediary subunit complex (A5-B3), covalently linked by a disulfide bond, and the mature A4 subunit, which may associate with the above subunit complex by non-covalent interactions. From the results obtained by the Chou-Fasman rules we speculated that the two post-translational cleavage sites of this subunit precursor might be processed by the same proteolytic enzyme.