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 a cDNA clone for human aldolase B

Two specific clones for human aldolase B were isolated from a human liver cDNA library using a rat aldolase B cDNA probe. The clones were identified by positive hybridization-selection and one of them was sequenced. The 127 C-terminal residues of the human protein were deduced from this nucleotide sequence analysis. They showed 92% homology with the corresponding previously published amino-acid sequence of rat liver aldolase B.     

Nucleotide sequence of a cDNA clone for human aldolase: a messenger RNA in the liver

Nearly complete cDNA clones for human aldolase A mRNA were isolated from human liver cDNA library and the nucleotide sequence determined. Using the cDNA clone as a probe the length of human aldolase A mRNAs, isolated from the skeletal muscle, liver and placenta tissues, was measured by RNA blotting and estimated to be 1,600 nucleotides for skeletal muscle mRNA and 1,700 nucleotides for both the liver and placenta mRNAs, indicating that different species of mRNA coding for human aldolase A were expressed in the different tissues.     

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.     

Molecular cloning, primary structure and disruption of the structural gene of aldolase from Saccharomyces cerevisiae

A yeast cDNA genetic library in a bacteriophage expression vector was screened using an antiserum reacting with fructose 1,6-bisphosphate aldolase from Saccharomyces cerevisiae. Radio-labelled probes of selected immunopositive clones were used for screening of a yeast genomic library. From the genomic clones a yeast/Escherichia coli shuttle plasmid was constructed containing on a 1990-base-pair fragment the entire structural gene FBA1 coding for yeast aldolase. The primary structure of the FBA1 gene was determined. An open reading frame comprises 1077 base pairs coding for a protein of 359 amino acids with a predicted molecular mass of 39,608 Da. As observed for other strongly expressed yeast genes, codon usage is extremely biased. The 810 base pairs at the 5' end and the 90 base pairs at the 3' end of the coding region of the cloned FBA1 gene are sufficient for normal expression and show characteristic elements present in the noncoding sequences of other yeast genes. Aldolase is the major protein in yeast cells transformed with a high-copy-number plasmid containing the FBA1 gene. The aldolase gene was disrupted by insertion of the yeast URA3 gene into the coding region of one FBA1 allele in a homozygous diploid ura3 strain. The haploid offsprings with the defective aldolase allele fba1::URA3 lack aldolase enzymatic activity and fail to grow in media containing as a carbon source metabolites of only one side of the aldolase reaction.     

Observation of a possible pause mutant in the total synthesis of T4 lysozyme

A DNA of 495 bp coding for T4-lysozyme was chemically synthesized and cloned in Escherichia coli. On DNA sequence analysis, clones pTLY.10 and pTLY.9 were identified to contain identical and complete T4-lysozyme coding sequences except that pTLY.9 had an additional 23 bp inverted repeat DNA at the 3'-end of the coding sequence. On expression and purification under similar conditions, T4-lysozymes from these two clones showed different degrees of retention time on HPLC as well as in the rate of enzymatic reaction. We speculate that this difference could be due to the generation of a pause mutant of T4-lysozyme in pTLY.9 under the influence of 3'-inverted repeat DNA that alters the rate of protein synthesis.     

Genomic structure of the rice aldolase isozyme C-1 gene and its regulation through a Ca2+-mediated protein kinase-phosphatase pathway

Complementary and genomic DNA clones coding for aldolase C-1, the fourth-type isozyme of aldolase in rice Oryza sativa L., have been characterized. The organization of the gene is quite similar to those encoding rice aldolase C-a and a maize cytoplasmic-type aldolase, in that introns are located in the same position. Amino acid sequences are highly conserved among cytoplasmic aldolases in plants. Expression of the gene in rice callus is activated by a protein phosphatase inhibitor okadaic acid, and is inhibited in the presence of thapsigargin, a reagent which increases calcium influx into the cytoplasm. The inhibition is rescued by the simultaneous addition of protein kinase inhibitor H-7. Thus, it is suggested that expression of the aldolase C-1 gene is regulated through a signal transduction pathway involving a Ca²⁺-mediated protein kinase-protein phosphatase system.     

Nucleic acid (cDNA) and amino acid sequences of isocitrate lyase from castor bean

A cDNA library was constructed to mRNA enriched for isocitrate-lyase mRNA from castor-bean (Ricinus communis var. zanzibarensis) endosperms. Nine clones for isocitrate lyase (EC 4.1.3.1) were identified. The insert of 2.2 kb from clone ICL4 was sequenced and proved to contain the entire coding region, 1731 bp, for isocitrate lyase. The amino acid sequence of isocitrate lyase was deduced from the nucleic acid sequence. By analogy with muscle aldolase a lysine residue that possibly takes part in the binding of the substrate was identified. The 3 untranslated region contained three putative polyadenylation addition signals and two direct repeats.     

The plastid aldolase gene fromChlamydomonas reinhardtii: Intron/exon organization,evolution, and promoter structure

Genomic clones encoding the plastidic fructose- 1,6-bisphosphate aldolase ofChlamydomonas reinhardtii were isolated and sequenced. The gene contains three introns which are located within the coding sequence for the mature protein. No introns are located within or near the sequence encoding the transit-peptide, in contrast to the genes for plastidic aldolases of higher plants. Neither the number nor the positions of the three introns of theC. reinhardtii aldolase gene are conserved in the plastidic or cytosolic aldolase genes of higher plants and animals. The 5′ border sequences of introns in the aldolase gene ofC. reinhardtii exhibit the conserved plant consensus sequence. The 3′ acceptor splice sites for introns 1 and 3 show much less similarity to the eukaryotic consensus sequences than do those of intron 2. The plastidic aldolase gene has two tandemly repeated CAAT box motifs in the promoter region. Genomic Southern blots indicate that the gene is encoded by a single locus in theC. reinhardtii genome.     

Ribosomal DNA genes of Bombyx mori: a minor fraction of the repeating units contain insertions

We have analyzed multiple recombinant DNA clones containing ribosomal RNA repeat units of the silkmoth, Bombyx mori. In combination with genomic DNA blots, analysis of these clones indicated that the rDNA repeat of B. mori is 10.8 kilobase pair in length and tandemly repeated in the genome, as reported by Manning et al. (18). However, contrary to that report, approximately 12% of the rDNA cistrons are interrupted by insertions of non-ribosomal DNA. Two classes of DNA insertions were identified. In one class the insertions are positioned in a region of the 28S coding sequence similar to that of the predominant rDNA insertions found in a variety of Dipteran and Tetrahymena species. In the second class, probable insertions are found close to the 3' terminus of the 28S coding sequence. Restriction enzyme analysis indicates that the two classes of insertions are not related.     

Developmentally regulated plant genes: the nucleotide sequence of a wheat gliadin genomic clone

Gliadins, the major wheat seed storage proteins, are encoded by a multigene family. Northern blot analysis shows that gliadin genes are transcribed in endosperm tissue into two classes of poly(A)+ mRNA, 1400 bases (class I) and 1600 bases (class II) in length. Using poly(A)+ RNA from developing wheat endosperm we constructed a cDNA library from which a number of clones coding for alpha/beta and gamma gliadins were identified by hybrid-selected mRNA translation and DNA sequencing. These cDNA clones were used as probes for the isolation of genomic gliadin clones from a wheat genomic library. One such genomic clone was characterized in detail and its DNA sequence determined. It contains a gene for a 33-kd alpha/beta gliadin protein (a 20 amino acid signal peptide and a 266 amino acid mature protein) which is very rich in glutamine (33.8%) and proline (15.4%). The gene sequence does not contain introns. A typical eukaryotic promoter sequence is present at -104 (relative to the translation initiation codon) and there are two normal polyadenylation signals 77 and 134 bases downstream from the translation termination codon. The coding sequence contains some internal sequence repetition, and is highly homologous to several alpha/beta gliadin cDNA clones. Homology to a gamma-gliadin cDNA clone is low, and there is no homology with known glutenin or zein cDNA sequences.     

Localization of the active gene of aldolase on chromosome 16, and two aldolase A pseudogenes on chromosomes 3 and 10

Summary Southern blot analysis of human genomic DNA hybridized with a coding region aldolase A cDNA probe (600 bases) revealed four restriction fragments with EcoRI restriction enzyme: 7.8 kb, 13 kb, 17 kb and >30 kb. By human-hamster hybrid analysis (Southern technique) the principal fragments, 7.8 kb, 13 kb, >30 kb, were localized to chromosomes 10, 16 and 3 respectively. The 17-kb fragment was very weak in intensity; it co-segregated with the >30-kb fragment and is probably localized on chromosome 3 with the >30-kb fragment. Analysis of a second aldolase A labelled probe protected against S1 nuclease digestion by RNAs from different hybrid cells, indicated the presence of aldolase A mRNAs in hybrid cells containing only chromosome 16. Under the stringency conditions used, the EcoRI sequences detected by the coding region aldolase A cDNA probe did not correspond to aldolase B or C. The 7.8-kb and >30-kb EcoRI sequences, localized respectively on chromosomes 10 and 3, correspond to aldolase A pseudogenes, the 13-kb EcoRI sequence localized on chromosome 16 corresponds to the aldolase active gene. The fact that the aldolase A gene and pseudogenes are located on three different chromosomes supports the hypothesis that the pseudogenes originated from aldolase A mRNAs, copied into DNA and integrated in unrelated chromosomal loci.     

Characterization of the gene for human plasminogen, a key proenzyme in the fibrinolytic system

The organization and structure of the gene coding for plasminogen has been determined by a combination of in vitro amplification of leukocyte DNA from normal individuals and isolation of unique clones from three different human genomic libraries. These clones were characterized by restriction mapping, Southern blotting, and DNA sequencing. The gene for human plasminogen spanned about 52.5 kilobases of DNA and consisted of 19 exons separated by 18 introns. DNA sequence analysis revealed that the five kringle structures in plasminogen were coded by two exons. The nucleotides in the introns at the intron-exon boundaries were GT-AG analogous to those found in other eukaryotic genes. Three polyadenylation sites for plasminogen mRNA were also identified. When the amino acid sequences deduced from the genomic DNA and cDNAs of plasminogen were compared with that of the plasma protein determined by amino acid sequence analysis, an apparent amino acid polymorphism was observed in several positions of the polypeptide chain. Nucleotide sequence analysis of the amplified genomic DNAs and genomic clones also revealed that the plasminogen gene was very closely related to several other proteins, including apolipoprotein(a). This protein may have evolved via duplication and exon shuffling of the plasminogen gene. The presence of another plasminogen-related gene(s) in the human genomic library was also observed.     

Isolation of two genomic sequences encoding the Mr = 14,000 subunit of rat prostatein

Complementary DNAs to rat ventral prostate poly(A) RNA were cloned into pBR322 by the "dG-dC tailing" procedure. Clones containing cDNAs to the mRNAs coding for each of the three subunits of a major secretory protein (prostatein) were identified by hybrid-arrested translation. A 457-nucleotide base pair cDNA (E45) and a portion of a 365-base pair cDNA (E85) were analyzed to determine the composite complete DNA coding sequence for the Mr = 14,000 (C3) subunit of prostatein. A sequence of 12-nucleotide bases (TTTGCTGCTATG) in the signal peptide of C3 was noted to be homologous to signal peptide nucleotide sequences reported in cDNAs coding for the other two prostatein subunits, Mr = 6,000 (C1) and 10,000 (C2). Complementary DNA coding for the C3 subunit was used as a hybridization probe to screen an EcoRI rat genomic DNA library. Two unique 12-kilobase genomic clones, each containing mRNA coding sequences within 2.5-3-kilobase fragments, were identified by restriction enzyme mapping and Southern blot analysis. Restriction enzyme sites within the coding regions of both genes were analogous to the cDNA. Differences in restriction enzyme sites in regions of intervening sequences and flanking DNA established the uniqueness of the two genes. It is suggested that both genes may be transcribed in vivo.     

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.