Cloning of cDNA for argininosuccinate synthetase mRNA and study of enzyme overproduction in a human cell line

Previous studies of the human cell line RPMI-2650 (wild type) and its canavanine-resistant variants have demonstrated differences in argininosuccinate synthetase activity as follows: canavanine-resistant much greater than wild type grown in citrulline greater than wild type grown in arginine (Su, T.-S., Beaudet, A. L., and O'Brien, W. E. (1981) Biochemistry 20, 2956-2960). A recombinant plasmid containing a 1.55-kilobase insert complementary to the mRNA for human argininosuccinate synthetase was isolated by the combined use of differential colony hybridization and immunoprecipitation of the products of plasmid-selected mRNA translation. Both blot and dot hybridization analysis of polyadenylated RNA indicated a major mRNA species of 1.67 kilobase in all cells, and the levels of mRNA correlated well with the levels of enzyme activity: canavanine-resistant, 180; wild type grown in citrulline, 7; and wild type grown in arginine, 1. One major mRNA species of 1.67 kilobase and one minor species of 2.68 kilobase were observed in wild type and canavanine-resistant cell lines. Reassociation kinetics of pAS1 with genomic DNA from human liver, canavanine-resistant cells, and wild type cells were not significantly different. Blot hybridization of genomic DNA revealed no detectable differences between wild type cells, canavanine-resistant cells, and human leukocytes. The data demonstrated that there were multiple copies, perhaps 10 or more, of argininosuccinate synthetase-like sequences in human DNA and that the canavanine-resistant phenotype was not due to gene amplification.     

Molecular characterization of the murine argininosuccinate synthetase locus.

The cDNA and gene encoding murine argininosuccinate synthetase were cloned and characterized. The cDNA sequence predicts a peptide of 412 amino acids (aa) including the initiator methionine. There is 98% identity with the aa sequence of the human enzyme. The 3'-untranslated region of the cDNA includes two regions of sequence which are conserved between mouse, rat, human and cow. The murine gene contains 16 exons with the start codon occurring in exon 3. Although alternative splicing occurs in primates to include or exclude exon 2, exon 2 sequences were included in the murine mRNA in all tissues and developmental stages examined. The inclusion of exon 2 in murine mRNA, compared to the usual exclusion in human mRNA, may be explained by differences in the donor splice sequences for exon 2.     

Relative argininosuccinate synthetase mRNA levels and gene copy number in canavanine-resistant lymphoblasts

Mutants resistant to the arginine analogue, canavanine, have been isolated from two normal lymphoblast lines, MGL8B2 and MGL33. These mutants constitutively express up to 200-fold higher amounts of structurally normal argininosuccinate synthetase, the urea cycle enzyme that converts citrulline to argininosuccinate. Relative levels of argininosuccinate synthetase mRNA were compared among normal and canavanine-resistant lines using in vitro translation of poly(adenylic acid) RNA and blot hybridization of total cytoplasmic RNA to an argininosuccinate synthetase cDNA. Both of these approaches indicated that the canavanine-resistant lines contain increased steady-state levels of synthetase-specifc mRNA relative to their sensitive parents and that these were roughly correlated with levels of enzyme activity. Blot hybridization of Eco RI-digested genomic DNA preparations revealed no detectable differences in argininosuccinate synthetase structural gene copy number between normal and canavanine-resistant lymphoblasts, demonstrating that the canavanine-resistant phenotype is not caused by gene amplification.     

Molecular structures of human argininosuccinate synthetase pseudogenes. Evolutionary and mechanistic implications

In the human genome there is one expressed gene for argininosuccinate synthetase and 14 pseudogenes. A cDNA coding for human argininosuccinate synthetase was used to screen a human genomic library. Twenty-five unique genomic clones were isolated and extensively characterized. At least seven clones represented processed argininosuccinate synthetase pseudogenes that lost the introns in the expressed gene. Restriction mapping demonstrated that these processed pseudogenes were located in distinct regions of the human genome. Complete nucleotide sequences of two processed pseudogenes, psi AS-1 and psi AS-3, and a partial sequence of psi AS-7 were determined. Both psi AS-1 and psi AS-3 had an adenine-rich region at their 3' end and were flanked by distinct imperfect direct repeats. A comparison of these pseudogene sequences to that of the cDNA demonstrated that psi AS-1 and psi AS-3 were 93% homologous to the cDNA, whereas psi AS-7 was 89% homologous to the cDNA. Therefore, it is estimated that psi AS-1 and psi AS-3 were created 10-11 million years ago, whereas psi AS-7 arose approximately 21 million years ago. We have estimated the evolutionary rate for the expressed argininosuccinate synthetase gene based on the sequences of psi AS-1 and psi AS-3. These data indicate that the expressed argininosuccinate synthetase gene is evolving at a rate similar to that of the beta-globin gene and much faster than the alpha-tubulin gene. Furthermore, a comparison of the sequences of psi AS-1 and psi AS-3 suggests the possibility that these pseudogenes arose from a common intermediate.     

Molecular cloning and nucleotide sequence of cDNA encoding the rat kidney S-adenosylmethionine synthetase.

We previously reported the isolation of a cDNA encoding the liver-specific isozyme of rat S-adenosylmethionine synthetase from a lambda gt11 rat liver cDNA library. Using this cDNA as a probe, we have isolated and sequenced cDNA clones for the rat kidney S-adenosylmethionine synthetase (extrahepatic isoenzyme) from a lambda gt11 rat kidney cDNA library. The complete coding sequence of this enzyme mRNA was obtained from two overlapping cDNA clones. The amino acid sequence deduced from the cDNAs indicates that this enzyme contains 395 amino acids and has a molecular mass of 43,715 Da. The predicted amino acid sequence of this protein shares 85% similarity with that of rat liver S-adenosylmethionine synthetase. This result suggests that kidney and liver isoenzymes may have originated from a common ancestral gene. In addition, comparison of known S-adenosylmethionine synthetase sequences among different species also shows that these proteins have a high degree of similarity. The distribution of kidney- and liver-type S-adenosylmethionine synthetase mRNAs in kidney, liver, brain, and testis were examined by RNA blot hybridization analysis with probes specific for the respective mRNAs. A 3.4-kilobase (kb) mRNA species hybridizable with a probe for kidney S-adenosylmethionine synthetase was found in all tissues examined except for liver, while a 3.4-kb mRNA species hybridizable with a probe for liver S-adenosylmethionine synthetase was only present in the liver. The 3.4-kb kidney-type isozyme mRNA showed the same molecular size as the liver-type isozyme mRNA. Thus, kidney- and liver-type S-adenosylmethionine synthetase isozyme mRNAs were expressed in various tissues with different tissue specificities.     

Molecular cloning of a novel human PAPS synthetase which is differentially expressed in metastatic and non-metastatic colon carcinoma cells.

Subtractive hybridisation was used to select for genes which are differentially expressed between a highly metastatic human colon carcinoma cell line, KM12SM, and the isogenetic non-metastatic cell line, KM12C. This led to the isolation of cDNA clones for a novel human adenosine 5'-phosphosulphate kinase/ATP sulphurylase (PAPS synthetase). Northern hybridisation revealed a single 4.2 kb mRNA species which showed an approximately 20-fold higher level of expression in the non-metastatic cell line than in the metastatic cell line. The overlapping cDNA clones together covered 3,774 bp including the entire coding region of 1,842 bp encoding a protein of 614 amino acids (calculated molecular mass of 69,496 Da). The protein contains consensus sequences for APS kinase and ATP sulphurylase, in its amino- and carboxy-terminal regions, respectively, as well as other sequences that are highly conserved amongst ATP sulphurylases and APS kinases. Interestingly, consensus sequences for GTPase activity were also identified, indicating that enzyme activity may be regulated by an intrinsic GTPase mechanism. Overall the new protein is 78% homologous with a previously described human PAPS synthetase (PAPSS1) indicating that we have identified the second member of a gene family which we have provisionally named PAPSS2. The gene locus for PAPSS2 was identified on chromosome 10 at 10q23.1-q23.2. This locus has synteny with the mouse brachymorphic gene recently identified as a PAPS synthetase (SK2). PAPSS2 appears to be the human homologue of this gene and thus PAPSS2 is likely to be important in human skeletogenesis.     

Differential splicing of thymosin beta 4 mRNA

A cDNA clone was isolated from a mouse pre-B cell line, the sequence of which has a very high homology with rat and human thymosin beta 4 genes. However, the mouse clone has an insertion of 98 bp relative to the published rat and human sequences upstream of the coding region. By isolation of a second set of clones from a different cDNA library and by cloning a PCR amplified region of mouse genomic DNA it was confirmed that the insertion is not a cloning artifact. Furthermore, it was shown by RNase protection assays with RNA from the pre-B cell line that two sizes of thymosin beta 4 mRNA exist, a long form containing the 98 nucleotide insertion, and a short form that corresponds to the known rat and human mRNA. The short form is about 50 times more abundant than the long form. Analysis of genomic DNA by sequencing and Southern blotting revealed that both forms are encoded by a single gene in the mouse. The two forms of mRNA arise by differential RNA splicing; the long mRNA contains three separate exons, whereas the short mRNA is missing exon 2. The long mRNA is present in two different pre-B cell lines, spleen and thymus, but could not be detected in brain, liver, and kidney. It is possible that the longer mRNA, which encodes a hydrophobic NH2-extension of six additional amino acids, plays a role in lymphocyte function or development. In contrast to the mouse which has a single thymosin beta 4 gene, rat and human have multiple homologs. Most or all of these also contain sequences that cross-hybridize with the newly discovered exon 2. A polymorphic thymosin beta 4 gene has been found in human DNA.     

Genomic structure of the human mitochondrial aldehyde dehydrogenase gene

We have isolated and characterized four overlapping clones from two cosmid human genomic libraries, which span about 90 kilobase pairs (kbp) and contain the entire human mitochondrial aldehyde dehydrogenase (ALDH2) gene. Restriction maps of the genomic clones were elucidated utilizing cDNA probes and specific oligonucleotide probes. The organization of exons and introns was established by DNA sequencing of each exon and splicing junctions. The ALDH2 gene is about 44 kbp in length and contains at least 13 exons which encode 517 amino acid residues. Except for the signal NH2-terminal peptide, which is absent in the mature enzyme, the amino acid sequence deduced from the exons coincided with the reported primary structure of human liver ALDH2 (J. Hempel, R. Kaiser, and H. J?rnvall, 1985, Eur. J. Biochem. 153: 13-28). Several introns contain Alu repetitive sequences. A TATA-like sequence (TTATAAAA) and a CAAT-like sequence (GTCATCAT) are located 473 and 515 bp, respectively, upstream from the translation initiation codon. Primer extension and S1 nuclease mapping were performed to characterize the 5'-region of the gene.     

Integrity of the exon 6 sequence is essential for tissue-specific alternative splicing of human leukocyte common antigen pre-mRNA.

By alternative splicing, exons 4, 5, and 6 of the human leukocyte common antigen (LCA) gene are included in B-cell mRNA but excluded from thymocyte mRNA. A mini-LCA gene that contains only LCA exons 2, 6, and 8 faithfully reproduces this tissue-specific alternative splicing in mouse B and thymocyte cell lines. Elimination of almost all of the intron sequences associated with exon 6 had no effect on the alternative splicing, while linker-scanning analysis showed that a significant length of the exon 6 sequence is essential for alternative splicing.     

Transcription of human neuronal nitric oxide synthase mRNAs derived from different first exons is partly controlled by exon 1-specific promoter sequences

The human neuronal nitric oxide synthase (NOS1) gene is subject to extensive splicing. A total of 12 NOS1 mRNA species have been identified. They differ in their 5' ends and are derived from 12 different first exons (termed exons 1a to 1l). Various cell lines whose NOS1 first exon expression patterns were representative of human brain, skin, and skeletal muscle were identified. These included A673 neuroepithelioma cells, SK-N-MC neuroblastoma cells, HaCaT keratinocyte-like cells, and C2C12 myocyte-like cells. In these cell lines, correlations were found between the exon 1 variants preferentially expressed and the promoter activities of their cognate 5' flanking sequences. These data demonstrate that expression of the different exon 1-related splice variants of NOS1 mRNA is controlled directly (at least in part) by the associated 5' flanking sequences.     

Molecular cloning of cDNA for rat and human carbamyl phosphate synthetase I

Recombinant plasmids with inserts complementary to the mRNA for carbamyl phosphate synthetase I were identified from a rat liver cDNA library by hybrid-selected mRNA translation. Four clones, the largest being 3100 base pairs, were identified for the rat liver enzyme. Using the rat liver cDNA as a probe, two homologous recombinant plasmids of approximately 1200 base pairs in length were isolated from a human liver cDNA library. Northern blot analysis of rat liver mRNA and baboon liver mRNA revealed the presence of a 5000-base mRNA homologous to both rat and human cDNA probes. No homologous mRNA was observed in mRNA from rat heart or rat kidney as is consistent with the known tissue distribution of this enzyme. The induction of carbamyl phosphate synthetase and argininosuccinate synthetase mRNA during the fetal and postnatal development of the rat was studied by dot blot analysis of isolated mRNA. The mRNA for both enzymes appeared between 17 and 19 days of fetal life and reached approximately 40% of adult levels during this period. This initial increase was followed by a rapid decline just prior to birth. The mRNA levels slowly increased during postnatal life, not reaching adult levels until after the 20th day of neonatal life. Using the human cDNA clones, the human carbamyl phosphate synthetase gene was mapped to chromosome 2 utilizing a panel of Chinese hamster X human somatic cell hybrids. Analysis of one hybrid with a human-Chinese hamster translocation provided a provisional assignment to the short arm of chromosome 2.     

A complex intronic splicing enhancer from the c-src pre-mRNA activates inclusion of a heterologous exon.

The mouse c-src gene contains a short neuron-specific exon, N1. To characterize the sequences that regulate N1 splicing, we used a heterologous gene, derived from the human beta-globin gene, containing a short internal exon that is usually skipped by the splicing machinery. Various fragments from the src gene were inserted into the globin substrate to measure their effects on the splicing of the test exon. These clones were transiently expressed in neuronal and nonneuronal cell lines, and the level of exon inclusion was measured by primer extension. Several sequences from the N1 exon region induced the splicing of the heterologous exon. The most powerful effect was seen with a sequence from the intron downstream of the N1 exon. This sequence acted as a strong splicing enhancer, activating splicing of the test exon when placed in the intron downstream. The enhancer was strongest in neuronal LA-N-5 cells but also activated splicing in nonneuronal HEK293 cells. Deletion and linker scanning mutagenesis indicate that the enhancer is made up of multiple smaller elements that must act in combination. One of these elements was identified as the sequence UGCAUG. Three copies of this element can strongly activate splicing of the test exon in LA-N-5 neuroblastoma cells. These component elements of the src splicing enhancer are also apparently involved in the splicing of other short cassette exons.