Molecular structure of the human argininosuccinate synthetase gene: occurrence of alternative mRNA splicing

Citrullinemia type I is associated with a novel splicing variant, c.773 + 4A > C, in ASS1: a case report and literature review

BACKGROUND

Citrullinemia type I (CTLN1) is a rare autosomal recessive disorder of the urea cycle caused by a deficiency in the argininosuccinate synthetase (ASS1) enzyme due to mutations in the ASS1 gene. Only a few Chinese patients with CTLN1 have been reported, and ASS1 gene mutations have been identified sporadically in China.

CASE PRESENTATION

A Chinese family with one member affected with mild CTLN1 was enrolled. Targeted exome sequencing was performed on the proband, and Sanger sequencing was used to validate the detected mutation. We also reviewed the genetic and clinical characteristics of CTLN1 in Chinese patients that have been published to date. Newborn screening showed remarkably increased concentrations of citrulline with elevated ratios of citrulline/arginine and citrulline/phenylalanine, and the patient presented with a speech delay at age three. The urinary organic acid profiles were normal. A novel homozygous splicing variant c.773 + 4A > C in the ASS1 gene was identified in the proband, and it was predicted to affect splicing by in silico analysis. To date, only nine Chinese patients with CTLN1 have been reported, with a total of 15 ASS1 mutations identified and no high frequency or hot spot mutations found; the mutation spectrum of Chinese patients with CTLN1 was heterogeneous.

CONCLUSIONS

We described a mild Chinese CTLN1 case with a novel homozygous splicing variant c.773 + 4A > C and reviewed previous genotypes and phenotypes in Chinese patients with CTLN1. Thus, our findings contribute to understanding the molecular genetic background and clinical phenotype of CTLN1 in this population.

Increased expression of argininosuccinate synthetase protein predicts poor prognosis in human gastric cancer

Aberrant expression of argininosuccinate synthetase (ASS1, also known as ASS) has been found in cancer cells and is involved in the carcinogenesis of gastric cancer. The aim of the present study was to investigate the level of ASS expression in human gastric cancer and to determine the possible correlations between ASS expression and clinicopathological findings. Immunohistochemistry was performed on paraffin-embedded tissues to determine whether ASS was expressed in 11 of 11 specimens from patients with gastric cancer. The protein was localized primarily to the cytoplasm of cancer cells and normal epithelium. In the Oncomine cancer microarray database, expression of the ASS gene was significantly increased in gastric cancer tissues. To investigate the clinicopathological and prognostic roles of ASS expression, we performed western blot analysis of 35 matched specimens of gastric adenocarcinomas and normal tissue obtained from patients treated at the National Cheng Kung University Hospital. The ratio of relative ASS expression (expressed as the ASS/β-actin ratio) in tumor tissues to that in normal tissues was correlated with large tumor size (P=0.007) and with the tumor, node, metastasis (TNM) stage of the American Joint Committee on Cancer staging system (P=0.031). Patients whose cancer had increased the relative expression of ASS were positive for perineural invasion and had poor recurrence-free survival. In summary, ASS expression in gastric cancer was associated with a poor prognosis. Further study of mechanisms to silence the ASS gene or decrease the enzymatic activity of ASS protein has the potential to provide new treatments for patients with gastric cancer.

Transcriptional regulation of genes for ornithine cycle enzymes

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Mitochondrial DNA does not appear to influence the congenital onset type of myotonic dystrophy

Neither the maternal inheritance pattern nor the early onset of congenital myotonic dystrophy are fully explained. One possible mechanism is that mitochondrial DNA (mtDNA) mutations might interact with the DM gene product, producing an earlier onset than would otherwise occur. We have used Southern hybridisation to show that high levels of major rearrangements of mtDNA are not present in muscle of five and in blood of 35 patients with congenital myotonic dystrophy. We used sequence analysis to show that no one particular mtDNA morph appears to cosegregate with congenital onset. A minor degree of depletion of mtDNA compared with nuclear DNA was present in the muscle of five patients with congenital DM, but we propose that this is not the primary cause of the muscle pathology but secondary to it. We have not found evidence that mtDNA is involved in congenital myotonic dystrophy.

Molecular analysis of human argininosuccinate lyase: mutant characterization and alternative splicing of the coding region

Argininosuccinic acid lyase (ASAL) deficiency is a clinically heterogeneous autosomal recessive urea cycle disorder. We previously established by complementation analysis that 28 ASAL-deficient patients have heterogeneous mutations in a single gene. To prove that the ASAL structural gene is the affected locus, we sequenced polymerase chain reaction-amplified ASAL cDNA of a representative mutant from the single complementation group. Fibroblast strain 944 (approximately 1% of residual ASAL activity), from a late-onset patient who was the product of a consanguineous mating, had only a single base-pair change in the coding region, a C-283----T transition at a CpG dinucleotide in exon 3. This substitution converts Arg-95 to Cys (R95C), occurs in a stretch of 13 residues that is identical in yeast and human ASAL, and was present in both of the patient's alleles but not in 14 other mutant or 10 normal alleles. Expression in COS cells demonstrated that the R95C mutation produces normal amounts of ASAL mRNA but little protein and less than 1% ASAL activity. We observed that amplified cDNA from mutant 944 and normal cells (liver, keratinocytes, lymphoblasts, and fibroblasts) contained, in addition to the expected 5' 513-base-pair band, a prominent 318-base-pair ASAL band formed by the splicing of exon 2 from the transcript. The short transcript maintains the ASAL reading frame but removes Lys-51, a residue that may be essential for catalysis, since it binds the argininosuccinate substrate. We conclude (i) that the identification of the R95C mutation in strain 944 demonstrates that virtually all ASAL deficiency results from defects in the ASAL structural gene and (ii) that minor alternative splicing of the coding region occurs at the ASAL locus.

Molecular definition of bovine argininosuccinate synthetase deficiency

Citrullinemia is an inborn error of metabolism due to deficiency of the urea cycle enzyme, argininosuccinate synthetase [L-citrulline:L-aspartate ligase (AMP-forming), EC 6.3.4.5]. The disease was first described in humans but was recently reported in dairy cattle in Australia. Here we report the nucleotide sequence of the normal bovine cDNA for argininosuccinate synthetase and the mutation present in animals with citrullinemia. Analysis of DNA from affected animals by Southern blotting did not readily identify the mutation in the bovine gene. RNA (Northern) blotting revealed a major reduction in the steady-state amount of mRNA in the liver of affected animals to less than 5% of controls. The bovine cDNA was cloned and sequenced and revealed 96% identity with the deduced human sequence at the amino acid level. Starting with mutant bovine liver, the mRNA was reverse-transcribed; the cDNA product was amplified with the polymerase chain reaction, cloned, and sequenced. The sequence revealed a C----T transition converting arginine-86 (CGA) to a nonsense codon (TGA). A second C----T transition represented a polymorphism in proline-175 (CCC----CCT). The mutation and the polymorphism were confirmed by amplification of genomic DNA and demonstration with restriction endonuclease enzymes of both the loss of an Ava II site in DNA from mutant animals at codon 86 and the presence or absence of a Dde I site at codon 175. The loss of the Ava II site can be used for rapid, economical, nonradioactive detection of heterozygotes for bovine citrullinemia.

Human liver-type arginase gene: structure of the gene and analysis of the promoter region

The gene for human liver-type arginase (EC 3.5.3.1), a urea cycle enzyme, was cloned and the structure was determined. This gene is 11.5 kilobases long and is split into 8 exons. The cap site was determined by nuclease S1 mapping and primer extension. A "TATA box"-like sequence is located 28 bases upstream from the cap site, and a sequence similar to the binding sites of the transcription factor CTF/NF1, a "CAAT box"-binding protein, is located 72 bases upstream. In the 5' end region, sequences resembling the glucocorticoid responsive elements, the cAMP responsive elements, and the enhancer core sequences are present. The immediately 5' flanking region of the human gene up to position -105 is 84% identical with the corresponding segment of the rat gene. In this region of the human gene, one DNase I-protected area and several hypersensitive cleavage sites were detected by footprint analysis, using nuclear extracts from the rat liver. The protected area contains the sequence similar to the binding sites of CTF/NF1 and also overlaps with the sequence resembling the glucocorticoid responsive elements.

Conservation of structure in the human gene encoding argininosuccinate synthetase and the argG genes of the archaebacteria Methanosarcina barkeri MS and Methanococcus vannielii

The DNA sequences of the argG genes of Methanosarcina barkeri MS and Methanococcus vannielii were determined. The polypeptide products of these methanogen genes have amino acid sequences which are 50% identical to each other and 38% identical to the amino acid sequence encoded by the exons of the human argininosuccinate synthetase gene. Introns in the human chromosomal gene separate regions which encode amino acids conserved in both the archaebacterial and human gene products. An open reading frame immediately upstream of argG in Methanosarcina barkeri MS codes for an amino acid sequence which is 45 and 31% identical to the sequences of the large subunits of carbamyl phosphate synthetase in Escherichia coli and Saccharomyces cerevisiae, respectively. If this gene encodes carbamyl phosphate synthetase in Methanosarcina barkeri, this is the first example, in an archaebacterium, of physical linkage of genes that encode enzymes which catalyze reactions in the same amino acid biosynthetic pathway.

Do exons code for structural or functional units in proteins?

In considering the origin and evolution of proteins, the possibility that proteins evolved from exons coding for specific structure-function modules is attractive for its economy and simplicity but is not systematically supported by the available data. However, the number of correspondences between exons and units of protein structure-function that have so far been identified appears to be greater than expected by chance alone. The available data also show (i) that exons are fairly limited in size but are large enough to specify structure-function modules in proteins; (ii) that the position of introns for homologous domains in the same gene is reasonably stable, but there is also evidence for mechanisms that alter the position or existence of introns; and (iii) that it is possible that the observed relationship of exons to protein structure represents a degenerate state of an ancestral correspondence between exons and structure-function modules in proteins.

Evolution of nuclear gene families in primates. Copy-number variation in the argininosuccinate synthetase (ASS) pseudogene family and the anonymous DNA sequence, D1S1

Changes in the copy number of nuclear genes provide the raw material for the creation of new gene functions. To better understand the mechanisms for such events, and their physiologic and evolutionary consequences, it is valuable to study a well characterized and closely related group of species such as primates. Fortuitously, most of the powerful molecular techniques and DNA probes developed for research in humans are equally applicable to non-human primates. We review what is known of copy number variation in primates and describe two informative DNA probes: pAS-1, a cDNA probe to the human urea cycle enzyme argininosuccinate synthetase (ASS), and an anonymous DNA probe, D1S1. In addition to the ASS structural locus on human chromosome 9, pAS-1 detects at least 14 dispersed, processed pseudogenes in humans. The number of pseudogene copies appears to be approximately the same in humans, chimpanzees, gorillas, orangutans and baboons; less in marmosets; and least in some rodents. Chimpanzees and gorillas appear to have all of the human pseudogenes though an Xp copy may be missing from gorillas. The Y pseudogene is apparently absent from orangutans and baboons, and, finally, a comparison of humans and chimpanzees revealed that the number of nucleotide substitutions in the Y chromosome pseudogenes is approximately 1 per 100. D1S1 maps to human chromosome 3 but also detects a high homology copy on chromosome 1. Chimpanzees, gorillas and orangutans all appear to have only the chromosome 3 homolog suggesting that this is the ancestral sequence and that the duplication occurred after separation of humans and the great apes. Both the ASS pseudogene family and the D1S1 system provide valuable information on the evolution of nuclear gene families in primates.

Optional exon in the 5'-untranslated region of 3-hydroxy-3-methylglutaryl coenzyme A synthase gene: conserved sequence and splicing pattern in humans and hamsters

3-Hydroxy-3-methylglutaryl coenzyme A synthase (hydroxymethylglutaryl-CoA synthase, EC 4.1.3.5) is a negatively regulated enzyme in the synthetic pathway for cholesterol, isopentenyl tRNA, and other isoprenoids. The 5'-untranslated region of the mRNA for Chinese hamster hydroxymethylglutaryl-CoA synthase contains an optional exon of 59 nucleotides located 10 nucleotides upstream of the translation start site. About 50% of the mRNAs contain this exon, and the other 50% lack it owing to differential intron splicing. We show that the two transcripts are found in similar ratios in multiple tissues of the Syrian hamster, including the brain. The relative amounts of the two transcripts in brain and liver are constant from day 0 to day 75 of life. A similar alternative splicing pattern for hydroxymethylglutaryl-CoA synthase was observed in three human tissues: cultured fibroblasts, fetal adrenal gland, and fetal liver. A cDNA for human synthase had 90% homology to the hamster sequence in the region corresponding to the optional exon. This sequence contains a 20 out of 26 nucleotide match with the sequence immediately upstream of the initiator AUG codon in the mRNA for hamster hydroxymethylglutaryl-CoA reductase, the enzyme that follows the synthase in the isoprenoid biosynthetic pathway. These findings raise the possibility that the optional exon plays an important, conserved functional role in humans and hamsters.

Expression of a human cytomegalovirus late gene is posttranscriptionally regulated by a 3'-end-processing event occurring exclusively late after infection

A phenomenon of posttranscriptional regulation has been previously identified in cytomegalovirus-infected human fibroblast cells (Wathen and Stinski, J. Virol. 41:462, 1982). A region typifying this phenomenon has been located within the large unique component of the viral genome (map units 0.408 to 0.423). Even though this transcriptional unit was highly transcribed at early times after infection, mRNAs from this region were only detectable on the polyribosomes after viral DNA replication. Thus, this region is believed to code for a late gene. Single-strand-specific nuclease mapping experiments of viral transcripts established that the transcriptional initiation sites and the 5' ends of a downstream exon were identical at early and late times. However, the late transcripts differed from the early transcripts by the processing of the 3' end of the viral RNAs. This involved either the removal of a distinct region of the transcript by the selection of an upstream cleavage and polyadenylation site or the differential splicing of the RNA molecule. The upstream cleavage and polyadenylation site was identified by nuclease mapping analyses and DNA sequencing. The 3'-end processing of these transcripts is necessary for the detection of these viral RNAs within the cytoplasm of the infected cell. We propose that human cytomegalovirus either codes for a factor(s) that is involved in the 3'-end-processing event at late times after infection or stimulates the synthesis of a host cell factor(s) involved in this complex regulatory event. This level of regulation may have an influence on the types of cells that permit productive cytomegalovirus replication.

Transcriptional regulation of the muscle creatine kinase gene and regulated expression in transfected mouse myoblasts

The muscle-specific form of creatine kinase (MCK) is induced in differentiating myoblast cultures, and a dramatic increase in mRNA levels precedes and parallels the increase in MCK protein. To study this induction, the complete MCK gene was cloned and characterized. The transcription unit was shown to span 11 kilobases and to contain seven introns. The splice junctions were identified and shown to conform to the appropriate consensus sequences. Close homology with branchpoint consensuses was found upstream of the 3' splice sites in six of seven cases. Transcriptional regulation of the gene in differentiating myoblast cultures was demonstrated by nuclear run-on experiments; increases in transcription accounted for a major part of the increased mRNA levels. Regulated expression of a transfected MCK gene containing the entire transcription unit with 3.3 kilobases of 5'-flanking sequence was also demonstrated during differentiation of the MM14 mouse myoblast cell line. The MCK 5'-flanking region was sufficient to confer transcriptional regulation to a heterologous structural gene, since chloramphenicol acetyl transferase activity was induced during differentiation of cultures transfected with an MCK-chloramphenicol acetyl transferase fusion construct. Examination of the DNA sequence immediately upstream of the transcription start site revealed a 17-nucleotide element which occurred three times. Comparisons with other muscle-specific genes which are also transcriptionally regulated during myogenesis revealed upstream homologies in the alpha-actin and myosin heavy chain genes, but not in the myosin light-chain genes, with the regions containing these repeats. We suggest that coordinate control of a subset of muscle genes may occur via recognition of these common sequences.

Human argininosuccinate synthetase minigenes are subject to arginine-mediated repression but not to trans induction

The human argininosuccinate synthetase locus is subject to metabolite-mediated repression by arginine in some cultured cell lines. To gain insight into the mechanism underlying this regulation, chloramphenicol acetyltransferase (CAT) minigenes under the transcriptional control of the human argininosuccinate synthetase promoter were constructed and tested for regulation. When the minigenes were introduced into RPMI 2650 cells, a human cell line that shows sixfold regulation of the argininosuccinate synthetase gene, CAT expression was repressed three- to fivefold when arginine was present in the culture medium. A minigene containing only 149 base pairs of 5'-flanking sequence was expressed at similar levels and regulated to the same degree as one having approximately 3 kilobases of 5'-flanking sequence. Therefore, the cis-acting sequences required for the arginine-mediated repression are likely to be located within the region of the transcription initiation site. The arginine-mediated repression of the CAT minigenes was not observed in canavanine-resistant variants of RPMI 2650 cells, and therefore they showed the appropriate cell-type specificity. Cultured cells having 200-fold-increased levels of argininosuccinate synthetase can be selected by growth in medium containing the arginine analog canavanine. It was previously demonstrated that the increased expression of argininosuccinate synthetase in canavanine-resistant human lymphoblasts was due to a trans-acting mechanism. To gain further support for a trans-acting mechanism, we tested our CAT minigenes for the trans induction in canavanine-resistant variants of RPMI 2650 cells. Transfection of the CAT minigenes into RPMI 2650 cells and canavanine-resistant variants of this cell line yielded no difference in transient CAT expression. Furthermore, cloned canavanine-resistant variant cells having integrated copies of the CAT minigenes expressed CAT at similar levels as compared to the parental cell lines. Since these cell lines do exhibit arginine-mediated repression of CAT but not trans induction, these data indicate that the argine-mediated repression is a regulatory event that occurs independently of the trans induction.

Arginine-mediated regulation of an argininosuccinate synthetase minigene in normal and canavanine-resistant human cells

Regulation of argininosuccinate synthetase (AS) was studied by using minigenes containing 3 kilobases of DNA upstream from the TATAA box and 9 kilobases downstream (including the first four exons of the AS gene) ligated to either the cDNA for AS or to the chloramphenicol acetyltransferase (CAT) gene. Unlike the endogenous AS gene, expression of the CAT minigene was not elevated in Canr1 cells, which overproduce AS compared with parental RPMI-2650 cells. Expression of the CAT minigene in both stable and transient analyses was four- to five-fold higher in RPMI-2650 cells grown in citrulline medium than in cells grown in arginine medium. Although endogenous AS activity is not subject to metabolite regulation in Canr1 cells and expression of the CAT minigene in Canr1 cells was not increased when cells were grown in citrulline medium, expression of the CAT minigene was 10- to 22-fold greater when intracellular arginine pools were depleted by transient starvation for arginine and citrulline.

Expression of a human cytomegalovirus late gene is posttranscriptionally regulated by a 3'-end-processing event occurring exclusively late after infection

A phenomenon of posttranscriptional regulation has been previously identified in cytomegalovirus-infected human fibroblast cells (Wathen and Stinski, J. Virol. 41:462, 1982). A region typifying this phenomenon has been located within the large unique component of the viral genome (map units 0.408 to 0.423). Even though this transcriptional unit was highly transcribed at early times after infection, mRNAs from this region were only detectable on the polyribosomes after viral DNA replication. Thus, this region is believed to code for a late gene. Single-strand-specific nuclease mapping experiments of viral transcripts established that the transcriptional initiation sites and the 5' ends of a downstream exon were identical at early and late times. However, the late transcripts differed from the early transcripts by the processing of the 3' end of the viral RNAs. This involved either the removal of a distinct region of the transcript by the selection of an upstream cleavage and polyadenylation site or the differential splicing of the RNA molecule. The upstream cleavage and polyadenylation site was identified by nuclease mapping analyses and DNA sequencing. The 3'-end processing of these transcripts is necessary for the detection of these viral RNAs within the cytoplasm of the infected cell. We propose that human cytomegalovirus either codes for a factor(s) that is involved in the 3'-end-processing event at late times after infection or stimulates the synthesis of a host cell factor(s) involved in this complex regulatory event. This level of regulation may have an influence on the types of cells that permit productive cytomegalovirus replication.

Cloning and sequence analysis of cDNA for human argininosuccinate lyase

Using antibodies specific for argininosuccinate lyase (EC 4.3.2.1), we isolated two cDNA clones by screening a human liver cDNA library constructed in the lambda gt11 expression vector. The identity of these isolates was confirmed by in vitro translation of plasmid-selected mRNA. One of these isolates was used to rescreen the cDNA library and a 1565-base-pair (bp) clone was identified. The entire nucleotide sequence of this clone was determined. An open reading frame was identified which encoded a protein of 463 amino acids with a predicted molecular weight of 51,663. The clone included 115 bp of 5' untranslated sequence and 46 bp of 3' untranslated sequence. A canonical poly(A) addition site was present in the 3' end, 16 bp from the beginning of the poly(A) tract. Comparison of the deduced amino acid sequence of the human enzyme with that of the yeast enzyme revealed a 56% homology, when conservative amino acid changes were taken into consideration. The yeast protein is also 463 amino acids long, with a molecular weight of 51,944. By use of a genomic DNA panel from human-Chinese hamster somatic cell hybrids, the human gene was mapped to chromosome 7. Another hybridizing region, corresponding to a portion of the 5' end of the cDNA, was found on chromosome 22.

Transcriptional regulation of the muscle creatine kinase gene and regulated expression in transfected mouse myoblasts

The muscle-specific form of creatine kinase (MCK) is induced in differentiating myoblast cultures, and a dramatic increase in mRNA levels precedes and parallels the increase in MCK protein. To study this induction, the complete MCK gene was cloned and characterized. The transcription unit was shown to span 11 kilobases and to contain seven introns. The splice junctions were identified and shown to conform to the appropriate consensus sequences. Close homology with branchpoint consensuses was found upstream of the 3' splice sites in six of seven cases. Transcriptional regulation of the gene in differentiating myoblast cultures was demonstrated by nuclear run-on experiments; increases in transcription accounted for a major part of the increased mRNA levels. Regulated expression of a transfected MCK gene containing the entire transcription unit with 3.3 kilobases of 5'-flanking sequence was also demonstrated during differentiation of the MM14 mouse myoblast cell line. The MCK 5'-flanking region was sufficient to confer transcriptional regulation to a heterologous structural gene, since chloramphenicol acetyl transferase activity was induced during differentiation of cultures transfected with an MCK-chloramphenicol acetyl transferase fusion construct. Examination of the DNA sequence immediately upstream of the transcription start site revealed a 17-nucleotide element which occurred three times. Comparisons with other muscle-specific genes which are also transcriptionally regulated during myogenesis revealed upstream homologies in the alpha-actin and myosin heavy chain genes, but not in the myosin light-chain genes, with the regions containing these repeats. We suggest that coordinate control of a subset of muscle genes may occur via recognition of these common sequences.

Arginine-mediated regulation of an argininosuccinate synthetase minigene in normal and canavanine-resistant human cells

Regulation of argininosuccinate synthetase (AS) was studied by using minigenes containing 3 kilobases of DNA upstream from the TATAA box and 9 kilobases downstream (including the first four exons of the AS gene) ligated to either the cDNA for AS or to the chloramphenicol acetyltransferase (CAT) gene. Unlike the endogenous AS gene, expression of the CAT minigene was not elevated in Canr1 cells, which overproduce AS compared with parental RPMI-2650 cells. Expression of the CAT minigene in both stable and transient analyses was four- to five-fold higher in RPMI-2650 cells grown in citrulline medium than in cells grown in arginine medium. Although endogenous AS activity is not subject to metabolite regulation in Canr1 cells and expression of the CAT minigene in Canr1 cells was not increased when cells were grown in citrulline medium, expression of the CAT minigene was 10- to 22-fold greater when intracellular arginine pools were depleted by transient starvation for arginine and citrulline.

Human argininosuccinate synthetase minigenes are subject to arginine-mediated repression but not to trans induction

The human argininosuccinate synthetase locus is subject to metabolite-mediated repression by arginine in some cultured cell lines. To gain insight into the mechanism underlying this regulation, chloramphenicol acetyltransferase (CAT) minigenes under the transcriptional control of the human argininosuccinate synthetase promoter were constructed and tested for regulation. When the minigenes were introduced into RPMI 2650 cells, a human cell line that shows sixfold regulation of the argininosuccinate synthetase gene, CAT expression was repressed three- to fivefold when arginine was present in the culture medium. A minigene containing only 149 base pairs of 5'-flanking sequence was expressed at similar levels and regulated to the same degree as one having approximately 3 kilobases of 5'-flanking sequence. Therefore, the cis-acting sequences required for the arginine-mediated repression are likely to be located within the region of the transcription initiation site. The arginine-mediated repression of the CAT minigenes was not observed in canavanine-resistant variants of RPMI 2650 cells, and therefore they showed the appropriate cell-type specificity. Cultured cells having 200-fold-increased levels of argininosuccinate synthetase can be selected by growth in medium containing the arginine analog canavanine. It was previously demonstrated that the increased expression of argininosuccinate synthetase in canavanine-resistant human lymphoblasts was due to a trans-acting mechanism. To gain further support for a trans-acting mechanism, we tested our CAT minigenes for the trans induction in canavanine-resistant variants of RPMI 2650 cells. Transfection of the CAT minigenes into RPMI 2650 cells and canavanine-resistant variants of this cell line yielded no difference in transient CAT expression. Furthermore, cloned canavanine-resistant variant cells having integrated copies of the CAT minigenes expressed CAT at similar levels as compared to the parental cell lines. Since these cell lines do exhibit arginine-mediated repression of CAT but not trans induction, these data indicate that the argine-mediated repression is a regulatory event that occurs independently of the trans induction.

Two ornithine decarboxylase mRNA species in mouse kidney arise from size heterogeneity at their 3' termini

Ornithine decarboxylase (OrnDCase; L-ornithine carboxy-lyase, EC 4.1.1.17) mRNA present in mouse kidney comprises two species with molecular sizes of approximately 2.2 and approximately 2.7 kilobases (kb). cDNA clones prepared from murine kidney OrnDCase mRNA were used to determine the reason for the size heterogeneity of these mRNAs. Two of the cDNA clones (pODC16 and pODC74) that differed at the 3' termini were isolated and sequenced. DNA sequencing indicated that each cDNA had a poly(A) tail; however, pODC74 was 429 nucleotides longer than pODC16 at the 3' end and contained two AATAAA signals for poly(A) addition. That the longer cDNA corresponded to the larger mRNA was confirmed by hybridization of a unique Pst I/Pst I fragment from the 3' terminus of pODC74 only to the 2.7-kb OrnDCase mRNA. The two cDNAs did not represent full-length copies of OrnDCase mRNAs and were 1199 (pODC16) and 1204 base pairs (bp) (pODC74) long. There were five mismatches in their 759-bp-long overlapping nucleotide sequence, suggesting that the 2.2- and 2.7-kb OrnDCase mRNAs may be products of two separate, yet very similar, OrnDCase genes. Androgen regulation of the accumulation of these two OrnDCase mRNAs appeared to occur coordinately, as testosterone administration brought about comparable increases in their concentrations in mouse kidney.