UNIPROT:P06889 - FACTA Search

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We studied immunochemical properties of rat testicular asparagine synthetase. Western blot analysis of testis extract with polyclonal antibody raised against purified asparagine synthetase revealed an immunoreactive band at 62 kDa. The pancreas, brain, thymus, and spleen also showed 62-kDa bands. The intensities of these bands were roughly proportional to the specific activities of the enzyme in these tissues. The antibody showed some degree of cross-reactivity to asparagine synthetases from human, beef, pig, mouse, guinea pig, chicken, and frog, but not carp. But the enzyme from human HL-60 cells and lower vertebrates reacted with the antibody less strongly than enzyme from rats. The N-terminal amino acid sequence of the enzyme, determined by the Edman degradation method, in 10 recovered residues was identical to that of human asparagine synthetase deduced from corresponding cDNA (I.L. Andrulis et al., 1987, Mol. Cell. Biol. 7, 2435-2443). Immunohistochemical staining of the testis showed the presence of asparagine synthetase mainly in Sertoli cells in the seminiferous tubules.
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PMID:Immunochemical characterization of rat testicular asparagine synthetase. 134 69

We have studied the regulation of expression of the asparagine synthetase (AS) gene in ts11 cells, a mutant of BHK hamster cells which encodes a temperature-sensitive AS and therefore does not produce endogenous asparagine at 39.5 degrees C. Incubation of ts11 cells at the nonpermissive temperature drastically increases the level of AS mRNA, and the stimulation of AS mRNA expression is effectively suppressed by the addition of asparagine to the medium. We show here that regulation of AS gene expression involves cis-acting elements which are contained in the mRNA as well as in the 5' genomic region. When a plasmid containing the human AS cDNA under the control of the human AS promoter region was stably transfected into ts11 cells, the expression of human AS RNAs was regulated as that of the endogenous hamster transcripts, indicating that this construct contained all cis elements necessary for regulation. Expression of the AS cDNA in ts11 cells under the control of a constitutive foreign promoter was also regulated by the concentration of asparagine, and this regulation required translation. When we introduced by mutagenesis a number of stop codons in the AS cDNA, the mutant mRNAs with short open reading frames were expressed at low levels that were not increased by asparagine deprivation. Inhibition of protein and RNA synthesis also prevented down-regulation of AS mRNA levels by high concentrations of asparagine. In a parallel series of experiments, we showed that an AS DNA fragment including the promoter and first exon can also regulate RNA expression in response to asparagine concentration. Furthermore, similar increases in the levels of AS RNAs are produced not only by asparagine deprivation in ts11 cells but also by deprivation of human and wild-type BHK cells of leucine, isoleucine, or glutamine. Thus, regulation of AS gene expression is a response to amino acid starvation through mechanisms which appear to involve both changes in RNA stability and change in the rates of transcription initiation or elongation.
Mol Cell Biol 1991 Dec
PMID:Regulation of asparagine synthetase gene expression by amino acid starvation. 168 98

Human cell lines resistant to L-asparaginase or albizziin were isolated by multistep selection of HT1080 fibrosarcoma and MIA PaCa-2 pancreatic carcinoma cells. Mutants were cross-resistant to both drugs, but more resistant to the drug used for selection. The drug-resistant cell lines expressed elevated levels of asparagine synthetase activity and protein, up to 17-fold over that of the parental cells. Enzyme overproduction was due to gene amplification in the albizziin-resistant cells, whereas increased expression without amplification was observed in L-asparaginase-resistant cells.
Somat Cell Mol Genet 1990 Jan
PMID:Molecular and genetic characterization of human cell lines resistant to L-asparaginase and albizziin. 196 81

A yeast nuclear gene, designated MSK1, has been selected from a yeast genomic library by transformation of a respiratory deficient mutant impaired in acylation of mitochondrial lysine tRNA. This gene confers a respiratory competent phenotype and restores the mutant's ability to acylate the mitochondrial lysine tRNA. The amino acid sequence of the protein encoded by MSK1 is homologous to yeast cytoplasmic lysyl-tRNA synthetase and to the product of the herC gene, which has recently been suggested to code for the Escherichia coli enzyme. These observations indicate that MSK1 codes for the lysyl-tRNA synthetase of yeast mitochondria. Several regions of high primary sequence conservation have been identified in the bacterial and yeast lysyl-tRNA synthetases. These domains are also present in the aspartyl- and asparaginyl-tRNA synthetases, further confirming the notion that all three present-day enzymes originated from a common ancestral gene. The most conserved domain, located near the carboxyl terminal ends of this group of synthetases is characterized by a cluster of glycines and is also highly homologous to the carboxyl-terminal region of the E. coli ammonia-dependent asparagine synthetase. A catalytic function of the carboxyl terminal domain is indicated by in vitro mutagenesis of the yeast mitochondrial lysyl-tRNA synthetase. Replacement of any one of three glycine residues by alanine and in one case by aspartic acid completely suppresses the activity of the enzymes, as evidenced by the inability of the mutant genes to complement an msk1 mutant, even when present in high copy. Other mutations result in partial loss of activity. Only one glycine replacement affects the stability of the protein in vivo. The observed presence of a homologous domain in asparagine synthetase, which, like the aminoacyl-tRNA synthetases, catalyzes the formation of an aminoacyladenylate, suggests that the glycine-rich sequence is part of a catalytic site involved in binding of ATP and of the aminoacyladenylate intermediate.
J Mol Biol 1991 Apr 05
PMID:Structure and evolution of a group of related aminoacyl-tRNA synthetases. 201 46

The human ts11 gene was isolated on the basis of its ability to complement the mutation of the BHK cell cycle ts11 mutant, which is blocked in G1 at the nonpermissive temperature. This gene has now been identified as the structural gene for asparagine synthetase (AS) on the bases of sequence homology and the ability of exogenous asparagine to bypass the ts11 block. The ts11 (AS) mRNA has a size of about 2 kilobases and is induced in mid-G1 phase in human, mouse, and hamster cell lines. We have studied the organization and regulation of expression of the ts11 gene. The human ts11 gene consists of 13 exons (the first two noncoding) interspersed in a region of about 21 kilobases of DNA. Transient expression assays using the bacterial chloramphenicol acetyltransferase reporter gene identified two separate promoters: one (ts11 P1) contained in a 280-base-pair region upstream of the first exon and the other (ts11 P2) contained in the first intron. ts11 P1 produced about sixfold more chloramphenicol acetyltransferase activity than did ts11 P2 and had features of the promoters of housekeeping genes: high G + C content, multiple transcription start sites, absence of a TATA box, and presence of putative Sp1 binding sites. ts11 P2 contained a TATA sequence and other elements characteristic of a promoter, but so far we have no evidence of its physiological utilization. The ts11 gene was overexpressed in ts11 cells exposed to the nonpermissive temperature. Addition of asparagine to the culture medium led to a drastic decrease in mRNA levels and prevented G1 induction in serum-stimulated cells, which indicated that expression of the AS gene is regulated by a mechanism of end product inhibition.
Mol Cell Biol 1989 Jun
PMID:Organization and expression of the cell cycle gene, ts11, that encodes asparagine synthetase. 256 68

In Chinese hamster ovary cells, the gene for asparagine synthetase, which spans 20 kilobase pairs, was found to contain a cluster of potential sites for CpG methylation in a 1-kilobase-pair region surrounding the first exon. Fourteen of the sites that could be assayed for methylation by MspI-HpaII digestions were found in this region, with an additional nine MspI sites spread throughout the remainder of the gene. The methylation status of the gene was analyzed in a series of cell lines that differed in the amount of asparagine synthetase activity. The level of expression showed a direct correlation with the extent of methylation of a subset of the MspI sites found in the 5' region of the gene. The rest of the gene was completely methylated in most cell lines. Wild-type cells, which expressed a basal level of asparagine synthetase activity, were partially demethylated in the 5' region. In contrast, asparagine-requiring N3 cells, which lacked detectable mRNA for asparagine synthetase, were methylated throughout the entire gene. Spontaneous revertants of strain N3, selected for growth in asparagine-free medium, exhibited extensive hypomethylation of the asparagine synthetase gene. The methylation pattern of the gene in cell lines that overproduced the enzyme was also examined. Albizziin-resistant cell lines, which had amplified copies of the gene, were extensively demethylated in the 5' region. Overexpression of asparagine synthetase in beta-aspartyl hydroxamate-resistant lines without amplified copies of the gene was also correlated with DNA hypomethylation.
Mol Cell Biol 1989 Jul
PMID:DNA methylation patterns associated with asparagine synthetase expression in asparagine-overproducing and -auxotrophic cells. 257 Oct 77

A new dominant amplifiable selective system for use in bacterium-animal cell shuttle vectors was developed by the insertion of a 2-kilobase genomic fragment containing the cloned Escherichia coli gene for asparagine synthetase (AS) into the pBR322-simian virus 40 recombinant vector pSV2 so as to place the translational initiator codon for the bacterial AS about 1,000 base pairs downstream from the simian virus 40 early promoter. This new construct, pSV2-AS, retains bacterial sequences for transcriptional and translational initiation and so can express AS in bacteria. The construct can also complement AS- mutants of mammalian cells, giving AS+ transfectants capable of growth in medium lacking asparagine, with relatively high efficiency (about 300 colonies per microgram of DNA per 10(6) cells exposed). The vector can be amplified up to 100-fold in such AS+ transfectants by selection in asparagine-free medium containing increasing concentrations of the AS inhibitor beta-aspartyl hydroxamate. AS+ transfectants were found to be much more resistant to a second AS inhibitor, Albizziin, than were normal AS+ animal cell lines. This difference, which may indicate a strong resistance of the bacterial AS enzyme to Albizziin, was exploited to develop an effective selection for bacterial AS transfectants of a number of wild-type AS+ cell lines of rat, Chinese hamster, mouse, and human origin. LR-73 cells, a Chinese hamster AS+ cell line, were transfected with pSV2-AS with an efficiency of about 1,000 colonies per 0.5 microgram of DNA per 10(6) cells. The integrated construct in these cells was amplified by incubation of the transfectants in increasing concentrations of beta-aspartyl hydroxamate. Advantages and disadvantages of this new dominant, selectable, and amplifiable marker over markers commonly used in shuttle vectors are discussed.
Mol Cell Biol 1987 May
PMID:Use of the Escherichia coli gene for asparagine synthetase as a selective marker in a shuttle vector capable of dominant transfection and amplification in animal cells. 288 40

Asparagine synthetase cDNAs containing the complete coding region were isolated from a human fibroblast cDNA library. DNA sequence analysis of the clones showed that the message contained one open reading frame encoding a protein of 64,400 Mr, 184 nucleotides of 5' untranslated region, and 120 nucleotides of 3' noncoding sequence. Plasmids containing the asparagine synthetase cDNAs were used in DNA-mediated transfer of genes into asparagine-requiring Jensen rat sarcoma cells. The cDNAs containing the entire protein-coding sequence expressed asparagine synthetase activity and were capable of conferring asparagine prototrophy on the Jensen rat sarcoma cells. However, cDNAs which lacked sequence for as few as 20 amino acids at the amino terminal could not rescue the cells from auxotrophy. The transferant cell lines contained multiple copies of the human asparagine synthetase cDNAs and produced human asparagine synthetase mRNA and asparagine synthetase protein. Several transferants with numerous copies of the cDNAs exhibited only basal levels of enzyme activity. Treatment of these transferant cell lines with 5-azacytidine greatly increased the expression of asparagine synthetase mRNA, protein, and activity.
Mol Cell Biol 1987 Jul
PMID:Isolation of human cDNAs for asparagine synthetase and expression in Jensen rat sarcoma cells. 288 7

Using specific mutants as a means of identification, the bacterial protein for asparagine synthetase (Asn Syn) was shown to be antigenically and electrophoretically similar to its mammalian counterpart. This observation prompted us to attempt direct transfer of the cloned bacterial gene for the enzyme to mammalian cells. DNA from the replicative form of clone M13 OriC, containing the bacterial gene for Asn Syn, was shown to be capable of causing transformation of Jensen rat Asn Syn- cells to cells capable of growth in Asn-free medium; no prior modification of the bacterial gene was required. This relatively inefficient transformation (20 colonies/micrograms DNA/10(6) cells) was sensitive or insensitive to restriction enzyme digestion of the M13 OriC DNA in complete agreement with the known restriction map of the bacterial gene. Clones of transformed rat cells contained the bacterial DNA, which was amplified if increased levels of the enzyme were demanded and lost if selection was removed. The clones also contained polysomal bacterial RNA and a new protein with properties similar but not identical to those of the bacterial enzyme. The biological significance of this unusual degree of compatibility between the prokaryotic and eukaryotic Asn Syn gene systems is discussed.
J Mol Appl Genet 1983
PMID:Direct transfer of the bacterial asparagine synthetase gene to mammalian cells. 613 53

The amino acid analog albizziin was used to isolate Chinese hamster ovary cell lines which overproduce asparagine synthetase. Mutants selected in a single step after ethyl methane sulfonate mutagenesis were approximately 10-fold more resistant to the drug than the parental lines and expressed 8- to 17-fold elevations in enzyme activity. The karyotypes of these lines show alterations such as breaks and translocations affecting the long arm of chromosome 1. Cell lines isolated in several steps by growth in progressively increasing concentrations of albizziin were more resistant to the drug and exhibited up to 300-fold enhancement of asparagine synthetase activity. The multistep albizziin-resistant cell lines usually had expanded chromosomal regions which stained somewhat homogeneously, often on the long arm of chromosome 1. These results suggest that resistance to albizziin in the multistep lines may be due to gene amplification.
Mol Cell Biol 1983 Mar
PMID:Chromosomal alterations associated with overproduction of asparagine synthetase in albizziin-resistant Chinese hamster ovary cells. 613 14

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