Evidence for tetrameric structure of mammalian hypoxanthine phosphoribosyltransferase

A fast electrophoretic variant of hypoxanthine phosphoribosyltransferase (HPRT) has been detected in Mus musculus bactrianus, a mouse subspecies from Middle Asia (USSR). The electrophoretic HPRT pattern yielded by hybrids between the somatic cell of LMTK^– (deficient in thymidine kinase) and the splenocytes of a male of M. m. bactrianus was five-banded. The pattern obtained from the germ cells of the ovaries from 14.5-day-old embryos from laboratory CBA mice × M. m. bactrianus crosses was also composed of five bands. The hybrids between the somatic cells of human fibroblasts × LMTK^– cells gave a three-banded electrophoretic HPRT pattern because the asymmetrical heteropolymeric isozymes are probably unstable. Taken together, all the evidence is in favor of a tetrameric structure of mammalian HPRT.     

Asparagine synthetases of Klebsiella aerogenes: properties and regulation of synthesis

We isolated pleiotropic mutants of Klebsiella aerogenes with the transposon Tn5 which were unable to utilize a variety of poor sources of nitrogen. The mutation responsible was shown to be in the asnB gene, one of two genes coding for an asparagine synthetase. Mutations in both asnA and asnB were necessary to produce an asparagine requirement. Assays which could distinguish the two asparagine synthetase activities were developed in strains missing a high-affinity asparaginase. The asnA and asnB genes coded for ammonia-dependent and glutamine-dependent asparagine synthetases, respectively. Asparagine repressed both enzymes. When growth was nitrogen limited, the level of the ammonia-dependent enzyme was low and that of the glutamine-dependent enzyme was high. The reverse was true in a nitrogen-rich (ammonia-containing) medium. Furthermore, mutations in the glnG protein, a regulatory component of the nitrogen assimilatory system, increased the level of the ammonia-dependent enzyme. The glutamine-dependent asparagine synthetase was purified to 95%. It was a tetramer with four equal 57,000-dalton subunits and catalyzed the stoichiometric generation of asparagine, AMP, and inorganic pyrophosphate from aspartate, ATP, and glutamine. High levels of ammonium chloride (50 mM) could replace glutamine. The purified enzyme exhibited a substrate-independent glutaminase activity which was probably an artifact of purification. The tetramer could be dissociated; the monomer possessed the high ammonia-dependent activity and the glutaminase activity, but not the glutamine-dependent activity. In contrast, the purified ammonia-dependent asparagine synthetase, about 40% pure, had a molecular weight of 80,000 and is probably a dimer of identical subunits. Asparagine inhibited both enzymes. Kinetic constants and the effect of pH, substrate, and product analogs were determined. The regulation and biochemistry of the asparagine synthetases prove the hypothesis strongly suggested by the genetic and physiological evidence that a glutamine-dependent enzyme is essential for asparagine synthesis when the nitrogen source is growth rate limiting.     

Comparative study of pig-rodent somatic cell hybrids

The pig chromosome complement of six different types of pig-rodent hybrid cell lines was examined by means of fluorescence in situ hybridization with a porcine SINE probe. The cell lines were obtained by fusing pig lymphocytes with cells of the Chinese hamster cell lines wg3h, BK14-150 and E36, and of the mouse cell lines NSO, PU and LMTK^-. The hybrids were analysed with respect to: (1) the number of pig chromosomes, (2) the type of pig chromosomes, (3) the occurrence of pig-rodent chromosome trans-locations, and (4) the presence of pig chromsome fragments. The results show that the number of pig chromosomes varied within and among hybrid cell lines. The pig-hamster hybrids mainly retained nontelocentric pig chromosomes, whereas the pig-mouse hybrids also retained telocentric pig chromosomes. Pig-rodent chromosome translocations were found in all types of hybrids, but the incidence was in general low. Chromosome fragments were abundant in BK14-150 hybrids, and rare in most other hybrid cell lines. It is concluded that the SINE probe is a useful tool to make a preliminary characterization of the porcine chromosome complement of pig-rodent somatic cell hybrids. The results of this characterization can be used to select hybrids for further cytogenetic analysis. Furthermore, our data show that different rodent cell lines will have to be used as fusion partners for the production of hybrids when constructing a panel informative for all pig chromosomes.     

Cotransfer and phenotypic stabilisation of syntenic and asyntenic mink genes into mouse cells by chromosome-mediated gene transfer

Summary By means of metaphase chromosomes, the genes for mink thymidine kinase (TK) and hypoxanthine-phosphoribosyltransferase (HPRT) were transferred to mutant mouse cells, LMTK^-, A9 (HPRT^-) and teratocarcinoma cells, PCC4-aza 1 (HPRT^-). Eighteen colonies were isolated from LMTK^- (series A), 9 from A9 (series B) and none from PCC4-aza 1. The transformed clones contained mink TK or HPRT. Analysis of syntenic markers in series B demonstrated that one clone contained mink glucose-6-phosphate dehydrogenase (G6PD) and the other alpha-galactosidase; in series A, nine clones contained mink galactokinase (GALK) and six mink aldolase C (ALDC). Analysis of 12 asyntenic markers located in ten mink chromosomes showed the presence of only aconitase-1 (ACON1) (the marker of mink chromosome 12) in three clones of series A. The clones lost mink ACON1 between the fifth to tenth passages. Cytogenetic analysis established the presence of a fragment of mink chromosome 8 in eight clones of series A, but not in series B. The clones of series A lost mink TK together with mink GALK and ALDC during back-selection; in B, back-selection retained mink G6PD. No stable TK⁺ phenotype was detected in clones with a visible fragment of mink chromosome 8. Stability analysis demonstrated that about half of the clones of series B have stable HPRT⁺ phenotype whereas only three clones of series A have stable TK⁺ phenotype. It is suggested that the recipient cells, LMTK^- and A9, differ in their competence for genetic transformation and integration of foreign genes.     

Expression and extinction of glial properties in glioma X neuroblastoma cell hybrids

Rat glioma cells (clone C₆TK⁻) were hybridized with mouse neuroblastoma cells (clone NA), and 18 primary and secondary hybrid clones containing one chromosome set from each parent were isolated. The hybrids were assayed for the glial marker enzymes 2′,3′-cyclic nucleotide 3′-phosphohydrolase (CNP) and glycerol-3-phosphate dehydrogenase (GPDH). In many of the hybrid clones, the levels of CNP and GPDH were reduced to 5–20% of the activity of C₆TK⁻, as has been observed in other classes of glial X non-glial cell hybrids. In some hybrid clones, however, GPDH and CNP were expressed at high activity. Rat (glial) GPDH activity was not reduced in these clones, but mouse GPDH activity remained low, and was not “de-repressed” or “activated”. This suggests that the controls governing differentiation in neuroblastoma cells and extinction in hybrids may differ in some important details. There was a strong positive correlation between the specific activities of CNP and GPDH in the hybrid clones, suggesting that a mechanism regulates the activity of these two glial enzymes coordinately.     

Topographical separation of the catalytic sites of asparagine synthetase explored with monoclonal antibodies

Monoclonal antibodies which inhibited the enzymatic activity of bovine pancreatic asparagine synthetase were mapped to two topographically separate regions of the enzyme surface using competitive binding assays. Three antibodies which all inhibited glutamine- and NH3-dependent synthesis of asparagine bound to a common antigenic region. A fourth monoclonal antibody which interfered with glutamine binding or cleavage but not with NH3-dependent synthesis of asparagine was mapped to a separate region of the enzyme surface. These findings suggest a topographical separation between the aspartyl-AMP and glutamine-binding sites of bovine pancreatic asparagine synthetase. Three noninhibitory antibodies exhibited conformation-dependent binding and were mapped to a third region of the enzyme. Binding assays were used to demonstrate extensive cross-reaction of these antibodies with asparagine synthetases isolated from bovine liver and sheep pancreas. Substantial cross-reactions were also seen with the enzyme isolated from rat liver or pancreas, a human tumor cell line, and a mouse tumor cell line. Of the four antibodies that inhibited glutamine- and NH3-dependent synthesis of asparagine from ruminant species, only one bound to and inhibited the enzyme from rat liver or mouse cells, which suggests significant structural differences between the ruminant and rodent enzymes.     

Cereal asparagine synthetase genes

Asparagine synthetase catalyses the transfer of an amino group from glutamine to aspartate to form glutamate and asparagine. The accumulation of free (nonprotein) asparagine in crops has implications for food safety because free asparagine is the precursor for acrylamide, a carcinogenic contaminant that forms during high‐temperature cooking and processing. Here we review publicly available genome data for asparagine synthetase genes from species of the Pooideae subfamily, including bread wheat and related wheat species (Triticum and Aegilops spp.), barley (Hordeum vulgare) and rye (Secale cereale) of the Triticeae tribe. Also from the Pooideae subfamily: brachypodium (Brachypodium dIstachyon) of the Brachypodiae tribe. More diverse species are also included, comprising sorghum (Sorghum bicolor) and maize (Zea mays) of the Panicoideae subfamily and rice (Oryza sativa) of the Ehrhartoideae subfamily. The asparagine synthetase gene families of the Triticeae species each comprise five genes per genome, with the genes assigned to four groups: 1, 2, 3 (subdivided into 3.1 and 3.2) and 4. Each species has a single gene per genome in each group, except that some bread wheat varieties (genomes AABBDD) and emmer wheat (Triticum dicoccoides; genomes AABB) lack a group 2 gene in the B genome. This raises questions about the ancestry of cultivated pasta wheat and the B genome donor of bread wheat, suggesting that the hybridisation event that gave rise to hexaploid bread wheat occurred more than once. In phylogenetic analyses, genes from the other species cluster with the Triticeae genes, but brachypodium, sorghum and maize lack a group 2 gene, while rice has only two genes, one group 3 and one group 4. This means that TaASN2, the most highly expressed asparagine synthetase gene in wheat grain, has no equivalent in maize, rice, sorghum or brachypodium. An evolutionary pathway is proposed in which a series of gene duplications gave rise to the five genes found in modern Triticeae species.     

N2 fixation and NH 4 + assimilation in the thermophilic anaerobes Clostridium thermosaccharolyticum and Clostridium thermoautotrophicum

Inorganic nitrogen metabolism in the obligate anaerobic thermophiles Chlostridium thermosaccharolyticum and Clostridium thermoautotrophicum differs in several respects. C. thermosaccharolyticum contains a nitrogenase as inferred from NH ₄ ⁺ repressible C₂H₂ reduction, a glutamine synthetase which is partially repressed by ammonium, very labile glutamate synthase activities with both NADH and NADPH, NADPH-dependent glutamate dehydrogenase, and NH ₄ ⁺ -dependent asparagine synthetase. C. thermoautotrophicum contains no nitrogenase, but glutamine synthetase, no glutamate synthase, no glutamate dehydrogenase, but a NADH-dependent alanine dehydrogenase and a NH ₄ ⁺ -dependent asparagine synthetase.Abbreviation GOGAT glutamine-oxoglutarate amidotransferase amidotransferase (glutamate synthase)     

Modulation and mapping of a human plasminogen activator by cell fusion

Neoplastic cells, transformed cells and some normal mammalian cells secrete large amounts of plasminogen activator (PA), an arginine-specific protease which converts plasminogen to plasmin. To study the regulation of PA, we have obtained two classes of mouse-human somatic cell hybrids. PG19, a mouse PA⁺ cell line, was fused with C32 (human PA⁺) or human diploid fibroblasts (PA^?). All hybrids secreted PA. Human- and mouse-specific forms of PA were distinguished in these hybrids by electrophoretic methods. While all hybrids produced the murine PA, many produced the human PA and some did not. All hybrids which produced human PA had chromosome 6 in common. The absence of each of the other human chromosomes did not affect PA expression, while the absence of chromosome 6 correlated with the lack of human PA. We conclude that chromosome 6 carries the structural gene for human PA. These experiments also show that the fusion of mouse PA⁺ cells with human PA-cells results in the activation of the human PA gene.     

Time course study of H-2 and other antigen expression by hybrids of a myeloma cell line with inflammatory macrophages

The hybrids (the CANS lines) between inflammatory macrophages from C57BL/6N (B6) mice (H-2^b) and BALB/c mouse (H-2^d)-derived myeloma cell line NS1 in the early period after cell fusion showed no macrophage functions. However, most of the hybrids expressed these functions after prolonged cultivation accompanied with chromosome loss. In contrast, the hybrids initially displaying myeloma functions ( light chain production) lost this function when they exhibited macrophage functions. We studied the expression of cell-surface antigens in these hybrids and found that hybrids in the early period after cell fusion codominantly expressed both parental cell H-2 antigens (H-2K^b, H-2K^d, and H-2D^d) but not the H-2D^b antigen. On the other hand, aged hybrids strongly expressed the H-2 d antigen but lacked the H-2K^b antigen. Alternatively, these aged hybrids with macrophage functions expressed antigen(s) as detected with antiaged CANS-196 cell sera and asialo GM1 antigen, both of which were thought to be found exclusively on macrophages. Thus, the expression of cell-surface antigens in these hybrids was greatly altered after cell fusion.     

Relaxed tRNA specificity of the Staphylococcus aureus aspartyl-tRNA synthetase enables RNA-dependent asparagine biosynthesis

The human pathogen Staphylococcus aureus is an asparagine prototroph despite its genome not encoding an asparagine synthetase. S. aureus does use an asparaginyl-tRNA synthetase (AsnRS) to directly ligate asparagine to tRNA^Asn. The S. aureus genome also codes for one aspartyl-tRNA synthetase (AspRS). Here we demonstrate the lone S. aureus aspartyl-tRNA synthetase has relaxed tRNA specificity and can be used with the amidotransferase GatCAB to synthesize asparagine on tRNA^Asn. S. aureus thus encodes both the direct and indirect routes for Asn-tRNA^Asn formation while encoding only one aspartyl-tRNA synthetase. The presence of the indirect pathway explains how S. aureus synthesizes asparagine without either asparagine synthetase.     

The Predatory Bacterium Bdellovibrio bacteriovorus Aspartyl-tRNA Synthetase Recognizes tRNAAsn as a Substrate

The predatory bacterium Bdellovibrio bacteriovorus preys on other Gram-negative bacteria and was predicted to be an asparagine auxotroph. However, despite encoding asparaginyl-tRNA synthetase and glutaminyl-tRNA synthetase, B. bacteriovorus also contains the amidotransferase GatCAB. Deinococcus radiodurans, and Thermus thermophilus also encode both of these aminoacyl-tRNA synthetases with GatCAB. Both also code for a second aspartyl-tRNA synthetase and use the additional aspartyl-tRNA synthetase with GatCAB to synthesize asparagine on tRNA^Asn. Unlike those two bacteria, B. bacteriovorus encodes only one aspartyl-tRNA synthetase. Here we demonstrate the lone B. bacteriovorus aspartyl-tRNA synthetase catalyzes aspartyl-tRNA^Asn formation that GatCAB can then amidate to asparaginyl-tRNA^Asn. This non-discriminating aspartyl-tRNA synthetase with GatCAB thus provides B. bacteriovorus a second route for Asn-tRNA^Asn formation with the asparagine synthesized in a tRNA-dependent manner. Thus, in contrast to a previous prediction, B. bacteriovorus codes for a biosynthetic route for asparagine. Analysis of bacterial genomes suggests a significant number of other bacteria may also code for both routes for Asn-tRNA^Asn synthesis with only a limited number encoding a second aspartyl-tRNA synthetase.     

Genetic complementation in hybrid cells derived from two metabolic co-operation defective mammalian cell lines

A series of hybrid clones have been isolated following the somatic cell fusion of two mammalian cell lines, each defective in junctional transfer of metabolites. One of these parental lines is a variant isolated by selection from the metabolic co-operation competent embryonal carcinoma line PC13TG8. The other parent is LMTK⁻ in which inability to transfer was found to be a pre-existing property. Hybrids between these two cell lines are restored in their ability to co-operate, indicating the existence of at least two genetically distinct lesions affecting metabolic co-operation, each of which is recessive. This is the first demonstration that more than one locus is involved in junctional communication.     

Genetic complementation in hybrid cells derived from two metabolic co-operative defective mammalian cell lines

A series of hybrid clones have been isolated following the somatic cell fusion of two mammalian cell lines, each defective in junctional transfer of metabolites. One of these parental lines is a variant isolated by selection from the metabolic co-operation competent embryonal carcinoma line PC13TG8. The other parent is LMTK^? in which inability to transfer was found to be a pre-existing property. Hybrids between these two cell lines are restored in their ability to co-operate, indicating the existence of at least two genetically distinct lesions affecting metabolic co-operation, each of which is recessive. This is the first demonstration that more than one locus is involved in junctional communication.     

Assignment of rat Jun family genes to Chromosome 19 (Junb), Chromosome 5q31–33 (Jun), and Chromosome 16 (Jund)

By means of somatic cell hybrids segregating rat chromosomes, we determined the chromosome localization of three rat genes of the Jun family: Jumb (Chr 19), Jun (=c-Jun) (Chr 5) and Jund (Chr 16). The Jun gene was also localized to the 5q31–33 region by fluorescence in situ hybridization. These rat gene assignments reveal two new homologies with mouse and human chromosomes, and provide a new example of synteny conserved in the human and a rodent species (the mouse), but split between the two rodent species.     

Chromosomal assignment of 11 loci in the rat by mouse-rat somatic hybrids and linkage

Eleven rat genes have been assigned to rat chromosomes by use of mouse × rat somatic hybrids and/or use of linkage to known chromosome markers. Among them, the genes for the inducible nitric oxide synthase (Nos2) and for a vasoactive intestinal peptide receptor (Vipr) are potential candidates for genetic regulation of blood pressure and were localized to rat Chromosomes (Chrs) 10 and 8 respectively. Genes for gastric H,K-ATPase alpha subunit (Atp4a). Class I alcohol dehydrogenase (Adh), and aldolase C (Aldoc) were localized to Chrs 1, 2, and 10 respectively, and thus provide more DNA markers for genetic mapping of quantitative trait loci for blood pressure on those chromosomes. Genes for alkaline phosphatase (Alp1) and cardiac AE-3 Cl^-/HCO₃ ^- exchanger (Ae3) were both localized to Chr 9. Genes for glutamate dehydrogenase (Glud) and gastric H,K-ATPase beta subunit (Atp4b) were localized to Chr 16. The ornithine decarboxylase (Odc) gene and ornithine decarboxylase pseudogene (Odcp) were localized to Chrs 6 and 11 respectively.     

d-Glycerate Transport by the Pea Chloroplast Glycolate Carrier : Studies on [1-C]d-Glycerate Uptake and d-Glycerate Dependent O(2) Evolution

Rapid direct conversion of exogenously supplied [¹⁴C]aspartate to [¹⁴C] asparagine and to tricarboxylic cycle acids was observed in alfalfa (Medicago sativa L.) nodules. Aspartate aminotransferase activity readily converted carbon from exogenously applied [¹⁴C]aspartate into the tricarboxylic acid cycle with subsequent conversion to the organic acids malate, succinate, and fumarate. Aminooxyacetate, an inhibitor of aminotransferase activity, reduced the flow of carbon from [¹⁴C]aspartate into tricarboxylic cycle acids and decreased ¹⁴CO₂ evolution by 99%. Concurrently, maximum conversion of aspartate to asparagine was observed in aminooxyacetate treated nodules (30 nanomoles asparagine per gram fresh weight per hour. Metabolism of [¹⁴C]aspartate and distribution of nodulefixed ¹⁴CO₂ suggest that two pools of aspartate occur in alfalfa nodules: (a) one involved in asparagine biosynthesis, and (b) another supplying a malate/aspartate shuttle. Conversion of [¹⁴C]aspartate to [¹⁴C]asparagine was not inhibited by methionine sulfoximine, a glutamine synthetase inhibitor, or azaserine, a glutmate synthetase, inhibitor. The data did not indicate that asparagine biosynthesis in alfalfa nodules has an absolute requirement for glutamine. Radioactivity in the xylem sap, derived from nodule ¹⁴CO₂ fixation, was markedly decreased by treating nodulated roots with aminooxyacetate, methionine sulfoximine, and azaserine. Inhibitors decreased the [¹⁴C]aspartate and [¹⁴]asparagine content of xylem sap by greater than 80% and reduced the total amino nitrogen content of xylem sap (including nonradiolabeled amino acids) by 50 to 80%. Asparagine biosynthesis in alfalfa nodules and transport in xylem sap are dependent upon continued aminotransferase activity and an uninterrupted assimilation of ammonia via the glutamine synthetase/glutamate synthase pathway. Continued assimilation of ammonia apparently appears crucial to continued root nodule CO₂ fixation in alfalfa.     

Peptide-N 4-(N-acetylglucosaminyl)asparagine amidase (PNGase) activity could explain the occurrence of extracellular xylomannosides in a plant cell suspension

We have previously isolated mannoside and xylomannoside oligosaccharides with one or two terminal reducingN-acetylglucosamine residues from the extracellular medium of white campion (Silene alba) suspension culture. We have now demonstrated the presence of peptide-N ⁴-(N-acetylglucosaminyl)asparagine amidase (PNGase) activity in cell extracts as well in the culture medium that could explain the production of those compounds. An additional xylomannoside, (GlcNAc)Man₃(Xyl)GlcNAc(Fuc)GlcNAc, was characterized, and¹H- and¹³C-NMR assignments for the oligosaccharide Man₃(Xyl)GlcNAc(Fuc)GlcNAc were obtained using homonuclear and heteronuclear spectroscopy (COSY).Abbreviations Endo endo--N-acetylglucosaminidase - Fuc fucose - GlcNAc N-acetylglucosamine - Man mannose - NMR nuclear magnetic resonance - PNGase peptide-N ⁴-(N-acetylglucosaminyl)asparagine amidase - Xyl xylose     

Characterization of single step albizziin-resistant Chinese hamster ovary cell lines with elevated levels of asparagine synthetase activity

The amino acid analog, albizziin, which acts as a competitive inhibitor of asparagine synthetase with respect to glutamine was used to isolate mutants of Chinese hamster ovary cells with alterations in levels of the target enzyme. These mutant lines have been characterized biochemically and genetically. Mutants selected in a single step are up to 40-fold more resistant to the drug than the parental line, express levels of asparagine synthetase activity 6-17-fold greater than that of wild type cells, and act co-dominantly in hybrids. Several classes of mutations can be distinguished on the basis of cross-resistance to beta-aspartyl hydroxamate, another amino acid analog. Studies on asparagine synthetase indicate that resistance to albizziin may be due to altered regulation of asparagine synthetase, structural mutations of the enzyme, and gene amplification.