A yeast gene for trehalose-6-phosphate synthase and its complementation of an Escherichia coli otsA mutant

Abstract A Saccharomyces cerevisiae gene for trehalose-6-phosphate synthase (TPS1) was sequenced. The gene appeared to code for a protein of 495 amino acid residues, giving the protein a molecular mass of 56 kDa. The TPS1 gene was able to restore both osmotolerance and trehalose accumulation during salt stress in an Escherichia coli strain mutated in the otsA gene encoding trehalose-6-phosphate synthase. Complementation studies with E. coli galU mutants showed that the TPS1-encoded trehalose-6-phosphate synthase is UDP-glucose-dependent. Sequence analysis and data base searches showed that TPS1 is allelic to GGS1, byp1, cif1 and fdp1 . A possible gene for trehalose-6-phosphate synthase in Methanobacterium thermoautotrophicum was identified.     

Saccharomyces carlsbergensis fdp mutant and futile cycling of fructose 6-phosphate.

In Saccharomyces, the addition of glucose to cells grown in media lacking sugars causes irreversible inactivation of fructose bisphosphatase. One function of this process might be to prevent a futile cycle of formation and hydrolysis of fructose 1,6-bisphosphate. We tested such cycling by assessing the labeling of the 1-position of glucose in polysaccharides from [6-14C]glucose (J.P. Chambost and D. G. Fraenkel, J. Biol. Chem. 225:2867-2869, 1980) by using mutants impaired in glucose growth and known not to inactivate the phosphatase normally (i.e., the fdp mutant of Saccharomyces carlsbergensis [van de Poll et al., J. Bacteriol. 117:965-970, 1974] and the similar cif mutant of Saccharomyces cerevisiae [Navon et al., Biochemistry 18:4487-4499, 1979] ), as well as in the wild-type strain tested in the 1-h period before inactivation is complete. There was marginal, if any, cycling in any situation, and we conclude that the phosphatase activity is controlled by means other than inactivation or that the extent of cycling is too low to be significant, or both. For the fdp mutant data are also presented on growth, rate of glucose metabolism, metabolite accumulations, enzyme levels, and glucose transport, but the primary lesion is unknown.     

Characterization of the 56-kDa subunit of yeast trehalose-6-phosphate synthase and cloning of its gene reveal its identity with the product of CIF1, a regulator of carbon catabolite inactivation.

Trehalose-6-phosphate synthase is the key enzyme for biosynthesis of trehalose, the major soluble carbohydrate in resting cells of yeast. This enzyme was purified from a strain of Saccharomyces cerevisiae lacking vacuolar proteases. It was found to be a multimeric protein of 630 kDa. Monoclonal antibodies were raised against its smallest subunit (56 kDa) and used for screening a yeast cDNA library. This yielded an immunopositive cDNA clone of 1.7 kb, containing an open reading frame of 1485 base pairs. Its sequence, called TPS1 (for trehalose-6-phosphate synthase), was represented by a single gene in the yeast genome and was found to be almost identical with the recently sequenced CIF1, a gene important for carbon catabolite inactivation, believed to be allelic with FDP1. A mutant obtained by disruption of TPS1 had a very low activity of trehalose-6-phosphate synthase, indicating that TPS1 is an important component of the enzyme. The mutant also showed a growth defect when transferred from glycerol to glucose, a phenotype similar to that of the cif1 and fdp1 mutants deficient in carbon catabolite inactivation. Thus, the smallest subunit of the biosynthetic enzyme trehalose-6-phosphate synthase appears to have, in addition, a central regulatory role in the carbohydrate metabolism of yeast.     

Identification of amino acid residues responsible for the pyrimidine and purine nucleoside specificities of human concentrative Na(+) nucleoside cotransporters hCNT1 and hCNT2.

hCNT1 and hCNT2 mediate concentrative (Na(+)-linked) cellular uptake of nucleosides and nucleoside drugs by human cells and tissues. The two proteins (650 and 658 residues, 71 kDa) are 72% identical in sequence and contain 13 putative transmembrane helices (TMs). When produced in Xenopus oocytes, recombinant hCNT1 is selective for pyrimidine nucleosides (system cit), whereas hCNT2 is selective for purine nucleosides (system cif). Both transport uridine. We have used (i) chimeric constructs between hCNT1 and hCNT2, (ii) sequence comparisons with a newly identified broad specificity concentrative nucleoside transporter (system cib) from Eptatretus stouti, the Pacific hagfish (hfCNT), and (iii) site-directed mutagenesis of hCNT1 to identify two sets of adjacent residues in TMs 7 and 8 of hCNT1 (Ser(319)/Gln(320) and Ser(353)/Leu(354)) that, when converted to the corresponding residues in hCNT2 (Gly(313)/Met(314) and Thr(347)/Val(348)), changed the specificity of the transporter from cit to cif. Mutation of Ser(319) in TM 7 of hCNT1 to Gly enabled transport of purine nucleosides, whereas concurrent mutation of Gln(320) to Met (which had no effect on its own) augmented this transport. The additional mutation of Ser(353) to Thr in TM 8 converted hCNT1/S319G/Q320M, from cib to cif, but with relatively low adenosine transport activity. Additional mutation of Leu(354) to Val (which had no effect on its own) increased the adenosine transport capability of hCNT1/S319G/Q320M/S353T, producing a full cif-type transporter phenotype. On its own, the S353T mutation converted hCNT1 into a transporter with novel uridine-selective transport properties. Helix modeling of hCNT1 placed Ser(319) (TM 7) and Ser(353) (TM 8) within the putative substrate translocation channel, whereas Gln(320) (TM 7) and Leu(354) (TM 8) may exert their effects through altered helix packing.     

Specific mutations in transmembrane helix 8 of human concentrative Na+/nucleoside cotransporter hCNT1 affect permeant selectivity and cation coupling

The Na+/nucleoside cotransporters hCNT1 (650 residues) and hCNT2 (658 residues) are 72% identical in amino acid sequence and contain 13 putative transmembrane helices (TMs). Both transport uridine and adenosine but are otherwise selective for pyrimidine (system cit) and purine (system cif) nucleosides, respectively. Previously, we used site-directed mutagenesis and functional expression in Xenopus oocytes to identify two pairs of adjacent residues in TMs 7 and 8 of hCNT1 (Ser319-Gln320 and Ser353-Leu354) that, when converted to the corresponding residues in hCNT2 (Gly-Met and Thr-Val, respectively), changed the permeant selectivity of the transporter from cit to cif. We now report an investigation of the effects of corresponding mutations in TM 8 alone and demonstrate unique S353T- and L354V-induced changes in nucleoside specificity and cation coupling, respectively. hCNT1 mutation S353T produced a profound decrease in cytidine transport efficiency (Vmax/Km ratio) and, in combination with L354V (S353T/L354V), resulted in a novel uridine-preferring transport phenotype. In addition, the L354V mutation markedly increased the apparent affinity of hCNT1 for Na+ and Li+. Both hCNT1 TM 8 residues exhibited uridine-protectable inhibition by p-chloromercuribenzene sulfonate when converted to Cys, suggesting that they occupy positions within or closely adjacent to a common cation/nucleoside translocation pore.     

L1210/B23.1 cells express equilibrative, inhibitor-sensitive nucleoside transport activity and lack two parental nucleoside transport activities.

Cultured mouse leukemia L1210 cells express the nucleoside-specific membrane transport processes designated es, ei, and cif. The es and ei processes are equilibrative, but may be distinguished by the high sensitivity of the former to 6-[(4-nitrobenzyl)thio]-9-beta-D-ribofuranosylpurine (NBMPR); the cif process is mediated by a Na+/nucleoside cotransporter of low sensitivity to NBMPR. Cells of an ei-deficient clonal line, L1210/MC5-1, were mutagenized, and clones were selected in soft agar medium that contained (i) NBMPR (an inhibitor of es processes), (ii) erythro-9-(2-hydorxy-3-nonyl)adenine (an inhibitor of adenosine deaminase), and (iii) arabinofuranosyladenine (a cytotoxic substrate for the three nucleotide transporters). The selection medium did not allow es activity and selected against cells that expressed the Na(+)-linked cif process. Cells of the L1210/B23.1 clonal isolate were deficient in cif transport activity, and inward fluxes of formycin B, a poorly metabolized analog of inosine, were virtually abolished by NBMPR in these cells. In the mutant cells, nonisotopic formycin B behaved as a countertransport substrate during influx of [3H]formycin B, and inward fluxes of the latter were competitively inhibited by purine and pyrimidine nucleosides. The transport behavior of L1210/B23.1 cells indicates that (i) the mutation/selection procedure impaired or deleted the Na(+)-linked cif process and (ii) es nucleoside transport activity is expressed in the mutant cells.     

A yeast homologue of the bovine lens fibre MIP gene family complements the growth defect of a Saccharomyces cerevisiae mutant on fermentable sugars but not its defect in glucose-induced RAS-mediated cAMP signalling.

Recently a new family of membrane proteins comprising the bovine lens fibre major intrinsic protein, soybean nodulin-26 protein and the Escherichia coli glycerol facilitator has been described [M.E. Baker and M.H. Saier, Jr (1990) Cell, 60, 185-186]. These proteins have six putative membrane spanning domains and one (probably intracellular) intermembrane fragment is particularly well conserved. We have identified a new member of this family in the yeast Saccharomyces cerevisiae. It also possesses the six transmembrane domains and the highly conserved intermembrane sequence. In contrast to the other three proteins which are all approximately 280 amino acids long, the yeast protein has an N-terminal extension of approximately 250 amino acids, which contains a string of 17 asparagine residues and a C-terminal extension of approximately 150 amino acids. The gene, which we called FPS1 (for fdp1 suppressor), suppresses in single copy the growth defect on fermentable sugars of the yeast fdp1 mutant but it is not allelic to FDP1. The deficiency of the fdp1 mutant in glucose-induced RAS-mediated cAMP signalling and in rapid glucose-induced changes in the activity of certain enzymes was not restored. Deletion of FPS1 does not cause any of the phenotypic deficiencies of the fdp1 mutant.     

Genetic analysis of a pleiotropic deletion mutation (delta igf) in Bacillus subtilis.

A delta igf mutation of Bacillus subtilis (formerly called fdpAl) is a large deletion causing pleiotropic defects. The mapping of the delta igf deletion by phage PBS1 transduction revealed the following map order: sacA, thiC, hsrE, delta igf, ts199, purA. To analyze the pleiotropic nature of the delta igf mutation, mutants affected in each property of the pleiotropic mutation were isolated, and the mutations were mapped. iol and gnt mutants could not grow on inositol and gluconate, respectively, and fdp mutants were affected only in fructose-bisphosphatase. The map order from sacA to purA was as follows: sacA, thiC, hsrE, iol-6, gnt-4, fdp-74, hsrB, ts199, purA. The delta igf deletion covered loci from iol-6 to hsrB.     

Isolation and characterization of an L1210 cell line retaining the sodium-dependent carrier cif as its sole nucleoside transport activity

Nucleoside permeation across mammalian cell membranes is complex with at least four distinct transporters known. Two of these (es and ei) are equilibrative (facilitated diffusion) carriers that have been studied is considerable detail. The other two (cif and cit) are concentrative, Na(+)-dependent carriers. A major obstacle to the characterization of the latter two mechanisms has been the lack of suitable model systems expressing only a single nucleoside transport activity. The present study describes the isolation of a cell line that has cif as its sole nucleoside transporter. L1210/MC5-1 cells, which have es and cif transport activity, were mutagenized and plated in soft agar containing two cytotoxic nucleosides (tubercidin (7-deazaadenosine) and cytosine arabinoside) that are substrates for es but not cif. A clonal line (L1210/MA-27.1) was isolated which retained the capacity for Na(+)-dependent [3H]formycin B transport but was unable to transport [3H]thymidine, a substrate for es but not cif. Failure of the mutant to transport thymidine was also demonstrated by the inability of thymidine (with adenine as a purine source) to rescue these cells from methotrexate toxicity. Furthermore, the mutant lacked nitrobenzylthioinosine (NBMPR) binding activity (an integral part of the es transporter) as demonstrated by reversible NBMPR binding and photoaffinity labeling with [3H]NBMPR. Loss of es transport activity was also demonstrated by the failure of NBMPR to affect the toxicity of 2-chlorodeoxyadenosine (IC50 approximately 30 nM) in L1210/MA27.1 cells. In contrast, NBMPR decreased the IC50 for 2-chlorodeoxyadenosine from 100 to 30 nM in the parental L1210/MC5-1 cell line. These results are consistent with the mechanism of NBMPR potentiation of 2-chlorodeoxyadenosine toxicity in L1210 cells being a blockade of efflux via es while the nucleoside is pumped into the cells by the concentrative cif carrier.     

一个中国Gilbert综合征家系的遗传学分析

对一个中国汉族Gilbert综合征遗传家系致病基因突变位点进行鉴定,以期了解该病的分子遗传学基础。首先提取先证者基因组DNA,PCR扩增尿苷二磷酸葡萄糖醛酸转移酶UGT1A1基因的5个外显子,以琼脂糖电泳鉴定PCR产物,纯化后直接测序鉴定。基因扫描显示,与血清胆红素水平密切相关的UGT1A1基因在第1和第5外显子存在纯合突变,而 UGT1A1基因启动子区域和内含子/外显子剪接边界位点序列未检测到突变。进一步对其他家系成员该基因的相应位点进行突变检测,结果显示他们在第1和第5外显子也存在杂合突变,其中还有两个成员在启动子区域检测到(TA)插入突变。对家系成员未抗凝新鲜血液进行生化检测证实了基因突变分析的结果。综合以上结果发现该家系三种突变并存,致病因素为第1和/或第5外显子突变,为显性遗传,两种突变位点纯合导致先证者出现严重胆红素代谢功能障碍。该家系因此成为Gilbert综合征突变位点及其致病机理研究的一个典型临床病例。     

Genetic Mapping of Mutations Affecting Phosphoglucose Isomerase and Fructose Diphosphatase in Escherichia coli

The loci on the Escherichia coli genome of mutations affecting phosphoglucose isomerase (pgi) and fructose diphosphatase (fdp) have been determined by conjugation and transduction experiments, chiefly three-factor crosses. The loci for these two constitutive enzymes of central intermediary metabolism lie in the same region of the chromosome, but they are not cotransducible. The order of some markers in this region of the chromosome is arg(ACFH) metA pgi malB uvrA fdp pyrB thr.     

The Arabidopsis compact inflorescence genes: phase-specific growth regulation and the determination of inflorescence architecture

During their life cycle, higher plants pass through a series of growth phases that are characterized by the production of morphologically distinct vegetative and reproductive organs and by different growth patterns. Three major phases have been described in Arabidopsis: juvenile vegetative, adult vegetative, and reproductive. In this report we describe a novel, phase-specific mutant in Arabidopsis, compact inflorescence (cif). The most apparent aspect of the cif phenotype is a strong reduction in the elongation of internodes in the inflorescence, resulting in the formation of a floral cluster at the apical end of all reproductive shoots. Elongation and expansion of adult vegetative rosette leaves are also compromised in mutant plants. The onset of the cif trait correlates closely with morphological changes marking the phase transition from juvenile to adult, and mutant plants produce normal flowers and are fully fertile. Hence the cif phenotype appears to be adult vegetative phase-specific. Histological sections of mutant inflorescence internodes indicate normal tissue specification, but reduced cell elongation compared to wild-type. compact inflorescence is inherited as a two-gene trait involving the action of a recessive and a dominant locus. These two cif genes appear to be key components of a growth regulatory pathway that is closely linked to phase change, and specifies critical aspects of plant growth and architecture including inflorescence internode length.     

The R1947X mutation of NF1 causing autosomal dominant neurofibromatosis type 1 in a Chinese family

Neurofibromatosis type 1 is a common autosomal dominant disorder with a high rate of penetrance. It is caused by the mutation of the tumor suppressor gene NF1, which encodes neurofibromin. The main function of neurofibromin is down-regulating the biological activity of the proto-oncoprotein Ras by acting as a Ras-specific GTPase activating protein. In this study, we identified a Chinese family affected with neurofibromatosis type 1. The known gene NF1 associated with NF1 was studied by linkage analysis and by direct sequencing of the entire coding region and exon-intron boundaries of the NF1 gene. The R1947X mutation of NF1 was identified, which was co-segregated with affected individuals in the Chinese family, but not present in unaffected family members. This is the first report, which states that the R1947X mutation of NF1 may be one of reasons for neurofibromatosis type 1 in Chinese population.     

Mutational analysis of xenobiotic metabolizing genes (CYP1A1 and GSTP1) in sporadic head and neck cancer patients

CYP1A1 is the phase I enzyme that detoxifies the carcinogen or converts it into a more electrophilic form, metabolized by phase II enzymes like GSTP1. These detoxifying genes have been extensively studied in association with head and neck cancer (HNC) in different ethnic groups worldwide. The current study was aimed at screening genetic polymorphisms of genes CYP1A1 and GSTP1 in 388 Pakistani HNC patients and 150 cancer-free healthy controls, using PCR-SSCP. No already known variants of either gene were found, however a novel frameshift mutation due to insertion of T (g.2842_2843insT) was observed in the CYP1A1 gene. A statistically significant number (5.4%) of HNC cases, with the mean age of 51.75 (±15.7) years, presented this frameshift mutation in the conserved domain of CYP1A1. Another novel substitution mutation in was found in the GSTP1 gene, presenting TA instead of AG. The g.2848A > T polymorphism causes a leucine-to-leucine formation, whereas g.2849G > A causes alanine-to-threonine formation at amino acid positions 166 and 167, respectively. These exonic mutations were found in 9.5% of the HNC patients and in none of the controls. In addition, two intronic deletions of C (g.1074delC and g.1466delC) were also found in 11 patients with a mean age of 46.2 (±15.6) years. In conclusion, accumulation of mutations in genes CYP1A1 and GSTP1 appears to be associated with increased risk of developing HNC, suggesting that mutations in these genes may play a role in the etiology of head and neck cancer.     

A PP1-binding motif present in BRCA1 plays a role in its DNA repair function

Protein phosphatase 1alpha (PP1alpha) regulates phosphorylation of BRCA1, which contains a PP1-binding motif (898)KVTF(901). Mutation of this motif greatly reduces the interaction between BRCA1 and PP1alpha. Here we show that mutation of the PP1-binding motif abolishes the ability of BRCA1 to enhance survival of Brca1-deficient mouse mammary tumor cells after DNA damage. The Rad51 focus formation and comet assays revealed that the DNA repair function of BRCA1 was impaired when the PP1-binding motif was mutated. Analysis of subnuclear localization of GFP-tagged BRCA1 demonstrated that mutation of the PP1-binding motif affected BRCA1 redistribution in response to DNA damage. BRCA1 is required for the formation of Rad51 subnuclear foci after DNA damage. Mutation of the PP1-binding motif in BRCA1 also affected recruitment of Rad51 to sites of DNA damage. Consistent with these findings, knockdown of PP1alpha in BRCA1-proficient cells by small interfering RNA also significantly reduced Rad51 focus formation induced by DNA damage. Further analysis indicated that mutation of the PP1-binding motif compromised BRCA1 activities in homologous recombination. Altogether, our data implicate that interaction with PP1alpha is important for BRCA1 function in DNA repair.     

Genes involved in the uptake and catabolism of gluconate by Escherichia coli.

The isolation and properties of a mutant of Escherichia coli K12 that is totally unable to take up and utilize gluconate are described. Genetical analysis shows this phenotype to be associated with two lesions. One phenotype, designated GntM-, is the result of a mutation in a gene co-transducible with malA; the other, designated GNTS-, is the result of a mutation in a gene (GntS) co-transducible with fdp. The GntS--phenotype differs little from that of wild-type cells, but GntM- GntS+ organisms grow on gluconate only after a prolonged lag and form a gluconate uptake system that is strongly repressed by pyruvate. Moreover, such GntM- mutants readily give rise to further mutants that form a gluconate uptake system, gluconate kinase and 6-phosphogluconate dehydratase consititutively; in partial diploids, this constitutivity is recessive to the inducible character. It is postulated that the GntM- phenotype is due to malfunction of a negative control gene gntR, and that gntS+ specifies the activity of a gluconate uptake system.     

应用PCR技术对先天性长QT综合征KCNQ1 基因进行定点突变的研究

利用聚合酶链反应（PCR）技术对长QT综合征（LQTS）KCNQ1基因进行定点突变的研究。首先设计两对引物（包含预定的突变）,通过3轮PCR扩增,扩增出含有所需突变位点的片段,然后将片段克隆入T载体中,通过酶切连接的方法将突变点引入到pIRES2-EGFP-KCNQ1中,随后用Effectene转染试剂介导转染HEK293细胞。结果在真核表达载体pIRES2-EGFP-KCNQ1基础上获得了KCNQ1 cDNA C934T的突变体,测序表明在序列中发生了预期的突变。将含突变点的pIRES2-EGFP-KCNQ1转染HEK293细胞后,在荧光显微镜下观察到被转染的HEK293细胞发出绿色荧光,表明含突变点的pIRES2-EGFP-KCNQ1得到了表达。Abstract: To study PCR site-directed mutagenesis of long QT syndrome KCNQ1 gene in vitro. The site-directed mutagenesis of LQTS gene KCNQ1 was made by PCR. Two sets of primers were designed according to the sequence of KCNQ1 cDNA, and mismatch was introduced into primers. Mutagenesis was performed in a three-step PCR. The amplified fragments from the third PCR which contained the mutation site were subcloned into the T-vecor PCR2.1.Then the fragments containing the mutation site was obtained from PCR2.1 with restriction enzyme digestion and was inserted into the same restriction site of pIRES2-EGFP-KCNQ1. With Effectene Transfection Reagent, pIRES2-EGFP-KCNQ1 was transfected into HEK293 cell. The sequencing analysis showed that the mutation site was correct. Mutation from T to C in 934 site of KCNQ1 cDNA was found. Under the fluorescence microscope, the green fluorescence was spread in the transfected HEK293 cell, meaning the pIRES2-EGFP-KCNQ1 containing the mutation site was expressed correctly.