Molecular cloning, physical mapping and expression of the bet genes governing the osmoregulatory choline-glycine betaine pathway of Escherichia coli

An analysis of the bet genes governing the osmoregulatory choline-glycine betaine pathway of Escherichia coli was performed. A 9 kb BamHI fragment, located 30 to 39 kb counterclockwise of the EcoRI site of lacZ, coded for all known Bet activities. The following genes were identified: the betA gene for the choline dehydrogenase, the betB gene for the betaine aldehyde dehydrogenase, and the betT gene or operon for the high-affinity choline transport. The betB and the betT genes were named in this paper, and the clockwise gene order was shown to be betA,B,T. Subcloning gave plasmids which expressed each of the three Bet activities separately. The cloned bet genes remained osmotically regulated, indicating the existence of several osmotically regulated promoters in the bet region. Salmonella typhimurium, which carried the bet region of E. coli in the broad-host-range vector pRK293 expressed the three Bet activities and displayed increased osmotic tolerance in the presence of choline.     

Synechococcus sp. PCC7942 Transformed with Escherichia coli bet Genes Produces Glycine Betaine from Choline and Acquires Resistance to Salt Stress

Synechococcus sp. PCC7942, a fresh water cyanobacterium, was transformed by a shuttle plasmid that contains a 9-kb fragment encoding the Escherichia coli bet gene cluster, i.e. betA (choline dehydrogenase), betB (betaine aldehyde dehydrogenase), betI (a putative regulatory protein), and betT (the choline transport system). The expression of these genes was demonstrated in the cyanobacterial cells (bet-containing cells) by northern blot analysis, as well as by the detection of glycine betaine by 1H nuclear magnetic resonance in cells supplemented with choline. Endogenous choline was not detected in either control or bet-containing cells. Both control and bet-containing cyanobacterial cells were found to import choline in an energy-dependent process, although this import was restricted only to bet-containing cells in conditions of salt stress. Glycine betaine was found to accumulate to a concentration of 45 mM in bet-containing cyanobacterial cells, and this resulted in a stabilization of the photosynthetic activities of photosystems I and II, higher phycobilisome contents, and general protective effects against salt stress when compared to control cells. The growth of bet-containing cells was much faster in the presence of 0.375 M NaCl than that of control cells, indicating that the transformant acquired resistance to salt stress.     

Roles of three transporters, CbcXWV, BetT1, and BetT3, in Pseudomonas aeruginosa choline uptake for catabolism

Pseudomonas aeruginosa uses the quaternary amine choline as a carbon source, osmoprotectant, and macromolecular precursor. The importance of choline in P. aeruginosa physiology is highlighted by the presence of multiple known and putative choline transporters encoded within its genome. This report describes the relative roles of three choline transporters, the ABC transporter CbcXWV and two symporters, BetT1 and BetT3, in P. aeruginosa growth on choline under osmotic conditions that are physiologically relevant to eukaryotic hosts. The increased lag phases exhibited by the ΔbetT1 and ΔbetT1 ΔbetT3 mutants relative to the wild type upon transfer to medium with choline as a sole carbon source suggested roles for BetT1 and BetT3 in cells newly exposed to choline. BetT3 and CbcXWV, but not BetT1, were sufficient to support growth on choline. betT1 and betT3 expression was regulated by the repressor BetI and choline, whereas cbcXWV expression was induced by the activator GbdR and glycine betaine. The data support a model in which, upon transfer to a choline-based medium, the glycine betaine derived from choline taken up by BetT1 and BetT3 promotes subsequent GbdR-mediated cbcXWV induction. Furthermore, growth data indicated that the relative contributions of each transporter varied under different conditions, as BetT1 and CbcXWV were the primary choline transporters under hypo-osmolar conditions whereas BetT3 was the major choline transporter under hyperosmolar conditions. This work represents the first systematic approach to unravel the mechanisms of choline uptake in P. aeruginosa, which has the most complex bacterial choline uptake systems characterized to date.     

Genetic analysis of acetan biosynthesis in Acetobacter xylinum: DNA sequence analysis of the aceM gene encoding an UDP-glucose dehydrogenase

Analysis of the nucleotide sequence of a 1592 bp region of Acetobacter xylinum genomic DNA involved in acetan biosynthesis revealed the presence of an open-reading frame (aceM) encoding a protein of 449 amino acids with a molecular weight of 48.5 kDa. The deduced amino acid sequence of aceM displayed high homology to the protein sequences of genes encoding UDP-glucose dehydrogenase (UGDH) activities from other organisms. AceM is likely to encode the UGDH involved in the biosynthesis of UDP-glucuronic acid required for acetanbiosynthesis. This revised version was published online in November 2006 with corrections to the Cover Date.     

Betaine aldehyde dehydrogenase in sorghum.

The ability to synthesize and accumulate glycine betaine is wide-spread among angiosperms and is thought to contribute to salt and drought tolerance. In plants glycine betaine is synthesized by the two-step oxidation of choline via the intermediate betaine aldehyde, catalyzed by choline monooxygenase and betaine aldehyde dehydrogenase (BADH). Two sorghum (Sorghum bicolor) cDNA clones, BADH1 and BADH15, putatively encoding betaine aldehyde dehydrogenase were isolated and characterized. BADH1 is a truncated cDNA of 1391 bp. BADH15 is a full-length cDNA clone, 1812 bp in length, predicted to encode a protein of 53.6 kD. The predicted amino acid sequences of BADH1 and BADH15 share significant homology with other plant BADHs. The effects of water deficit on BADH mRNA expression, leaf water relations, and glycine betaine accumulation were investigated in leaves of preflowering sorghum plants. BADH1 and BADH15 mRNA were both induced by water deficit and their expression coincided with the observed glycine betaine accumulation. During the course of 17 d, the leaf water potential in stressed sorghum plants reached -2.3 MPa. In response to water deficit, glycine betaine levels increased 26-fold and proline levels increased 108-fold. In severely stressed plants, proline accounted for > 60% of the total free amino acid pool. Accumulation of these compatible solutes significantly contributed to osmotic potential and allowed a maximal osmotic adjustment of 0.405 MPa.     

Uncoupling of choline-O-sulphate utilization from osmoprotection in Pseudomonas putida

The genomic context of the recognized bet genes for choline-O-sulphate (COS) utilization in Pseudomonas putida KT2440 is such that betC (choline sulphatase) lies adjacent to an ATP-binding cassette transporter and a LysR type regulator, but well away from betBA, encoding enzymes for transformation of choline into glycine betaine. The consequences of such genetic layout of the functions for COS metabolism have been examined with a suite of genetic and biochemical approaches. An early clue of the utilities of the betencoded products was exposed by the phenotypes of a betC deletion. This mutant still accumulated intact COS but failed to use this compound as carbon or nitrogen source. Furthermore, betC expression was downregulated at high salt concentrations, showing that the principal role of this gene lied in COS metabolism, not in osmoprotection. In contrast, the betBA genes were required for choline transformation into the highly effective compatible solute glycine betaine (and the concomitant endurance to high salt) and also for its utilization as carbon or nitrogen source. Thus, unlike in the cases of Bacillus subtilis and Sinorhizobium meliloti, betC is unrelated to osmoprotection in Pseudomonas putida while the betBA genes are required for both betaine synthesis and tolerance to high osmotic pressure.     

CoA-dependent methylmalonate-semialdehyde dehydrogenase, a unique member of the aldehyde dehydrogenase superfamily. cDNA cloning, evolutionary relationships, and tissue distribution.

Three overlapping cDNA clones encoding methylmalonate-semialdehyde dehydrogenase (MMSDH; 2-methyl-3-oxopropanoate:NAD+ oxidoreductase (CoA-propanoylating); EC 1.2.1.27) have been isolated by screening a rat liver lambda gt 11 library with nondegenerate oligonucleotide probes synthesized according to polymerase chain reaction-amplified portions coding for the N-terminal amino acid sequence of rat liver MMSDH. The three clones cover a total of 1942 base pairs of cDNA, with an open reading frame of 1569 base pairs. The authenticity of the composite cDNA was confirmed by a perfect match of 43 amino acids known from protein sequencing. The composite cDNA predicts a 503 amino acid mature protein with M(r) = 55,330, consistent with previous estimates. Polymerase chain reaction was used to obtain the sequence of the 32 amino acids corresponding to the mitochondrial entry peptide. Northern blot analysis of total RNA from several rat tissues showed a single mRNA band of 3.8 kilobases. Relative mRNA levels were: kidney greater than liver greater than heart greater than muscle greater than brain, which differed somewhat from relative MMSDH protein levels determined by Western blot analysis: liver = kidney greater than heart greater than muscle greater than brain. A 1423-base pair cDNA clone encoding human MMSDH was isolated from a human liver lambda gt 11 library. The human MMSDH cDNA contains an open reading frame of 1293 base pairs that encodes the protein from Leu-74 to the C terminus. Human and rat MMSDH share 89.6 and 97.7% identity in nucleotide and protein sequence, respectively. MMSDH clearly belongs to a superfamily of aldehyde dehydrogenases and is closely related to betaine aldehyde dehydrogenase, 2-hydroxymuconic semialdehyde dehydrogenase, and class 1 and 2 aldehyde dehydrogenases.     

Measurement of the formation of betaine aldehyde and betaine in rat liver mitochondria by a high pressure liquid chromatography-radioenzymatic assay.

A new assay procedure for measurement of rat liver mitochondrial choline dehydrogenase was developed. Oxidation of [methyl-14C]choline to [methyl-14C]betaine aldehyde and [methyl-14C]betaine was measured after isolating these compounds using HPLC. We observed that NAD+ was required for conversion of betaine aldehyde to betaine in rat liver mitochondria. In the absence of this cofactor, oxidation of choline led to the accumulation of betaine aldehyde. The apparent Km of the mitochondrial choline dehydrogenase for choline was 0.14-0.27 mM, which is significantly lower than previously reported. A partially purified preparation of choline dehydrogenase catalyzed betaine aldehyde formation only in the presence of exogenous electron acceptors (e.g., phenazine methosulfate). This preparation failed to catalyze the formation of betaine even in the presence of NAD+, indicating that betaine aldehyde dehydrogenase may be a separate enzyme from choline dehydrogenase.     

Cloning, sequence analysis, and purification of choline oxidase from Arthrobacter globiformis: a bacterial enzyme involved in osmotic stress tolerance

Choline oxidase catalyzes the four-electron oxidation of choline to glycine betaine, one of a limited number of compounds that accumulate to high levels in the cytoplasm of cells to prevent dehydration and plasmolysis in adverse hyperosmotic environments. In the present study, the highly GC rich codA gene encoding for choline oxidase was cloned from genomic DNA of Arthrobacter globiformis strain ATCC 8010 and expressed to high yields in Escherichia coli strain Rosetta(DE3)pLysS. The resulting enzyme was purified to high levels in a single chromatographic step using DEAE-Sepharose, as shown by SDS-PAGE analysis. Denaturation and mass spectroscopic analyses showed that the covalent linkage between the FAD cofactor and the protein is preserved in recombinant choline oxidase, consistent with protein flavinylation being a self-catalytic process. The enzyme was shown to be a homodimer of 120,000 Da by size-exclusion chromatography and to be active with both choline and betaine aldehyde as substrate. Sequencing analysis indicated that the nucleotide sequence of codA originally reported in GenBank contains seven flaws, resulting in a translated protein with a significantly altered amino acid sequence between position 298 and 410.     

Isolation and molecular characterization of theSinorhizobium meliloti bet locus encoding glycine betaine biosynthesis

To cope with osmotic stress,Sinorhizobium meliloti accumulates organic compatible solutes such as glutamate, trehalose, N-acetylglutaminylglutamine amide, and the most potent osmoprotectant glycine betaine. In order to study the regulation of the glycine betaine biosynthetic pathway, a genetic and molecular analysis was performed. We have selected a Tn5 mutant ofS. meliloti which was deficient in choline dehydrogenase activity. The mutation was complemented using a genomic bank ofS. meliloti. Subcloning and DNA sequencing of a 8-6 kb region from the complemented plasmid showed four open reading frames with an original structural organization of thebet locus compared to that described inE. coli. (i) ThebetB and thebetA genes which encode a glycine betaine aldehyde dehydrogenase, and a choline dehydrogenase, respectively, are separated from thebetI gene (regulatory protein) by an additional gene namedbetC. The BetC protein shares about 30% identity with various sulphatases and is involved in the conversion of choline-O-sulphate into choline. Choline-O-sulphate is used as an osmoprotectant, or as a carbon or sulphur source and this utilization is dependent on a functionalbet locus. (ii) No sequence homologous tobetT (encoding a high-affinity choline transport system inE. coli) was found in the vicinity of thebet locus. (iii) ThebetB and thebetA genes, as well as thebetI and thebetC genes are, respectively, separated by 211 and 167 bp sequences containing inverted repeats. Southern blot analysis indicated that thebet locus is located on the chromosome, and not on the megaplasmids.     

Gene array-based identification of changes that contribute to ethanol tolerance in ethanologenic Escherichia coli: comparison of KO11 (parent) to LY01 (resistant mutant)

Escherichia coli KO11 (parent) and LY01 (mutant) have been engineered for the production of ethanol. Gene arrays were used to identify expression changes that occurred in the mutant, LY01, during directed evolution to improve ethanol tolerance (defined as extent of growth in the presence of added ethanol). Expression levels for 205 (5%) of the ORFs were found to differ significantly (p < 0.10) between KO11 and LY01 under each of six different growth conditions (p < 0.000001). Statistical evaluation of differentially expressed genes according to various classification schemes identified physiological areas of importance. A large fraction of differentially expressed ORFs were globally regulated, leading to the discovery of a nonfunctional fnr gene in strain LY01. In agreement with a putative role for FNR in alcohol tolerance, increasing the copy number of fnr(+) in KO11(pGS196) decreased ethanol tolerance but had no effect on growth in the absence of ethanol. Other differences in gene expression provided additional clues that permitted experimentation. Tolerance appears to involve increased metabolism of glycine (higher expression of gcv genes) and increased production of betaine (higher expression of betIBA and betT encoding betaine synthesis from choline and choline uptake, respectively). Addition of glycine (10 mM) increased ethanol tolerance in KO11 but had no effect in the absence of ethanol. Addition of betaine (10 mM) increased ethanol tolerance by over 2-fold in both LY01 and KO11 but had no effect on growth in the absence of ethanol. Both glycine and betaine can serve as protective osmolytes, and this may be the basis of their beneficial action. In addition, the marAB genes encoding multiple antibiotic resistance proteins were expressed at higher levels in LY01 as compared to KO11. Interestingly, overexpression of marAB in KO11 made this strain more ethanol-sensitive. Overexpression of marAB in LY01 had no effect on ethanol tolerance. Increased expression of genes encoding serine uptake (sdaC) and serine deamination (sdaB) also appear beneficial for LY01. Addition of serine increased the growth of LY01 in the presence and absence of ethanol but had no effect on KO11. Changes in the expression of several genes concerned with the synthesis of the cell envelope components were also noted, which may contribute to increased ethanol tolerance.     

Isolation of cDNA and enzymatic properties of betaine aldehyde dehydrogenase from Zoysia tenuifolia

We isolated cDNAs encoding betaine aldehyde dehydrogenase (BADH, EC 1.2.1.8) from the salt-tolerant Poaceae, Zoysia tenuifolia by polymerase chain reactions. Zoysia betaine aldehyde dehydrogenase 1 (ZBD1) is 1892bp long and codes for 507 amino acids. The deduced amino acid sequence of ZBD1 is 88% similar to the sequence of rice BADH. Ten cDNA clones were isolated from a cDNA Library of salt-treated Z. tenuifolia by using the ZBD1 fragment as a probe. The proteins coded in some clones were more homologous to BBD2, the cytosolic BADH of barley, than to ZBD1. To investigate their enzymatic properties, ZBD1 and spinach BADH were expressed in Escherichia coli and purified. The optimal pH of ZBD1 was 9.5, which was more alkaline than that of spinach BADH. ZBD1 was less tolerant to NaCl than spinach BADH. ZBD1 showed not only BADH activity but also aminoaldehyde dehydrogenase activity. The Km values of ZBD1 for betaine aldehyde, 4-aminobutyraldehyde (AB-ald), and 3-aminopropionaldehyde (AP-ald) were 291, 49, and 4.0 microM, respectively. ZBD1 showed higher specific activities for AB-ald and AP-ald than did spinach BADH.     

Purification and properties of betaine aldehyde dehydrogenase from Xanthomonas translucens

Betaine aldehyde dehydrogenase from Xanthomonas translucens was purified to apparent homogeneity by ammonium sulfate fractionation, followed by ion-exchange, butyl-Toyopearl and gel filtration chromatography. The amino acid composition and the N-terminal sequence of 35 amino acid residues were determined. The enzyme was found to be a tetramer with identical 50 kDa subunits. Both NAD and NADP could be used as a cofactor for the enzyme and K_m values for NAD and NADP were 70 μM and 50 μM, respectively. The enzyme was highly specific for betaine aldehyde and the K_m value for betaine aldehyde was 0.19 mM.     

Functional characterization of betaine/proline transporters in betaine-accumulating mangrove

Betaine is an important osmoprotectant in many plants, but its transport activity has only been demonstrated using a proline transporter from tomato, a betaine-nonaccumulating plant. In this study, two full-length and one partial transporter genes were isolated from betaine-accumulating mangrove Avicennia marina. Their homologies to betaine transporters from bacteria and betaine/4-aminobutyrate transporters from mammalian cells were low but were high to proline transporters from Arabidopsis and tomato. Two full-length transporters could complement the Na(+)-sensitive phenotype of the Escherichia coli mutant deficient in betT, putPA, proP, and proU. Both transporters could efficiently take up betaine and proline with similar affinities (K(m), 0.32-0.43 mm) and maximum velocities (1.9-3.6 nmol/min/mg of protein). The uptakes of betaine and proline were significantly inhibited by mono- and dimethylglycine but only partially inhibited by betaine aldehyde, choline, and 4-aminobutyrate. Sodium and potassium chloride markedly enhanced betaine uptake rates with optimum concentrations at 0.5 m, whereas sucrose showed only modest activation. The change of amino acids Thr(290)-Thr-Ser(292) in a putative periplasmic loop to Arg(290)-Gly-Arg(292) yielded the active transporter independent of salts, suggesting the positive charge induced a conformational change to the active form. These data clearly indicate that the betaine-accumulating mangrove contains betaine/proline transporters whose properties are distinct from betaine transporters of bacteria and mammalian cells.     

一株南极嗜冷杆菌产丙酮酸脱氢酶的 性质研究及基因克隆

从南极普利兹湾深海沉积物中筛选到一株嗜冷杆菌7195。其16SrDNA序列分析表明谊菌株属于嗜冷杆菌属（Psychrobacter）,从该菌的全基因组DNA中克隆到编码丙酮酸脱氢酶系E1（PDHcEI）的完整ORF,全长为2817bp,使用DNAMAN5．1对其全长ORF的PDHcEI基因进行分析,PDHcE1基因编码一个由939AA残基组成、分子量预计为100663Da的PDHcEI蛋白质,与Psychrobacter sp．273—4的PDHcE1有78．53％的相似性。     

Molecular analysis of two genes of the Escherichia coli gab cluster: nucleotide sequence of the glutamate:succinic semialdehyde transaminase gene (gabT) and characterization of the succinic semialdehyde dehydrogenase gene (gabD).

We have characterized two genes of the Escherichia coli K-12 gab cluster, which encodes the enzymes of the 4-aminobutyrate degradation pathway. The nucleotide sequence of gabT, coding for glutamate:succinic semialdehyde transaminase (EC 2.6.1.19), alternatively known as 4-aminobutyrate transaminase, was determined. The structural gene consists of 1,281 nucleotides specifying a protein of 426 amino acids with a molecular mass of 45.76 kDa. The protein shows significant homologies to the ornithine transaminases from Saccharomyces cerevisiae and from rat and human mitochondria. Three functionally and structurally important amino acid residues of the transaminase were identified by sequence comparison studies, and evolutionary relationships of the aminotransferases are discussed. The gabD gene, encoding succinic semialdehyde dehydrogenase (EC 1.2.1.16), was cloned and shown to be located adjacent to the 5' end of gabT. Expression studies with subfragments of the initially cloned DNA region revealed a maximal size of 1.7 kb for gabD. Both genes are cotranscribed from a promoter located upstream of gabD.