Genetic and physical characterization of putP, the proline carrier gene of Escherichia coli K12

Summary Two new mutants of E. coli K12, strains PT9 and PT32 were isolated, that were defective in proline transport. They had no high affinity proline transport activity, but their cytoplasmic membranes retained proline binding activity with altered sensitivity to inhibition by p-chloromercuribenzoate(pCMB). The lesion was mapped at the putP gene, which is located at min 23 on the revised E. coli genetic map (Bachmann 1983) as a composite gene in the proline utilization gene cluster, putP, putC, and putA, arranged in this order. The putC gene was shown to regulate the synthesis of proline dehydrogenase (putA gene product).Hybrid plasmids carrying the put region (Motojima et al. 1979; Wood et al. 1979) were used to construct the physical map of the put region. The possible location of the putP gene in the DNA segment was determined by subcloning the putP gene, genetic complementation, and recombination analyses using several proline transport mutants.Abbreviations pCMB p-chloromercuribenzoate - DM Davis and Mingioli - Ap ampicillin - NTG N-methyl-N-nitro-N-nitrosoguanidine - EMS ethylmethane sulfonate - Str streptomycin - Tet tetracycline - Ac l-azetidine-2-carboxylic acid - DHP 3, 4-dehydro-d,l-proline - MTT 3-(4,5-dimethyl-2)2,5-diphenyl tetrazolium bromide - Tris tris(hydroxymethyl)aminomethane - EDTA ethylenediamine tetraacetic acid - Kan kanamycin - Spc spectinomycin     

Dissecting the molecular mechanism of ion-solute cotransport: Substrate specificity mutations in theputP gene affect the kinetics of proline transport

Summary Rare mutations that alter the substrate specificity of proline permease cluster in discrete regions of theputP gene, suggesting that they may replace amino acids at the active site of the enzyme. IfputP substrate specificity mutations directly alter the active site of proline permease, the mutants should show specific defects in the kinetics of proline transport. In order to test this prediction, we examined the kinetics of threeputP substrate specificity mutants. One class of mutation increases theK _m over 120-fold but only decreases theV _max fourfold. SuchK _m mutants may be specifically defective in substrate recognition, thus identifying an amino acid critical for substrate binding. Another class of mutation decreases theV _max 80-fold without changing theK _m .V _max mutants appear to alter the rate of substrate translocation without affecting the substrate binding site. The last class of mutation alters both theK _m andV _max of proline transport. These results indicate that substrate specificity mutations alter amino acids critical for Na⁺/proline symport.     

Nucleotide sequence of the Vibrio alginolyticus glnA region

The nucleotide sequence of a 4 kb fragment containing the Vibrio alginolyticus glnA, ntrB and ntrC genes was determined. The upstream region of the glnA gene contained tandem promoters. The upstream promoter resembled the consensus sequence for Escherichia coli ⁷⁰ promoters whereas the presumptive downstream promoter showed homology with nitrogen regulated promoters. Four putative NR_I binding sites were located between the tandem promoters. The ntrB gene was preceded by a single presumptive NR_I binding site. The ntrC gene was located 45 base pairs downstream from the ntrB gene. The V. alginolyticus ntrB and ntrC genes were able to complement ntrB, ntrC deletions in E. coli.Abbreviations bp base pair(s) - CAP catabolite-activating protein - GS glutamine synthetase - kb kilobase(s) - ORF open reading frame - SD Shine-Dalgarno     

Repression and catabolite gene activation in the araBAD operon.

Catabolite gene activation of the araBAD operon was examined by using catabolite gene activator protein (CAP) site deletion mutants. A high-affinity CAP-binding site between the divergently orientated araBAD and araC operons has been previously identified by DNase I footprinting techniques. Subsequent experiments disagreed as to whether this site is directly involved in stimulating araBAD expression. In this paper, we present data showing that deletions generated by in vitro mutagenesis of the CAP site led to a five- to sixfold reduction in single-copy araBAD promoter activity in vivo. We concluded that catabolite gene activation of araBAD involves this CAP site. The hypothesis that CAP stimulates the araBAD promoter primarily by relieving repression was then tested. The upstream operator araO2 was required for repression, but we observed that the magnitude of CAP stimulation was unaffected by the presence or absence of araO2. We concluded that CAP plays no role in relieving repression. Other experiments showed that when CAP binds it induces a bend in the ara DNA; similar bending has been reported upon CAP binding to lac DNA. This conformational change in the DNA may be essential to the mechanism of CAP activation.     

Biochemical and molecular characterisation of the 2,3-dichloro-1-propanol dehalogenase and stereospecific haloalkanoic dehalogenases from a versatile <Emphasis Type="Italic">Agrobacterium</Emphasis> sp.

We previously reported the presence of both haloalcohol and haloalkanoate dehalogenase activity in the Agrobacterium sp. strain NHG3. The versatile nature of the organism led us to further characterise the genetic basis of these dehalogenation activities. Cloning and sequencing of the haloalcohol dehalogenase and subsequent analysis suggested that it was part of a highly conserved catabolic gene cluster. Characterisation of the haloalkanoate dehalogenase enzyme revealed the presence of two stereospecific enzymes with a narrow substrate range which acted on d -2-chloropropionic and I-2-chloropropionoic acid, respectively. Cloning and sequencing indicated that the two genes were separated by 87 bp of non-coding DNA and were preceded by a putative transporter gene 66 bp upstream of the d-specific enzyme.     

Extracellular arabinases in Aspergillus nidulans: the effect of different cre mutations on enzyme levels

The regulation of the syntheses of two arabinan-degrading extracellular enzymes and several intracellular l-arabinose catabolic enzymes was examined in wild-type and carbon catabolite derepressed mutants of Aspergillus nidulans. α-l-Arabinofuranosidase B, endoarabinase, l-arabinose reductase, l-arabitol dehydrogenase, xylitol dehydrogenase, and l-xylulose reductase were all inducible to varying degrees by l-arabinose and l-arabitol and subject to carbon catabolite repression by d-glucose. With the exception of l-xylulose reductase, all were clearly under the control of creA, a negative-acting wide domain regulatory gene mediating carbon catabolite repression. Measurements of intracellular enzyme activities and of intracellular concentrations of arabitol and xylitol in mycelia grown on d-glucose in the presence of inducer indicated that carbon catabolite repression diminishes, but does not prevent uptake of inducer. Mutations in creA resulted in an apparently, in some instances very marked, elevated inducibility, perhaps reflecting an element of “self” catabolite repression by the inducing substrate. creA mutations also resulted in carbon catabolite derepression to varying degrees. The regulatory effects of a mutation in creB and in creC, two genes whose roles are unclear, but likely to be indirect, were, when observable, more modest. As with previous data showing the effect of creA mutations on structural gene expression, there were striking instances of phenotypic variation amongst creA mutant alleles and this variation followed no discernible pattern, i.e. it was non-hierarchical. This further supports molecular data obtained elsewhere, indicating a direct role for creA in regulating structural gene expression, and extends the range of activities under creA control.     

TUF factor binds to the upstream region of the pyruvate decarboxylase structural gene (PDC1) of Saccharomyces cerevisiae

Summary The upstream activation site of the pyruvate decarboxylase gene, PDC1, of Saccharomyces cerevisiae contains an RPG box, and mediates the increase in expression of a PDC1-lacZ fusion gene during growth on glucose. Oligonucleotide replacement experiments indicate that the RPG box functions as an absolute activator of expression, but other elements (possibly CTTCC repeats) are required for carbon source regulation, and maximal expression. Gel retardation and oligonucleotide competition experiments suggest that the DNA binding factor TUF interacts with the RPG box in the upstream region of PDC1. Binding of TUF factor is not carbon source dependent in in vitro experiments, and is probably not responsible for glucose induction of PDC1 expression.     

The Escherichia coli dam gene is expressed as a distal gene of a new operon

Summary DNA containing the Escherichia coli dam gene and sequences upstream from this gene were cloned from the Clarke-Carbon plasmids pLC29-47 and pLC13-42. Promoter activity was localized using pKO expression vectors and galactokinase assays to two regions, one 1650–2100 bp and the other beyon 2400 bp upstream of the dam gene. No promoter activity was detected immediately in front of this gene; plasmid pDam118, from which the nucleotide sequence of the dam gene was determined, is shown to contain the pBR322 promoter for the primer RNA from the pBR322 rep region present on a 76 bp Sau3A fragment inserted upstream of the dam gene in the correct orientation for dam expression. The nucleotide sequence upstream of dam has been determined. An open reading frame (ORF) is present between the nearest promoter region and the dam gene. Codon usage and base frequency analysis indicate that this is expressed as a protein of predicted size 46 kDa. A protein of size close to 46 kDa is expressed from this region, detected using minicell analysis. No function has been determined for this protein, and no significant homology exist between it and sequences in the PIR protein or GenBank DNA databases. This unidentified reading frame (URF) is termed urf-74.3, since it is an URF located at 74.3 min on the E. coli chromosome. Sequence comparisons between the regions upstream of urf-74.3 and the aroB gene show that the aroB gene is located immediately upstream of urf-74.3, and that the promoter activity nearest to dam is found within the aroB structural gene. This activity is relatively weak (about 15% of that of the E. coli gal operon promoter). The promoter activity detected beyond 2400 bp upstream of dam is likely to be that of the aroB gene, and is 3 to 4 times stronger than that found within the aroB gene. Three potential DnaA binding sites, each with homology of 8 of 9 bp, are present, two in the aroB promoter region and one just upstream of the dam gene. Expression through the site adjacent to the dam gene is enhanced 2-to 4-fold in dnaA mutants at 38°C. Restriction site comparisons map these regions precisely on the Clarke-Carbon plasmids pLC13-42 and pLC29-47, and show that the E. coli ponA (mrcA) gene resides about 6 kb upstream of aroB.     

Control of gene expression in plant cells using a 434:VP16 chimeric protein

The herpes simplex virus type 1 VP16 polypeptide is a potent trans-activator of viral gene expression. We have tested the ability of the VP16 activation domain to activate gene expression in plant cells. A plasmid encoding a translational fusion between the full-length 434 repressor and the C-terminal 80 amino acids of VP16, was constructed. When expressed in Escherichia coli, the chimeric protein binds efficiently to 434-binding motifs (operators). For expression in plant cells, the chimeric activator gene was placed between the cauliflower mosaic virus (CaMV) 35S promoter and nos terminator sequences in a pUC-based plasmid. The 434 operators were placed upstream of a minimal CaMV 35S promoter linked to the E. coli gus reporter gene. This reporter-expression cassette was then incorporated into the same plasmid as the 434 cI/VP16 activator-expression cassette. Two control plasmids were also constructed, one encoding the 434 protein with no activator domain and the second a chimeric activator with no DNA-binding domain. The chimeric activator was tested for its ability to activate gene expression in a tobacco protoplast transient assay system. Results are presented to show that we can obtain in plant cells significant activation of gene expression that is dependent on both DNA-binding and the presence of the activator domain.     

Cloning and initial characterization of the Bordetella pertussis fur gene

In several Gram-negative pathogens the fur (ferric uptake regulator) gene product controls the expression of many genes involved in iron uptake and virulence. To facilitate the study of iron-regulated gene expression in Bordetella pertussis, we cloned the fur gene from this organism. The B. pertussis fur gene product was 54% identical to the Escherichia coli Fur and complemented two E. coli fur mutants. As with the E. coli fur gene, sequences upstream of the B. pertussis fur were homologous to the consensus Fur-binding site and to the consensus catabolite activator protein binding site.     

The mglB sequence of Salmonella typhimurium LT2; promoter analysis by gene fusions and evidence for a divergently oriented gene coding for the mgl repressor

Summary The mglB gene of Salmonella typhimurium LT2 coding for the galactose-binding protein (GBP) was sequenced. We compared the deduced amino acid sequence with the GBP sequence of Escherichia coli K12. The mature proteins differ in only 19 of 309 amino acid residues, corresponding to 94% homology. Analysis of the mglB control region by promoter-probe vectors revealed that two promoters, P1 and P2, constitute the mgl control region (P _mgl ). P1 and P2 function in a synergistic way. P1 is the main promoter of the operon; its activity is 20 times the activity of P2. Both promoters are activated by the cyclic adenosine monophosphate catabolite activator protein (cAMP/CAP) complex. While P1 is inactive in the absence of the cAMP/CAP complex, there is residual activity of P2 under these conditions. Studies on the inducibility of the mglBAEC operon using multicopy plasmid promoter-probe vectors were hampered by the titration of the mgl repressor resulting in a partially constitutive expression of the mgl operon. The results indicate that only P1 is responding to induction by D-fucose. A weak promoter, P _D , within the P1 region but divergent to it was found. P _D is neither stimulated by the cAMP/CAP complex nor by D-fucose. We cloned the gene located downstream to P _D and found it to strongly repress the expression of the mgl operon. We termed this gene mglD. The presence of D-fucose abolished the repression caused by the plasmid-encoded mglD gene product.Abbreviations IPTG isopropyl-1-thic--D-galatopyranoside - ONPG 2-nitrophenyl--D-galatopyranoside - XG 5-bromo-4-chloro-3-indolyl--D-galatopyranoside - Kan^r Kanamycin resistance     

Proline production by regulatory mutants of Serratia marcescens

Summary Proline-producing strains of Serratia marcescens Sr41 were constructed by three rounds of mutagenesis. A strain SP103 which did not degrade l-proline carried the putA mutation leading to lack of proline oxidase. A 3,4-dehydroproline-resistant mutant SP105, derived from strain SP103, carried the dpr-1 mutation which resulted in desensitization of the feedback inhibition of glutamate kinase. Strain SP103 produced 5.5 mg of l-proline per ml of fermentation medium containing sucrose and urea. Growth inhibition by proline analogs was enhanced when succinate was used as a carbon source in the medium. A thiazolidine-4-carboxylate-resistant mutant SP126 derived from strain SP105 produced 20.5 mg of l-proline per ml of medium. The mutation carried by strain SP126 might be distant from dpr-1 and putA mutations on the chromosome. Pyrroline-5-carboxylate reductase was not repressed by proline in S. marcescens Sr41.     

Characterization of the <Emphasis Type="Italic">AXDH</Emphasis> gene and the encoded xylitol dehydrogenase from the dimorphic yeast <Emphasis Type="Italic">Arxula adeninivorans</Emphasis>

The xylitol dehydrogenase-encoding Arxula adeninivorans AXDH gene was isolated and characterized. The gene includes a coding sequence of 1107 bp encoding a putative 368 amino acid protein of 40.3 kDa. The identity of the gene was confirmed by a high degree of homology of the derived amino acid sequence to that of xylitol dehydrogenases from different sources. The gene activity was regulated by carbon source. In media supplemented with xylitol, D-sorbitol and D-xylose induction of the AXDH gene and intracellular accumulation of the encoded xylitol dehydrogenase was observed. This activation pattern was confirmed by analysis of AXDH promoter – GFP gene fusions. The enzyme characteristics were analysed from isolates of native strains as well as from those of recombinant strains expressing the AXDH gene under control of the strong A. adeninivorans-derived TEF1 promoter. For both proteins, a molecular mass of ca. 80 kDa was determined corresponding to a dimeric structure, an optimum pH at 7.5 and a temperature optimum at 35 °C. The enzyme oxidizes polyols like xylitol and D-sorbitol whereas the reduction reaction is preferred when providing D-xylulose, D-ribulose and L-sorbose as substrates. Enzyme activity exclusively depends on NAD⁺ or NADH as coenzymes.