A comparative study of gnd genes from Escherichia coli strains isolated from natural populations and laboratory strains and from Salmonella typhimurium was undertaken. In the accompanying paper (G. J. Barcak and R. E. Wolf, Jr., J. Bacteriol. 170:365-371, 1988), we showed that the growth-rate-dependent regulation of gnd expression was conserved among four natural E. coli isolates and E. coli B/r in a manner qualitatively similar to that of the gene from E. coli K-12. Here, we report the DNA sequence of the 5' regulatory region and the first 125 codons of the structural gene for the five E. coli gnd genes and the gnd gene from S. typhimurium LT-2. The sequences differed from one another by 5% on the average. All sequences defined putative secondary structures of the mRNA leader, which were previously proposed to be important in the regulation of the K-12 gene. In addition, a sequence between codons 69 and 74, which is highly complementary to the ribosome-binding site of the mRNA, was conserved in all the genes. The sequence data are discussed with respect to potential regulatory consequences.

OBJECTIVES--To examine the expression of the natural killer (NK) antigen CD56, and T cell receptor delta chain antigen (TCR delta), expressed on the gamma delta T cell subset, in patients with scleroderma, and to correlate levels of expression with clinical characteristics. METHODS--Peripheral blood mononuclear cells (PBMCs) from 15 patients with scleroderma and 11 controls were obtained from heparinised blood on a ficoll/hypaque gradient, stained with monoclonal antibodies, and examined by flow cytometry for expression of CD56 and TCR delta. RESULTS--Overall, the proportion of PBMCs expressing CD56 in the patient group (14.4 (SEM 2.6)%) was not significantly different from controls (8.75 (2.6)%). The greatest levels of expression were found in patients late (more than three years) in their disease course (18.1 (3.3)%) and in patients who did not express anti-Scl-70 antibodies (17.1 (3.5)%). The proportion of gamma delta T cells was significantly lower in the patient group (1.61 (0.52)% v control 2.61 (0.46)%) (p < 0.05). Patients early in their disease or with anti-Scl-70 antibodies accounted for the reduction in gamma delta T cells (0.71 (0.29)% and 0.96 (0.41)% (p < 0.01 and p < 0.05, respectively). CONCLUSIONS--This study emphasis that NK and gamma delta T cell numbers vary depending upon patient characteristics and may help explain prior contradictory reports. Decreased numbers of gamma delta T cells were seen in scleroderma patients, especially those with anti-Scl-70 antibodies and a disease duration of less than three years.

The Rob protein, isolated on the basis of its ability to bind to the right arm of the Escherichia coli origin of chromosomal replication, is about 50% identical in amino acid sequence to SoxS and MarA, the direct regulators of the superoxide (soxRS) and multiple antibiotic resistance (mar) regulons, respectively. Having previously demonstrated that SoxS (as a MalE-SoxS fusion protein) and MarA are essentially identical in their abilities to activate in vitro transcription of genes of the sox-mar regulons, we investigated the properties of Rob as a transcriptional activator. We found that Rob (i) activates the transcription of zwf,fpr,fumC, micF, nfo, and sodA, (ii) requires a 21-bp soxbox-marbox-robbox sequence to activate zwf transcription, (iii) protects the soxbox/marbox/robbox from attack by DNase 1, (iv) is ambidextrous, i.e., requires the C-terminal domain of the alpha subunit of RNA polymerase for activation of zwf but not fumC or micF, (v) bends zwf and fumC DNA, and (vi) binds zwf and fumC DNA as a monomer. Since these transcription activation properties of Rob are virtually identical to those of MalE-SoxS and MarA, it appears as if the E. coli genome encodes three genes with the same functional capacity. However, in contrast to SoxS and MarA, whose syntheses are induced by specific environmental stimuli and elicit a clear defense response, Rob is expressed constitutively and its normal function is unknown.

Transcriptional activation of the promoters of the mar/soxRS regulons by the sequence-related but independently inducible MarA and SoxS proteins renders Escherichia coli resistant to a broad spectrum of antibiotics and superoxide generators. Here, the effects of MarA and SoxS on transcription of the marRAB promoter itself were assayed in vitro by using a minimal transcription system and in vivo by assaying beta-galactosidase synthesized from marR::lacZ fusions. Purified MarA and MalE-SoxS proteins stimulated mar transcription about 6- and 15-fold, respectively, when the RNA polymerase/DNA ratio was 1. Purified MarA bound as a monomer to a 16-bp "marbox" located 69 to 54 nucleotides upstream of a putative RNA initiation site. Deletion of the marbox reduced MarA-mar binding 100-fold, abolished the stimulatory effects of MarA and SoxS on transcription in vitro, and reduced marR::lacZ synthesis about 4-fold in vivo. Deletion of upstream DNA adjoining the marbox reduced MarA binding efficiency 30-fold and transcriptional activation 2- to 3-fold, providing evidence for an accessory marbox. Although MarA and the mar operon repressor, MarR, bound to independent sites, they competed for promoter DNA in band shift experiments. Assays of marR::lacZ transcriptional fusions in marRAB deletion or soxRS deletion strains showed that the superoxide generator paraquat stimulates mar transcription via soxRS and that salicylate stimulates mar transcription both by antagonizing MarR and by a MarR-independent mechanism. Thus, transcription of the marRAB operon is autorepressed by MarR and autoactivated by MarA at a site that also can be activated by SoxS.

Expression of the marA or soxS genes is induced by exposure of Escherichia coli to salicylate or superoxides, respectively. This, in turn, enhances the expression of a common set of promoters (the mar/soxRS regulons), resulting in both multiple antibiotic and superoxide resistance. Since MarA protein is highly homologous to SoxS, and since a MalE-SoxS fusion protein has recently been shown to activate soxRS regulon transcription, the ability of MarA to activate transcription of these genes was tested. MarA was overexpressed as a histidine-tagged fusion protein, purified, cleaved with thrombin (leaving one N-terminal histidine residue), and renatured. Like MalE-SoxS, MarA (i) activated the transcription of zwf, fpr, fumC, micF, nfo, and sodA; (ii) required a 21-bp "soxbox" sequence to activate zwf transcription; and (iii) was "ambidextrous," i.e., required the C-terminal domain of the alpha subunit of RNA polymerase for activation of zwf but not fumC or micF. Thus, the mar and soxRS systems use activators with very similar specificities and mechanisms of action to respond to different environmental signals.

Previous research has indicated that the growth rate-dependent regulation of Escherichia coli gnd expression involves the internal complementary sequence (ICS), a negative control site that lies within the 6-phosphogluconate dehydrogenase coding sequence. To determine whether the ICS acts as a transcriptional operator or attenuator, we measured beta-galactosidase-specific activities in strains carrying gnd-lac operon and protein fusions containing or lacking the ICS. Whereas the presence of the ICS repressed beta-galactosidase expression from a protein fusion by 5-fold during growth on acetate and by 2.5-fold during growth on glucose, it had no effect on beta-galactosidase expression from an operon fusion. In vitro ribosome binding experiments employing the primer extension inhibition (toeprint) assay demonstrated that the presence of the ICS in gnd mRNA reduces both the maximum extent and the rate of ternary complex formation. Moreover, the effects of deletions scanning the ICS on in vivo gene expression were highly correlated with the effects of the deletions on ribosome binding in vitro. In addition, the distal end of the ICS element was found to contribute more to ICS function than did the proximal portion, which contains the complement to the Shine-Dalgarno sequence. Finally, RNA structure mapping experiments indicated that the presence of the ICS in gnd mRNA reduces the access of the nucleotides of the ribosome binding site to the single-strand-specific chemical reagents dimethyl sulfate and kethoxal. Taken together, these data support the hypothesis that the role of the ICS in the growth rate-dependent regulation of gnd expression is to sequester the translation initiation region into a long-range mRNA secondary structure that blocks ribosome binding and thereby reduces the frequency of translation initiation.

In Escherichia coli K-12, transcription of zwf, the gene for glucose 6-phosphate dehydrogenase, is subject to growth rate-dependent regulation and is activated by SoxS in response to superoxide stress. To define genetically the site of SoxS activation, we undertook a detailed deletion analysis of the zwf promoter region. Using specifically targeted 5' and 3' deletions of zwf sequences, we localized the SoxS activation site to a 21-bp region upstream of the zwf promoter. This minimal "soxbox" was able to confer paraquat inducibility when placed upstream of a normally unresponsive gnd-lacZ protein fusion. In addition, we used these findings as the basis for resecting unnecessary sequences from the region upstream of the promoters of two other SoxS-regulated genes, sodA and nfo. Like the zwf soxbox, the regions required for SoxS activation of sodA and nfo appear to lie just upstream or overlap the -35 hexamers of the corresponding promoters. Importantly, the sequence boundaries established here by deletion analysis agree with the primary SoxS recognition sites of zwf, sodA, and nfo that we previously identified in vitro by gel mobility shift and DNase I protection assays with a purified MalE-SoxS fusion protein.

In Escherichia coli K-12 strain W3110, the amount of 6-phosphogluconate dehydrogenase relative to that of total protein, i.e., the specific enzyme activity, increases about threefold during growth in minimal media over the range of growth rates with acetate and glucose as sole carbon sources. Previous work with gnd-lac operon and protein fusion strains indicated that two steps in the expression of the gnd gene are subject to growth rate-dependent control, with at least one step being posttranscriptional. With both Northern (RNA) and slot blot analyses, we found that the amount of gnd mRNA relative to that of total RNA was 2.5-fold higher in cells growing in glucose minimal medium than in cells grown on acetate. Therefore, since the total mRNA fraction of total RNA is essentially independent of the growth rate, the amount of gnd mRNA relative to that of total mRNA increases about 2.5-fold with increasing growth rate. This indicates that most of the growth rate-dependent increase in 6-phosphogluconate dehydrogenase can be accounted for by the growth rate-dependent increase in gnd mRNA level. We measured the decay of gnd mRNA mass in the two growth conditions after blocking transcription initiation with rifampin and found that the stability of gnd mRNA does not change with growth rate. We also used a gnd-lacZ protein fusion to measure the functional mRNA half-life and found that it too is growth rate independent. Thus, the growth rate-dependent increase in the level of gnd mRNA is due to an increase in gnd transcription, and this increase is sufficient to account for the growth rate regulation of the 6-phosphogluconate dehydrogenase level. The dilemma posed by interpretations of the properties of gnd-lac fusion strains and by direct measurement of gnd mRNA level is discussed.

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A patient with scleroderma renal disease and pulmonary hypertension who had a successful pregnancy with the use of angiotensin converting enzyme inhibitors is presented. The routine use of these inhibitors during pregnancy is not recommended, however, owing to the reported potential risks to the fetus.

The nucleotide sequence of the entire Escherichia coli edd-eda region that encodes the enzymes of the Entner-Doudoroff pathway was determined. The edd structural gene begins 236 bases downstream of zwf. The eda structural gene begins 34 bases downstream of edd. The edd reading frame is 1,809 bases long and encodes the 602-amino-acid, 64,446-Da protein 6-phosphogluconate dehydratase. The deduced primary amino acid sequences of the E. coli and Zymomonas mobilis dehydratase enzymes are highly conserved. The eda reading frame is 642 bases long and encodes the 213-amino-acid, 22,283-Da protein 2-keto-3-deoxy-6-phosphogluconate aldolase. This enzyme had been previously purified and sequenced by others on the basis of its related enzyme activity, 2-keto-4-hydroxyglutarate aldolase. The data presented here provide proof that the two enzymes are identical. The primary amino acid sequences of the E. coli, Z. mobilis, and Pseudomonas putida aldolase enzymes are highly conserved. When E. coli is grown on gluconate, the edd and eda genes are cotranscribed. Four putative promoters within the edd-eda region were identified by transcript mapping and computer analysis. P1, located upstream of edd, appears to be the primary gluconate-responsive promoter of the edd-eda operon, responsible for induction of the Entner-Doudoroff pathway, as mediated by the gntR product. High basal expression of eda is explained by constitutive transcription from P2, P3, and/or P4 but not P1.

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We characterized three cis dominant mutations which elevate glucose 6-phosphate dehydrogenase level. Growth rate-dependent regulation and oxidative stress control of enzyme level were altered by the mutations. DNA sequencing and transcript mapping showed that the "up" mutations created new promoters whose hyperactive expression overrides the normal regulation of the native promoter.

Growth rate-dependent regulation of the level of Escherichia coli glucose 6-phosphate dehydrogenase, encoded by zwf, and 6-phosphogluconate dehydrogenase, encoded by gnd, is similar during steady-state growth and after nutritional upshifts. To determine whether the mechanism regulating zwf expression is like that of gnd, which involves a site of posttranscriptional control located within the structural gene, we prepared and analyzed a set of zwf-lacZ protein fusions in which the fusion joints are distributed across the glucose 6-phosphate dehydrogenase coding sequence. Expression of beta-galactosidase from the protein fusions was as growth rate dependent as that of glucose 6-phosphate dehydrogenase itself, indicating that regulation does not involve an internal regulatory region. The level of beta-galactosidase in zwf-lac operon fusion strains and the level of zwf mRNA from a wild-type strain increased with increasing growth rate, which suggests that growth rate control is exerted on the mRNA level. The half-life of the zwf mRNA mass was 3.0 min during growth on glucose and 3.4 min during growth on acetate. Thus, zwf transcription appears to be the target for growth rate control of the glucose 6-phosphate dehydrogenase level.

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In Escherichia coli K-12, expression of zwf, the gene for glucose 6-phosphate dehydrogenase, is coordinated with the cellular growth rate and induced by superoxide-generating agents. To initiate the study of the molecular mechanisms regulating its expression, the gene was cloned and its DNA sequence was determined. The 5' ends of zwf mRNA isolated from cells growing in glucose and acetate minimal media were mapped. The map was complex in that transcripts mapped to -45, -52, and -62, with respect to the beginning of the coding sequence. Three analytical methods were used to search the DNA sequence for putative promoters. Only one sequence for a promoter recognized by the sigma 70 form of RNA polymerase was found by all three search routines that could be aligned with a mapped transcript, indicating that the other transcripts arise by processing of the mRNA. A computer-assisted search did not reveal a thermodynamically stable long-range mRNA secondary structure that is capable of sequestering the translation initiation region, which suggests that growth-rate-dependent regulation of glucose 6-phosphate dehydrogenase level may not be carried out by a mechanism similar to the one for the gene (gnd) for 6-phosphogluconate dehydrogenase. The DNA segment between the -10 hexamer and the start point of transcription resembles the discriminator sequence of stable RNA genes, which has been implicated in stringent control and growth-rate-dependent regulation.

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A genetic approach was used for the cloning of the Synechococcus sp. strain PCC 7942 (Synechococcus strain R2) gnd gene which encodes 6-phosphogluconate dehydrogenase (6PGD). A restriction map of the gnd locus was prepared by Southern analysis using the Escherichia coli gene as a heterologous probe. The Synechococcus strain R2 gene was genetically tagged by restriction site-specific insertion of the nptII gene of Tn903 into a pUC19 plasmid library of Synechococcus strain R2 chromosomal DNA. Synechococcus strain R2 was transformed with this insertion mutation library, and isolates carrying the gnd::nptII gene were identified as mutants hypersensitive to incubation in the dark. The interrupted gene was cloned from one of the mutants. A plasmid carrying the gnd::nptII gene was reintroduced into Synechococcus strain R2, and kanamycin-resistant transformants were selected. Transformants arising by gene replacement were dark sensitive and missing 6PGD activity. Transformants arising by plasmid insertion were dark resistant and had 6PGD activity. The wild-type gene was then cloned from a transformant containing a plasmid insertion, making use of the restriction map derived from the interrupted gene. Synechococcus strain R2 6PGD was expressed in E. coli when the cloned gnd gene was transcribed from the lacZ promoter resident on the vector. The boundaries of the gene and the direction of transcription were determined from the phenotypes conferred by plasmids carrying deletions entering gnd from either end. The nucleotide sequence was determined. The deduced amino acid sequence of Synechococcus strain R2 6PGD has 56% homology to that of the E. coli K-12 enzyme.

In Escherichia coli, the level of 6-phosphogluconate dehydrogenase is directly proportional to the cellular growth rate during growth in minimal media. This contrasts with the report by Winkler et al. (M. E. Winkler, J. R. Roth, and P. E. Hartman, J. Bacteriol. 133:830-843, 1978) that the level of the enzyme in Salmonella typhimurium LT-2 strain SB3436 is invariant. The basis for the difference in the growth-rate-dependent regulation between the two genera was investigated. Expression of gnd, which encodes 6-phosphogluconate dehydrogenase, was growth rate uninducible in strain SB3436, as reported previously, but it was 1.4-fold growth rate inducible in other S. typhimurium LT-2 strains, e.g., SA535. Both the SB3436 and SA535 gnd genes were growth rate inducible in E. coli K-12. Moreover, the nucleotide sequences of the regulatory regions of the two S. typhimurium genes were identical. We concluded that a mutation unlinked to gnd is responsible for the altered growth rate inducibility of 6-phosphogluconate dehydrogenase in strain SB3436. Transductional analysis showed that the altered regulation is due to the presence of a mutation in hisT, the gene for the tRNA modification enzyme pseudouridine synthetase I. A complementation test showed that the regulatory defect conferred by the hisT mutation was recessive. In E. coli, hisT mutations reduced the extent of growth rate induction by the same factor as in S. typhimurium. The altered regulation conferred by hisT mutations was not simply due to their general effect of reducing the polypeptide chain elongation rate, because miaA mutants, which lack another tRNA modification and have a similarity reduced chain growth rate, had higher rather than lower 6-phosphogluconate dehydrogenase levels. Studies with genetic fusions suggested that hisT mutations lower the gnd mRNA level. The data also indicated that hisT is involved in translational control of gnd expression, but not the aspect mediated by the internal complementary sequence.

6-Phosphogluconate dehydrogenase (6PGD), encoded by gnd, is highly polymorphic among isolates of Escherichia coli form natural populations. As a means of characterizing the growth-rate-dependent regulation of the level of 6PGD, five gnd alleles, including the E. coli B/r allele, were crossed into E. coli K-12 with bacteriophage P1. In each of the isogenic strains, the level of 6PGD was two- to threefold higher in cells grown on glucose than in cells grown on acetate. The level of enzyme activity in the acetate-grown cells varied about sixfold within the set of isogenic strains. The physiological importance of these differences in enzyme level is discussed. The gnd gene was cloned from five E. coli strains and Salmonella typhimurium LT-2 and mapped with twelve restriction endonucleases. gnd was located and oriented on the chromosomal DNAs. The restriction maps of the genes were aligned at conserved restriction sites, and the relative divergence of the genes was estimated from restriction site polymorphisms. The E. coli gnd genes differed from the S. typhimurium gene by about 11%. Most of the E. coli genes differed from one another by less than 5%, but one allele differed from the others by about 10%. Only the gnd gene from E. coli K-12 had an IS5 element located nearby.

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The level of 6-phosphogluconate dehydrogenase is positively correlated with the cellular growth rate. To determine whether growth rate-dependent regulation of expression of gnd, which encodes this enzyme, is carried out by a transcriptional mechanism, the structural genes of the lactose operon were fused to and brought under the control of the gnd promoter through the use of phage Mu d1(Apr lac). Four independent gnd::Mu d1(Apr lac) operon fusion strains were isolated. After the Mu d1 prophage was replaced with lambda p1(209), Lac+ specialized transducing phages carrying the gnd-lac fusions were prepared. These phages were used to demonstrate that the lac genes were fused to the gnd promoter by crossing them with gnd promoter deletion mutants and with polar phage Mu cts-induced gnd mutants. A genetic map of the fusion joints was deduced. The level of beta-galactosidase in each fusion strain was the same in cells growing on acetate as in cells growing on glucose (with specific growth rate constants of 0.1 and 0.55 h-1, respectively) and was unaffected by the presence of a gnd+ gene in trans. Our results suggest that a post-transcriptional mechanism mediates growth rate-dependent regulation of gnd and that this regulation is not autogenous. Models for regulation are discussed with respect to these results and the physiology and DNA sequence of gnd.

Previous studies showed that the level of 6-phosphogluconate (6PG) dehydrogenase increases about fourfold with increasing growth rate when the growth rate is varied by varying the carbon source. When the growth rate was reduced by anaerobic growth or by using mutations to divert metabolism to less efficient pathways, the level of 6PG dehydrogenase was the same as in a wild-type strain growing aerobically on other carbon sources that yielded the same growth rate. Thus, expression of gnd, which encodes 6PG dehydrogenase, is regulated by the cellular growth rate and not by specific nutrients in the medium. Growth rate-dependent regulation was independent of temperature. After a nutritional shift-up, 6PG dehydrogenase and total protein did not attain the postshift rate of accumulation for 30 min, whereas RNA accumulation increased immediately. The kinetics of accumulation of 6PG dehydrogenase and RNA were coincident after a nutritional shift-down. Partial amino acid starvation of a strain that controls RNA synthesis stringently (rel+) had no effect on the differential rate of accumulation of the enzyme. The level of 6PG dehydrogenase in cells harboring a gnd+ multicopy plasmid was in approximate proportion to gene dosage and somewhat higher at faster growth rates. Growth rate control of chromosomal gnd was normal in strains carrying multiple copies of the promoter-proximal and promoter-distal portions of gnd. These results show that gnd is not part of the same regulatory network as components of the translational apparatus since gnd shows a delayed response to a nutritional shift-up, is not autoregulated, and is not subject to stringent control. Models to account for growth rate-dependent regulation of gnd are discussed.

Expression of the gene gnd of Escherichia coli, which encodes 6-phosphogluconate dehydrogenase, is regulated by growth rate. Using deoxyribonucleic acid from the specialized transducing phage lambda h80 dgnd his as the source of gnd, we cloned restriction fragments carrying the complete gene and portions of it on the plasmid vector pBR322. A hybrid plasmid carrying a 3.7-megadalton HindIII restriction fragment from the phage was prepared and found to be gnd+. Through restriction mapping of this fragment and subcloning segments of it, we prepared a gnd+ hybrid plasmid which carried only 1.85 megadaltons of E. coli deoxyribonucleic acid. A cleavage site for the restriction endonuclease PstI was located on the genetic map of gnd by cloning adjacent EcoRI-PstI restriction fragments and crossing the resulting hybrid plasmids with previously mapped gnd deletion and bacteriophage Mu insertion mutants. A maxicell experiment was used to determine the direction of transcription of gnd, to identify which EcoRI-PstI fragment contains the gnd promote, and to localize th beginning of the structural gene to a region about 850 +/- 150 base pairs from the PstI cleavage site. A fine-structure restriction map surrounding the PstI cleavage site was prepared for endonucleases KpnI, HincII, HaeIII, HpaII, and TaqI.

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Molecular and genetic studies have revealed that several illegitimate recombinational events are associated with integration of the specialized transducing bacteriophage lambda cI57 St68 h80 dgnd his into either the Escherichia coli chromosome or into a plasmid. Most Gnd+ His+ transductants did not carry the prophage at att phi-80, and 10% were not immune to lambda, i.e., "nonlysogenic." Integration of the phage was independent of the phage Int and Red gene products and of the host's general recombination (Rec) system. In further studies, bacterial strains were selected which carried the phage integrated into an R-factor, pSC50. Restriction endonuclease analysis of plasmid deoxyribonucleic acid (DNA) purified from these strains showed that formation of the hybrid plasmids resulted from recombination between a single region of pSC50 and one of several sites within the lambda-phi 80 portion of the phage. Furthermore the his-gnd region of the phage, present in the chromosome of one nonlysogenic transductant, was shown to be able to translocate to pSC50. Concomitant deletion of phage DNA sequences or pSC50 DNA was frequently observed in conjunction with these integration or translocation events. In supplemental studies, a 22- to 24-megadalton segment of the his-gnd region of the chromosome of a prototrophic recA E. coli strain was shown to translocate to pSC50. One terminus of this translocatable segment was near gnd and was the same as a terminus of the his-gnd segment of the phage which translocated from the chromosome of the nonlysogenic transductant. These data suggest that integration of lambda cI857 St 68 h80 dgnd his may be directed by a recombinationally active sequence on another replicon and that the resulting cointegrate structure is subject to the formation of deletions which extend from the recombinationally active sequence. Translocation of the his-gnd portion of the phage probably requires prior replicon fusion, whereas the his-gnd region of the normal E. coli chromosome may comprise a discrete, transposable element.

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A genetic map was prepared for gnd, the gene of Escherichia coli which encodes the metabolically regulated 6-phosphogluconate dehydrogenase. Direct selection methods were used for the isolation of mutants with deletions that define the respective ends of gnd. These selections depended on the availability of a defective lysogen in which gnd was present on a lambda h80 dgnd his prophage located at the att phi 80 region of the chromosome. Mutants with deletions entering gnd from the his-distal end were selected as Gnd- TonB- mutants. Mutants with his-proximal gnd deletions were selected as Gnd-, temperature-resistant mutants of a specially prepared stable lysogen. Gnd- mutants were also isolated after mutagenesis with bacteriophage Mu cts61, and genetic tests were used to determine which mutants carry a Mu cts61 prophage in gnd. The deletion mutations were mapped against each other and against the insertion mutations through the use of F' merodiploid strains. The insertion mutations mapped at seven distinct sites in gnd; three mapped under the deletions defining the his-proximal portion of the gene and three mapped with the his-distal deletions.

The levels of 6-phosphogluconate dehydrogenase and glucose 6-phosphate dehydrogenase are subject to metabolic regulation; they increased three- to fivefold with increasing growth rate.

A rapid, high-yield method for purification of 6-phosphogluconate dehydrogenase from Escherichia coli K-12 is described. Sonic extracts prepared from heat-induced cultures of strain RW184, doubly lysogenic for the specialized transducing bacteriophage lambdacI857St68h80dgndhis and bearing a deletion of the gene for glucose 6-phosphate dehydrogenase, contained levels of 6-phosphogluconate dehydrogenase 15- to 20-fold higher than cultures of wild-type cells. Affinity chromatography on blue dextran-Sepharose with batchwise elution with 1 mM nicotinamide adenine dinucleotide phosphate affected a further 10-fold purification. Enzyme prepared in this manner was homogeneous according to electrophoresis on sodium dodecyl sulfate-polyacrylamide gels and immunoelectrophoresis using antiserum directed against it. Fructose 1,6-diphosphate is an inhibitor of enzyme activity.

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The proliferative response of human peripheral blood lymphocytes to phytohemagglutinin, concanavalin A, and pokeweed mitogen were suppressed by thymosin. Greatest decreases were observed when cells were preincubated with thymosin for 18 h before a 3-d culture with mitogen in the presence of thymosin. However, significant suppression also occurred when lymphocytes were preincubated for 2 h and cultured with thymosin or preincubated for either 2 or 18 h and washed free of thymosin before culture. These effects were related to the concentration of thymosin and time of exposure to thymosin but not merely to a delay in the response to mitogen or to toxicity. The suppression of mitogen-induced proliferation by thymosin appeared to result from effects of thymosin on a suppressor cell because lymphocytes incubated with thymosin did not acquire increased responsiveness to mitogens as did cells incubated for 18 h in its absence and because mixing thymosin-pretreated lymphocytes with cells not preincubated with thymosin resulted in decreased responsiveness to photohemagglutinin.