Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0519030 (Klebsiella)
21,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Synthetic nitrate saccharose (NS) nutrient media are offered to be used for Klebsiella pneumoniae. NS medium of the following composition is suggested for studies of substrates moderately contaminated with microorganisms: 20 g agar-agar, 1 g potassium nitrate, 2 g disubstituted potassium phosphate, monopotassium phosphate, 20 g saccharose, and 1 1 distilled water. NSK medium is offered for the isolation of Klebsiella from material abundantly contaminated with various bacteria; this medium includes, in addition to the said recipe, 10 ng/1 carbenicillin. Experiments and analysis of material from the patients demonstrated high sensitivity and inhibitory properties of NS media.
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PMID:[A synthetic nutrient medium for isolating Klebsiella pneumoniae]. 762 Jul 83

Enterobacteria use nitrate and nitrite both as electron acceptors and as sources of nitrogen for biosynthesis. Nitrate is reduced through nitrite to ammonium in both cases. The enzymes and structural genes for nitrate/nitrite respiration and assimilation are distinct, and are subject to different patterns of regulation. Respiratory enzyme synthesis is indifferent to the availability of ammonium, and is induced by anaerobiosis via the FNR protein. Respiratory enzyme synthesis is further induced by nitrate or nitrite via the NARL and NARP proteins, which are response regulators of two-component regulatory systems. The cognate sensor proteins NARX and NARQ monitor the availability of nitrate and nitrite, and control the activity of the NARL and NARP DNA-binding proteins accordingly. Additionally, nitrate represses the synthesis of respiratory nitrite reductase, and this control is mediated by the NARL protein. Assimilatory enzyme synthesis is indifferent to the availability of oxygen, and is induced by ammonium limitation via the NTRC protein. Assimilatory enzyme synthesis is further induced by nitrate or nitrite via the NASR protein, which may act as a transcription antiterminator. Even though the respiratory and assimilatory enzyme systems are genetically distinct and subject to different forms of regulation, the structural and regulatory genes are closely linked on the Klebsiella pneumoniae chromosome.
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PMID:Regulation of nitrate and nitrite reductase synthesis in enterobacteria. 774 39

Klebsiella pneumoniae can use nitrate and nitrite as sole nitrogen sources through the nitrate assimilatory pathway. The structural genes for assimilatory nitrate and nitrite reductases together with genes necessary for nitrate transport form an operon, nasFEDCBA. Expression of the nasF operon is regulated both by general nitrogen control and also by nitrate or nitrite induction. We have identified a gene, nasR, that is necessary for nitrate and nitrite induction. The nasR gene, located immediately upstream of the nasFEDCBA operon, encodes a 44-kDa protein. The NasR protein shares carboxyl-terminal sequence similarity with the AmiR protein of Pseudomonas aeruginosa, the positive regulator of amiE (aliphatic amidase) gene expression. In addition, we present evidence that the nasF operon is not autogenously regulated.
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PMID:Identification and structure of the nasR gene encoding a nitrate- and nitrite-responsive positive regulator of nasFEDCBA (nitrate assimilation) operon expression in Klebsiella pneumoniae M5al. 805 Oct 20

Klebsiella pneumoniae can use nitrate and nitrite as sole nitrogen sources through the nitrate assimilation pathway. We previously identified structural genes for assimilatory nitrate and nitrite reductases, nasA and nasB, respectively. We report here our further identification of four genes, nasFEDC, upstream of the nasBA genes. The nasFEDCBA genes probably form an operon. Mutational and complementation analyses indicated that both the nasC and nasA genes are required for nitrate assimilation. The predicted NASC protein is homologous to a variety of NADH-dependent oxidoreductases. Thus, the NASC protein probably mediates electron transfer from NADH to the NASA protein, which contains the active site for nitrate reduction. The deduced NASF, NASE, and NASD proteins are homologous to the NRTA, NRTB, and NRTD proteins, respectively, that are involved in nitrate uptake in Synechococcus sp. (T. Omata, X. Andriesse, and A. Hirano, Mol. Gen. Genet. 236:193-202, 1993). Mutational and complementation studies indicated that the nasD gene is required for nitrate but not nitrite assimilation. By analogy with the Synechococcus nrt genes, we propose that the nasFED genes are involved in nitrate transport in K. pneumoniae.
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PMID:The nasFEDCBA operon for nitrate and nitrite assimilation in Klebsiella pneumoniae M5al. 816 3

The metabolism of gluconate by Klebsiella pneumoniae NCTC 418 was studied in continuous culture. Under all gluconate-excess conditions at low culture pH values (pH 4.5-5.5) the majority (70-90%) of the gluconate metabolized was converted to 2-oxogluconate via gluconate dehydrogenase (GADH), although specific 2-oxogluconate production rates under potassium-limited conditions were significantly lower than under other gluconate-excess conditions. At high culture pH values, metabolism shifted towards production of acetate. Levels of GADH were highest at low culture pH values and synthesis was stimulated by the presence of (high concentrations of) gluconate. An increase in activity of the tricarboxylic acid cycle was accompanied by a decrease in GADH activity in vivo and in vitro, suggesting that the GADH serves a role as an alternative energy-generating system. Anaerobic 2-oxogluconate production was found to be possible in the presence of nitrate as electron acceptor. Levels of gluconate kinase were highest when K. pneumoniae was grown under gluconate-limited conditions. Under carbon-excess conditions, levels of this enzyme correlated with the intracellular catabolic flux.
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PMID:Gluconate metabolism of Klebsiella pneumoniae NCTC 418 grown in chemostat culture. 838 64

Klebsiella pneumoniae can use nitrate and nitrite as sole nitrogen sources during aerobic growth. Assimilatory nitrate and nitrite reductases convert nitrate through nitrite to ammonium. We report here the molecular cloning of the nasA and nasB genes, which encode assimilatory nitrate and nitrite reductase, respectively. These genes are tightly linked and probably form a nasBA operon. In vivo protein expression and DNA sequence analysis revealed that the nasA and nasB genes encode 92- and 104-kDa proteins, respectively. The NASA polypeptide is homologous to other prokaryotic molybdoenzymes, and the NASB polypeptide is homologous to eukaryotic and prokaryotic NADH-nitrite reductases. The narL gene product positively regulates expression of the structural genes for respiratory nitrate reductase, narGHJI. Surprisingly, we found that the nasBA operon is tightly linked to the narL-narGHJI region in K. pneumoniae, even though the nitrate assimilatory and respiratory enzymes serve different physiological functions.
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PMID:Structures of genes nasA and nasB, encoding assimilatory nitrate and nitrite reductases in Klebsiella pneumoniae M5al. 846 96

Klebsiella pneumoniae can use nitrate and nitrite as sole nitrogen sources during aerobic growth. Nitrate is converted through nitrite to ammonium by assimilatory nitrate and nitrite reductase, respectively. Enzymes required for nitrate assimilation are encoded by the nasFEDCBA operon of K. pneumoniae; nasF operon expression is subject to both general nitrogen control and pathway-specific nitrate/nitrite induction, mediated by the NtrC and NasR proteins, respectively. Sequence inspection revealed a presumptive sigmaN (sigma54)-dependent promoter as well as two presumptive upstream NtrC protein binding sites. Site-specific mutational and primer extension analyses confirmed the identity of the sigmaN-dependent promoter. Deletions removing the apparent NtrC protein binding sites greatly reduced NtrC-dependent regulation, indicating that these sites are involved in general nitrogen control. However, deletions removing most of the sequence upstream of the promoter had little effect on nitrate/nitrite regulation, suggesting that the nasF leader region is involved in nitrate/nitrite regulation. The 119 nucleotide long transcribed leader region contains an apparent factor-independent transcription terminator. Promoter replacement experiments demonstrated that the leader region is involved in nitrate/nitrite regulation of nasF operon expression. Deletions removing the transcription terminator structure resulted in a nitrate-blind constitutive phenotype, indicating that the transcription terminator structure serves a negative function. Other deletions, removing proximal portions of the leader region, resulted in an uninducible phenotype, indicating that this region serves a positive function. These results indicate that nitrate/nitrite regulation of nasF operon expression is determined by a transcription attenuation mechanism. We hypothesize that in the absence of nitrate or nitrite, the terminator structure abrogates transcription readthrough into the nasF operon. In the presence of nitrate or nitrite, the NasR protein mediates transcription antitermination, thereby allowing transcription to proceed into the nasF operon.
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PMID:Nitrate and nitrite-mediated transcription antitermination control of nasF (nitrate assimilation) operon expression in Klebsiella pheumoniae M5al. 860 28

An operon including two new genes (nasS and nasT) has been defined, cloned and sequenced. The deduced NASS protein is homologous to NRTA from Synechococcus sp. and to NASF from Klebsiella pneumoniae, two proteins involved in nitrate uptake. The predicted NAST polypeptide is homologous to the regulator proteins of the two-component regulatory systems. NASS plays a negative regulatory role in the synthesis of the nitrate and nitrite reductase. NAST is required for the expression of the nitrite-nitrate reductase operon (nasAB). Expression of the nasST operon is not under the control of the NTR system and is not regulated by the nitrogen source. A Phi(nasA-lacZ) fusion has been used to analyse expression of the nasAB operon in three different genetic backgrounds with altered nitrate reductase activity. Beta-galactosidase activity in two of them was independent of nitrate but in a mutant unable to reduce nitrate, nas-4, it was normally induced by nitrate.
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PMID:nasST, two genes involved in the induction of the assimilatory nitrite-nitrate reductase operon (nasAB) of Azotobacter vinelandii. 874 40

Antitermination of transcription mediated by proteins interacting with mRNA sequences is described for nine operons/regulons. Eight of the systems are catabolic, while the ninth, the Klebsiella pneumoniae nas regulon, is involved in the assimilation of nitrate and nitrite. Six of the catabolic operons/regulons are found in Bacillus subtilis, one is found in Escherichia coli, and one in Pseudomonas aeruginosa. The antitermination system of five of the operons/regulons (E. coli blg, and sacPA, sacB, bgl, and lic from B. subtilis) are assigned to the bgl-sac family on the basis of extensive similarities with regard to antiterminator proteins and the sequences of the antiterminators. Other members of the bgl-sac family are the arb operon of Erwinia chrysanthemi and a presumed bgl operon of Lactococcus lactis. The antitermination systems of the other four operons/regulons (B. subtilis glp, B. subtilis hut, P. aeruginosa ami, and K. pneumoniae nas) seem to be unrelated both to the bgl-sac family and to each other. The antiterminator protein of the B. subtilis glp regulon has been found not only to cause antitermination but also to stabilize the resultant mRNA and to mediate glucose repression. If other antiterminator proteins, and antitermination factors, also prove to have additional functions, it will broaden the impact of antitermination as a means of controlling gene expression.
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PMID:Antitermination of transcription of catabolic operons. 904 76

Gastrointestinal degradation of urea might, according to a new hypothesis, have consequences for the regulation of acid-base balance as well as control of breathing during infancy. Thirteen infants were investigated from their first few days of life to the age of 6 months by collecting faecal samples at the age of 3 days, 2, 3, and 6 months, respectively. The faecal microflora was determined after aerobic and anaerobic cultivation and the faecal urease activity was assessed after 36 h aerobic and anaerobic preincubation. The infants were mostly breast fed and had a faecal microflora containing anaerobic bacteria such as Bifidobacteria, Bacterioides and Lactobacilli but also aerobics such as Escherichia coli, Enterococci and sometimes Klebsiella. The faecal pH increased from approximately 5.30 to 5.90, the pH after anaerobic preincubation being on an average 0.2 pH units lower than after aerobic preincubation. Simultaneously the nitric oxide production of the faecal specimens increased approximately 10-fold and the urease activity decreased by a factor of 3 to 5. We also found an inhibitory action of nitrate, nitrite (in mumolar concentration) and nitric oxide (in parts per million concentration) on the faecal urease activity. Hence, the present results warrant further research in order to determine more precisely the action of different concentrations of various nitrous oxides on individual bacterial species, and furthermore, to assay the faecal urease activity in victims of sudden infant death syndrome as well as in infants dead due to other causes.
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PMID:Faecal microflora and urease activity during the first six months of infancy. 905 88


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