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:C0038187 (starvation)
24,951 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Depletion of nutrients, including phosphate, is a stress often encountered by a bacterial cell, and results in slowed growth, marking the cessation of exponential growth. Genes that are transcriptionally activated during phosphate starvation have been used to examine the signal-transduction mechanisms governing the Pho regulon in Bacillus subtilis. Alkaline phosphatase, the traditional reporter protein for Pho regulation in prokaryotes, is encoded by a multigene family in B. subtilis. Characterization of the alkaline phosphatase family was a breakthrough in the study of regulation of the Pho regulon, especially the discovery of promoter elements exclusively responsive to phosphate-starvation regulation. Current data suggest that at least three two-component signal-transduction systems interact, forming a regulatory network that controls the phosphate-deficiency response in B. subtilis. The interconnected pathways involve the PhoP-PhoR system, whose primary role is to mediate the phosphate-deficiency response; the SpoO phosphorelay required for the initiation of sporulation; and a newly discovered signal-transduction system, ResD-ResE, which also has a role in respiratory regulation during late growth. Parallel pathways positively regulate the Pho response via PhoP-PhoR. One pathway includes the ResD-ResE system, while the other involves a transition-state regulator, AbrB. The SpoO system represses the Pho response by negatively regulating both pathways. This review will discuss how the characterization of the APase multigene family made possible studies which show that the Pho regulon in B. subtilis is regulated by the integrated action of the Res, Pho and Spo signal-transduction systems.
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PMID:The signal-transduction network for Pho regulation in Bacillus subtilis. 883 Feb 74

Escherichia coli grown in high or low phosphate medium was inoculated into a lake water starvation medium. The viable count decreased at 37 degrees C but not at the lower temperatures over 70 d. Alkaline phosphatase was monitored using a colorimetric assay with pNPP as the substrate. Derepression of the enzyme occurred in cultures starved for > 30 d in the lake water and within 5 d in lake water microcosms supplemented with carbon and nitrogen sources where there was rarely an increase in viable count. Chloramphenicol prevented the synthesis of alkaline phosphatase suggesting that, even under starvation conditions, de novo synthesis of the enzyme occurs.
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PMID:Alkaline phosphatase activity of Escherichia coli starved in sterile lake water microcosms. 885 72

Several gene products, including three two-component systems, make up a signal transduction network that controls the phosphate starvation response in Bacillus subtilis. Epistasis experiments indicate that PhoP, a response regulator, is furthest downstream of the known regulators in the signaling pathway that regulates Pho regulon genes. We report the overexpression, purification, and use of PhoP in investigating its role in Pho regulon gene activation. PhoP was a substrate for both the kinase and phosphatase activities of its cognate sensor kinase, PhoR. It was not phosphorylated by acetyl phosphate. Purified phosphorylated PhoP (PhoPP) had a half-life of approximately 2.5 h, which was reduced to about 15 min by addition of the same molar amount of *PhoR (the cytoplasmic region of PhoR). ATP significantly increased phosphatase activity of *PhoR on PhoPP. In gel filtration and cross-linking studies, both PhoP and PhoPP were shown to be dimers. The dimerization domain was located within the 135 amino acids at the N terminus of PhoP. Phosphorylated or unphosphorylated PhoP bound to one of the alkaline phosphatase gene promoters, the phoB promoter. Furthermore, PhoP bound exclusively to the -18 to -73 region (relative to the transcriptional start site +1) of the phosphate starvation-inducible promoter (Pv) but not to the adjacent developmentally regulated promoter (Ps). These data corroborate the genetic data for phoB regulation and suggest that activation of phoB is via direct interaction between PhoP and the phoB promoter. Studies of the phosphorylation, oligomerization, and DNA binding activity of the PhoP protein demonstrate that its N-terminal phosphorylation and dimerization domain and its C-terminal DNA binding domain function independently of one another, distinguishing PhoP from other response regulators, such as PhoB (Escherichia coli) and NtrC.
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PMID:Bacillus subtilis PhoP binds to the phoB tandem promoter exclusively within the phosphate starvation-inducible promoter. 933 76

Transcriptional induction of the uspA gene of Escherichia coli occurs whenever conditions cause growth arrest and cells deficient in UspA survive poorly in stationary phase. We demonstrate that the product of uspA is a serine and threonine phosphoprotein. In vivo, three isoforms of UspA were detected, two of which were phosphorylated as determined by alkaline phosphatase treatment; in vitro, phosphorylation with [gamma-32P]ATP yielded two radioactive UspA isoforms. The phosphorylated isoforms were barely visible in growing cells but one increased during starvation conditions causing growth arrest. This phosphorylation is dependent on the o591 gene, which encodes an autophosphorylating tyrosine phosphoprotein and which is involved in the synthesis or modification of six other proteins. In vitro, UspA undergoes a rapid and dynamic autophosphorylation, as shown by chase experiments with GTP or ATP as phosphate donors.
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PMID:The universal stress protein, UspA, of Escherichia coli is phosphorylated in response to stasis. 940 42

In the yeast Saccharomyces cerevisiae, autophagy, a bulk protein degradation in the vacuole, is induced in response to nutrient starvation. In a screen for mutations that result in induction of autophagy even in the presence of nutrients, we have isolated four mutants representing two csc complementation groups. These mutants induce autophagy of which activity is represented by activation of truncated alkaline phosphatase that is designed to be expressed in the cytosol. CSC1 was cloned by complementation of loss of viability phenotype of csc1-1 mutant and shown to be identical to END13/VPS4/GRD13. Though csc1-1 mutation is recessive, cells of delta csc1 do not induce autophagy in rich media, suggesting that csc1-1 allele is not a complete loss-of-function. Csc1p is a member of novel ATPase family named AAA protein including Sec18p/NSF, Cdc48p/p97, and Pas8p. Mutation site in csc1-1 is found in the SRH region that is highly conserved among AAA proteins. Cells of csc1-1 show sorting defect of CPY and the appearance of the class E compartment. These mutant phenotypes suggest the role of the protein that is involved in the traffic among the Golgi, endosome, and the vacuole in autophagy.
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PMID:Mutational analysis of Csc1/Vps4p: involvement of endosome in regulation of autophagy in yeast. 943 54

A mathematical model of the Escherichia coli Pho regulon was developed to study the induction of the phoA gene by starvation for inorganic phosphate. The model includes phosphate transport, detection of the phosphate concentration at the cell surface, and the signal transduction cascade ultimately leading to the induction of various Pho-controlled genes. Four parameters were manipulated to match the dynamic response of a culture growing with phosphate as the growth-limiting substrate to available experimental data for alkaline phosphatase production and internal phosphate concentration. Steady-state analysis demonstrates that the cascade design of this genetic control system gives rise to a harp transition between the uninduced and induced state for a small change in the external phosphate concentration. Parameter sensitivity indicates that the dissociation constant of the repression complex (which holds PhoR in the inactive form when phosphate is in excess), the rate constants for PhoB and PhoR phosphorylation, and the rate constant for induced transcription of Pho genes have the most influence over the expression of Pho-controlled genes. Changes in the repression complex dissociation constant and the PhoB/PhoR phosphorylation rates alter the sensitivity of the phosphate-starvation response to external phosphate concentration, whereas changes in the transcription rate constant affect the gain of the system. The model also predicts that additional Pho promoter (i.e., for the production of a heterologous protein from the phoA promoter on a plasmid) titrate activator protein PhoB A, such that a lower phosphate concentration is required to initiate expression from a high-copy plasmid than from a single-copy plasmid or the chromosome.
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PMID:A dynamic model of the Escherichia coli phosphate-starvation response. 947 89

The expression of alkaline phosphatase in response to phosphate starvation was shown to be spatially and temporally heterogeneous in bacterial biofilms and colonies. A commercial alkaline phosphatase substrate that generates a fluorescent, insoluble product was used in conjunction with frozen sectioning techniques to visualize spatial patterns of enzyme expression in both Klebsiella pneumoniae and Pseudomonas aeruginosa biofilms. Some of the expression patterns observed revealed alkaline phosphatase activity at the boundary of the biofilm opposite the place where the staining substrate was delivered, indicating that the enzyme substrate penetrated the biofilm fully. Alkaline phosphatase accumulated linearly with time in K. pneumoniae colonies transferred from high-phosphate medium to low-phosphate medium up to specific activities of 50 mumol per min per mg of protein after 24 h. In K. pneumoniae biofilms and colonies, alkaline phosphatase was initially expressed in the region of the biofilm immediately adjacent to the carbon and energy source (glucose). In time, the region of alkaline phosphatase expression expanded inward until it spanned most, but not all, of the biofilm or colony depth. In contrast, expression of alkaline phosphatase in P. aeruginosa biofilms occurred in a thin, sharply delineated band at the biofilm-bulk fluid interface. In this case, the band of activity never occupied more than approximately one-sixth of the biofilm. These results are consistent with the working hypothesis that alkaline phosphatase expression patterns are primarily controlled by the local availability of either the carbon and energy source or the electron acceptor.
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PMID:Spatial patterns of alkaline phosphatase expression within bacterial colonies and biofilms in response to phosphate starvation. 954 88

Iron starvation of Bordetella avium induced expression of five outer membrane proteins with apparent molecular masses of 95, 92, 91.5, 84, and 51 kDa. Iron-responsive outer membrane proteins (FeRPs) of similar sizes were detected in six of six strains of B. avium, suggesting that the five FeRPs are common constituents of the outer membrane of most, if not all, strains of B. avium. Iron-regulated genes of B. avium were targeted for mutagenesis with the transposon TnphoA. Two mutants with iron-responsive alkaline phosphatase activities were isolated from the transposon library. The transposon insertion did not alter the iron-regulated expression of the five FeRPs in mutant Pho-6. The mutant Pho-20 exhibited a loss in expression of the 95-kDa FeRP and the 84-kDa FeRP. Both Pho-6 and Pho-20 were able to use free iron as a nutrient source. However, Pho-20 was severely compromised in its ability to use iron present in turkey serum. The data indicated that the mutation in Pho-20 affected expression of one or more components of an uptake machinery that is involved in acquisition of iron from organic ferricomplexes.
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PMID:Iron starvation of Bordetella avium stimulates expression of five outer membrane proteins and regulates a gene involved in acquiring iron from serum. 967 38

Osteoblast cells, recruited from mesenchymal precursors, initiate the final phase of bone remodeling by secreting the protein components of the bone matrix. Upon completion of remodeling, some of these osteoblasts may further differentiate, giving rise to matrix-embedded osteocytes and bone lining cells. The fate of the remaining osteoblasts is unknown, although by analogy with other cell systems, apoptotic cell death may be involved. We induced and characterized the apoptotic process in ROS 17/2.8 osteosarcoma cells by growing and maintaining confluent cultures in low serum medium. At confluence, but prior to apoptosis, the levels of collagen type I, alkaline phosphatase, and osteocalcin mRNAs declined abruptly. Expression of two housekeeping genes (ribosomal protein RPS6 and GAPDH) remained unchanged. Some 72 hours later cells began to show morphological and biochemical features of apoptosis, namely, chromatin condensation, membrane budding, and internucleosomal degradation of genomic DNA. We conclude that serum starvation-induced apoptosis of ROS 17/2.8 cells can serve as a model for investigating the mechanisms of osteoblastic apoptosis.
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PMID:Loss of the differentiated phenotype precedes apoptosis of ROS 17/2.8 osteoblast-like cells. 970 24

PhoP-PhoR, one of three two-component systems known to be required to regulate the pho regulon in Bacillus subtilis, directly regulates the alkaline phosphatase genes that are used as pho reporters. Biochemical studies showed that B. subtilis PhoR, purified from Escherichia coli, was autophosphorylated in vitro in the presence of ATP. Phosphorylated PhoR showed stability under basic conditions but not acidic conditions, indicating that the phosphorylation probably occurs on a conserved histidine residue. Phospho-PhoR phosphorylated its cognate response regulator, PhoP in vitro. B. subtilis phoR was placed in the Bacillus chromosome under the control of the Pspac promoter, which is IPTG inducible. The wild-type phoR, under either native promoter or Pspac promoter with IPTG induction, resulted in a similar level of alkaline phosphatase production. Under high phosphate conditions, strains containing wild-type phoR, or phoR mutant gene products that lacked either the periplasmic domain, or both N-terminal transmembrane PhoR mutant gene products that lacked either the periplasmic domain, or both N-terminal transmembrane PhoR sequences or various extended N-terminal sequences, showed no significant APase production. Under phosphate starvation conditions, in the presence of IPTG, all strains containing mutated phoR genes showed alkaline phosphatase induction patterns similar to that of the wild-type strain, although the fully induced level was lower in the mutants. The decrease in total alkaline phosphatase production in these mutant strains can be compensated completely or partially by increasing the copy number of the mutant phoR gene. These in vivo results suggest that the C-terminal kinase domain of PhoR is sufficient for the induction of alkaline phosphatase expression under phosphate-limited conditions, and that the regulation for repression of APase under phosphate-replete conditions remains intact.
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PMID:The cytoplasmic kinase domain of PhoR is sufficient for the low phosphate-inducible expression of pho regulon genes in Bacillus subtilis. 998 23


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