UMLS:C0038187 - FACTA Search

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

The influence of the anti-fungal agent phosphonate (Phi) on the response of oilseed rape (Brassica napus L. cv. Jet Neuf) cell suspensions to inorganic phosphate (Pi) starvation was examined. Subculture of the cells for 7 d in the absence of Pi increased acid phosphate (APase; EC 3.1.3.2) and pyrophosphate (PPi)-dependent phosphofructokinase (PFP; EC 2.7.1.90) activities by 4.5- and 2.8-fold, respectively, and led to a 19-fold increase in Vmax and a 14-fold decrease in Km (Pi) and Pi uptake. Addition of 2 mM Pi to the nutrient media caused dramatic reductions in the growth and Pi content of the Pi-starved, but not Pi-sufficient cells, and largely abolished the Pi-starvation-dependent induction of PFP, APase, and the high-affinity plasmalemma Pi translocator. Immunoblotting indicated the cells contain three APase isoforms that are synthesized de novo following Pi stress, and that Pi treatment represses this process. Phosphonate treatment of Pi-starved cells significantly altered the relative extent of in-vivo 32P-labelling of polypeptides having M(rs) of 66, 55, 45 and 40 kDa. However, Phi had no effect on the total adenylate pool of Pi-starved cells which was about 32% lower than that of Pi-sufficient cells by day 7. Soluble protein levels, and activities of pyruvate kinase (EC 2.7.1.40) and ATP-dependent phosphofructokinase (EC 2.7.1.11) were unaffected by Pi starvation and/or Phi treatment. The effects of Phi on the growth, and APase and PFP activities of Pi-starved B. napus seedlings were similar to those observed in the suspension cells. The results re consistent with the hypothesis that a primary site of Phi action in higher plants is at the level of the signal transduction chain by which plants perceive and respond to Pi stress at the molecular level.
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PMID:Disruption of the phosphate-starvation response of oilseed rape suspension cells by the fungicide phosphonate. 929 91

Most vascular plants can acquire phosphate from the environment either directly, via the roots, or indirectly, via a fungal symbiont that invades the cortical cells of the root. Here we have identified two cDNA clones (MtPT1 and MtPT2) encoding phosphate transporters from a mycorrhizal root cDNA library (Medicago truncatula/Glomus versiforme). The cDNAs represent M. truncatula genes and the encoded proteins share identity with high-affinity phosphate transporters from Arabidopsis, potato, yeast, Neurospora crassa, and an arbuscular mycorrhizal (AM) fungus, G. versiforme. The function of the protein encoded by MtPT1 was confirmed by complementation of a yeast phosphate transport mutant (pho84). The K(m) of the MtPT1 transporter in this system is 192 microM. MtPT1 and MtPT2 transcripts are present in roots and transcript levels increase in response to phosphate starvation. MtPT transcripts were not detected in leaves. Following colonization of the roots by the AM fungus G. versiforme, both MtPT1 and MtPT2 transcript levels decrease significantly. Down-regulation of phosphate starvation-inducible genes in mycorrhizal roots appears to be a common occurrence and a homologue of a phosphate starvation-inducible purple acid phosphatase is also down-regulated in the mycorrhizal roots. The functional characteristics and expression patterns of the MtPT transporters are consistent with a role in the acquisition of phosphate from the environment but suggest that they may not be involved in phosphate uptake at the symbiotic interface in mycorrhizal roots.
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PMID:Cloning and characterization of two phosphate transporters from Medicago truncatula roots: regulation in response to phosphate and to colonization by arbuscular mycorrhizal (AM) fungi. 942 84

Plant response to phosphorus starvation includes the increased production and secretion of acid phosphatase. We have isolated a mutant of Arabidopsis thaliana (L.) Heynh., phosphatase-underproducer 1 (pup1), that has reduced histochemical staining for acid phosphatase activity in roots of plants grown under phosphorus-starvation conditions. Although pup1 is defective in the production of one inducible acid phosphatase isoform, the most abundant inducible isoform is present. The pup1 mutants are able to respond to phosphorus-deficient conditions by an increase in overall levels of acid phosphatase activity, accumulation of anthocyanins, an increase of the root-to-shoot ratio, and changes in the partitioning of phosphorus between roots and shoots. The gross morphology of the mutants appears normal, except that a small difference in the root to shoot ratio was observed in plants grown under nonstressed conditions. The pup1 gene is incompletely dominant and it is located between 40.2 (+/- 6.2) and 44.9 (+/- 9.9) cM on chromosome 2. This mutant will be useful for determining the role of this acid phosphatase isoform in plant response to phosphorus starvation.
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PMID:An Arabidopsis mutant missing one acid phosphatase isoform. 982 87

It is now well established that progression through the eukaryotic cell cycle is controlled by oscillations in the activity of cyclin- dependent kinases (CDKs). In many cases, however, the physiological substrate(s) of CDKs are unknown. The Saccharomyces cerevisiae PHO5 gene encodes a secreted acid phosphatase which is induced in response to phosphate starvation. The PHO5 gene is activated by the Pho4p transcription factor, which itself is negatively regulated through phosphorylation by the products of PHO80 and PHO85. Pho80p and Pho85p are homologous to cyclins and CDKs, respectively, and the Pho80p/Pho85p heterodimer satisfies the biochemical definition of a cyclin/CDK. In the present study, several reporter genes were expressed in S. cerevisiae from promoters which are activated by the transcription factor Pho4p, thereby generating yeast strains which exhibit quantifiable phenotypes that reflect the activity of a specific cyclin/CDK. Positive genetic selections for inhibition of cyclin/CDK function were characterized using the E. coli neo and yeast LEU2 genes. Chromosomal disruptions of the yeast PHO80 and PHO85 genes were constructed and conditions for complementation by plasmid-borne genes were defined. Complementation is achieved at very low levels of expression of both Pho80p and Pho85p. High-level expression of Pho80p results in aberrant PHO5 promoter regulation, characterized by failure to derepress in low-phosphate medium. Genes encoding hybrid CDKs in which regions of Pho85p were replaced with the homologous region of human Cdk2 were constructed, and tested for function in S. cerevisiae by complementation of the pho85 chromosomal gene disruption. Hybrid proteins in which more than two-thirds of the molecule were derived from human Cdk2 retained Pho85p function with respect to high-phosphate repression of the PHO5 promoter. The hybrid proteins require the PHO80 gene product for this function. A hybrid human-yeast CDK in which a single amino acid is deleted, within a nonapeptide sequence which is perfectly conserved in Pho85p and human Cdk2, retains full function. These results demonstrate that, within the context of the conserved structure of CDKs, considerable primary sequence variability can be introduced without loss of the cyclin-dependent function of the CDK.
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PMID:Function of hybrid human-yeast cyclin-dependent kinases in Saccharomyces cerevisiae. 982 36

Low phosphorous availability, a common condition of many soils, is known to stimulate phosphatase activity in plants; however, the molecular details of this response remain mostly unknown. We purified and sequenced the N-terminal region of a phosphate starvation induced acid phosphatase (AtACP5) from Arabidopsis thaliana, and cloned its cDNA and the corresponding genomic DNA. The nucleotide sequence of the cDNA predicted that AtACP5 is synthesised as a 338 amino acid-long precursor with a signal peptide. AtACP5 was found to be related to known purple acid phosphatases, especially to mammal type 5 acid phosphatases. Other similarities with purple acid phosphatases, which contain a dinuclear metal centre, include the conservation of all residues involved in metal ligand binding and resistance to tartrate inhibition. In addition, AtACP5, like other type 5 acid phosphatases, displayed peroxidation activity. Northern hybridisation experiments, as well as in situ glucuronidase (GUS) activity assays on transgenic plants harbouring AtACP5:GUS translational fusions, showed that AtACP5 is not only responsive to phosphate starvation but also to ABA and salt stress. It is also expressed in senescent leaves and during oxidative stress induced by H2O2, but not by paraquat or salicylic acid. Given its bifunctionality, as it displays both phosphatase and peroxidation activity, we propose that AtACP5 could be involved in phosphate mobilisation and in the metabolism of reactive oxygen species in stressed or senescent parts of the plant.
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PMID:A type 5 acid phosphatase gene from Arabidopsis thaliana is induced by phosphate starvation and by some other types of phosphate mobilising/oxidative stress conditions. 1050 79

In the budding yeast Saccharomyces cerevisiae, PHO84 and PHO86 are among the genes that are most highly induced in response to phosphate starvation. They are essential for growth when phosphate is limiting, and they function in the high-affinity phosphate uptake system. PHO84 encodes a high-affinity phosphate transporter, and mutations in PHO86 cause many of the same phenotypes as mutations in PHO84, including a phosphate uptake defect and constitutive expression of the secreted acid phosphatase, Pho5p. Here, we show that the subcellular localization of Pho84p is regulated in response to extracellular phosphate levels; it is localized to the plasma membrane in low-phosphate medium but quickly endocytosed and transported to the vacuole upon addition of phosphate to the medium. Moreover, Pho84p is localized to the endoplasmic reticulum (ER) and fails to be targeted to the plasma membrane in the absence of Pho86p. Utilizing an in vitro vesicle budding assay, we demonstrate that Pho86p is required for packaging of Pho84p into COPII vesicles. Pho86p is an ER resident protein, which itself is not transported out of the ER. Interestingly, the requirement of Pho86p for ER exit is specific to Pho84p, because other members of the hexose transporter family to which Pho84 belongs are not mislocalized in the absence of Pho86p.
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PMID:Pho86p, an endoplasmic reticulum (ER) resident protein in Saccharomyces cerevisiae, is required for ER exit of the high-affinity phosphate transporter Pho84p. 1065 92

Expression of the PHO8 and PHO5 genes that encode a nonspecific alkaline and acid phosphatase, respectively, is regulated in response to the P(i) concentration in the medium by the same transcription factors. Upon induction by phosphate starvation, both promoters undergo characteristic chromatin remodeling, yet the extent of remodeling at the PHO8 promoter is significantly lower than at PHO5. Despite the coordinate regulation of the two promoters, the PHO8 promoter is almost 10 times weaker than PHO5. Here we show that of two Pho4 binding sites that had been previously mapped at the PHO8 promoter in vitro, only the high affinity one, UASp2, is functional in vivo. Activation of the PHO8 promoter is partially Pho2-dependent. However, unlike at PHO5, Pho4 can bind strongly to its binding site in the absence of Pho2 and remodel chromatin in a Pho2-independent manner. Replacement of the inactive UASp1 element by the UASp1 element from the PHO5 promoter results in more extensive chromatin remodeling and a concomitant 2-fold increase in promoter activity. In contrast, replacement of the high affinity UASp2 site with the corresponding site from PHO5 precludes chromatin remodeling completely and as a consequence promoter activation, despite efficient binding of Pho4 to this site. Deletion of the promoter region normally covered by nucleosomes -3 and -2 results in a 2-fold increase in promoter activity, further supporting a repressive role of these nucleosomes. These data show that there can be strong binding of Pho4 to a UAS element without any chromatin remodeling and promoter activation. The close correlation between promoter activity and the extent of chromatin disruption strongly suggests that the low level of PHO8 induction in comparison with PHO5 is partly due to the inability of Pho4 to achieve complete chromatin remodeling at this promoter.
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PMID:Transcriptional regulation of the yeast PHO8 promoter in comparison to the coregulated PHO5 promoter. 1080 9

Plants have evolved elaborate metabolic and developmental adaptations to low phosphorus availability. Biochemical responses to phosphate limitation include increased production and secretion of phosphate-acquisition proteins such as nucleases, acid phosphatases, and high-affinity phosphate transporters. However, the signal transduction pathways that sense phosphate availability and integrate the phosphate-starvation response in plants are unknown. We have devised a screen for conditional mutants in Arabidopsis thaliana (L.) Heynh. to dissect signaling of phosphate limitation. Our genetic screen is based on the facultative ability of wild-type Arabidopsis plants to metabolize exogenous DNA when inorganic phosphate is limiting. After screening 50,000 M2 seedlings, we isolated 22 confirmed mutant lines that showed severely impaired growth on medium containing DNA as the only source of phosphorus, but which recovered on medium containing soluble inorganic phosphate. Characterization of nine such mutant lines demonstrated an inability to utilize either DNA or RNA. One mutant line, psr1 (phosphate starvation response), had significantly reduced activities of phosphate-starvation-inducible isoforms of ribonuclease and acid phosphatase under phosphate-limiting conditions. The data suggest that a subset of the selected mutations impairs the expression of more than one phosphate-starvation-inducible enzyme required for utilization of exogenous nucleic acids, and may thus affect regulatory components of a Pi starvation response pathway in higher plants.
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PMID:Conditional identification of phosphate-starvation-response mutants in Arabidopsis thaliana. 1092 99

The expression and secretion of acid phosphatase (APase) was investigated in Indian mustard (Brassica juncea L. Czern.) plants using sensitive in vitro and activity gel assays. Phosphorus (P) starvation induced two APases in Indian mustard roots, only one of which was secreted. Northern-blot analysis indicated transcriptional regulation of APase expression. Polymerase chain reaction and Southern-blot analyses revealed two APase homologs in Indian mustard, whereas in Arabidopsis, only one APase homolog was detected. The Arabidopsis APase promoter region was cloned and fused to the beta-glucuronidase (GUS) and green fluorescent protein (GFP) reporter genes. GUS expression was first evident in leaves of the P-starved Arabidopsis plants. In P-starved roots, the expression of GUS initiated in lateral root meristems followed by generalized expression throughout the root. GUS expression diminished with the addition of P to the medium. Expression of GFP in P-starved roots also initiated in the lateral root meristems and the recombinant GFP with the APase signal peptide was secreted by the roots into the medium. The APase promoter was specifically activated by low P levels. The removal of other essential elements or the addition of salicylic or jasmonic acids, known inducers of gene expression, did not activate the APase promoter. This novel APase promoter may be used as a plant-inducible gene expression system for the production of recombinant proteins and as a tool to study P metabolism in plants.
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PMID:Characterization of Arabidopsis acid phosphatase promoter and regulation of acid phosphatase expression. 1102 12

Phosphate (Pi) is one of the least available plant nutrients found in the soil. A significant amount of phosphate is bound in organic forms in the rhizosphere. Phosphatases produced by plants and microbes are presumed to convert organic phosphorus into available Pi, which is absorbed by plants. In this study we describe the isolation and characterization of a novel tomato (Lycopersicon esculentum) phosphate starvation-induced gene (LePS2) representing an acid phosphatase. LePS2 is a member of a small gene family in tomato. The cDNA is 942 bp long and contains an open reading frame encoding a 269-amino acid polypeptide. The amino acid sequence of LePS2 has a significant similarity with a phosphatase from chicken. Distinct regions of the peptide also share significant identity with the members of HAD and DDDD super families of phosphohydrolases. Many plant homologs of LePS2 are found in the databases. The LePS2 transcripts are induced rapidly in tomato plant and cell culture in the absence of Pi. However, the induction is repressible in the presence of Pi. Divided root studies indicate that internal Pi levels regulate the expression of LePS2. The enhanced expression of LePS2 is a specific response to Pi starvation, and it is not affected by starvation of other nutrients or abiotic stresses. The bacterially (Escherichia coli) expressed protein exhibits phosphatase activity against the synthetic substrate p-nitrophenyl phosphate. The pH optimum of the enzyme activity suggests that LePS2 is an acid phosphatase.
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PMID:LEPS2, a phosphorus starvation-induced novel acid phosphatase from tomato. 1116 Oct 30

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