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)

Little is known about the degradation of the most abundant protein in nature, ribulose-bisphosphate carboxylase (RuBP carboxylase, EC 4.1.1.39), probably reflecting the fact that no stress situation has been identified capable of causing extensive RuBP carboxylase degradation without causing the death of the plant. We have subjected plants of Lemna minor L. to a variety of stress situations, nutritive deficiencies in particular, and have found a single condition--sulfur starvation--that caused almost complete degradation of RuBP carboxylase without causing plant death. Moreover, the enzyme was preferentially degraded under these conditions. However, when the plants were deprived of calcium, no RuBP carboxylase degradation was observed. Instead, the enzyme was oxidized and polymerized into high molecular mass aggregates. On the other hand, RuBP carboxylase shows an extreme stability when Lemna is deprived of some macronutrients (e.g. nitrogen, phosphorus, potassium, and magnesium) probably reflecting that this plant had to evolve in a way to cope with frequent shortages of such elements. The implications of these data for the role of RuBP carboxylase as a leaf storage protein are discussed.
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PMID:Sulfur starvation in Lemna leads to degradation of ribulose-bisphosphate carboxylase without plant death. 155 69

Pseudomonas aeruginosa was shown to be attracted to phosphate. The chemotactic response was induced by phosphate starvation. The specificity of chemoreceptors for phosphate was high so that no other tested phosphorus compounds elicited a chemotactic response as strong as that elicited by phosphate. Competition experiments showed that the chemoreceptors for phosphate appeared to be different from those for the common amino acids. Mutants constitutive for alkaline phosphatase showed the chemotactic response to phosphate regardless of whether the cells were starved for phosphate.
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PMID:Phosphate taxis in Pseudomonas aeruginosa. 162 73

Technological advances in the intensive care of low birth weight (LBW) infants have resulted in major increases in their survival. New challenges in meeting their nutritional needs have emerged. Very low birth (VLBW) weight infants have very little body fat or glycogen reserves at birth, making them susceptible to starvation. If fed enterally, they require at least 120 calories/kg per day for growth. Numerous immaturities in the gastrointestinal tract and liver limit protein digestion, absorption, and metabolism. Several amino acids not considered essential to the older child or adult are essential to the VLBW infant. Supplying a high protein load with an inappropriate amino acid composition may lead to metabolic imbalances. The digestion and absorption of fats differs from the older child or adult. Lingual and gastric lipases are important, and the lack of bile acids limits fat absorption. Lipoprotein lipase deficiency causes problems when too much fat or fat of incorrect composition is provided. There are controversies regarding the most appropriate carbohydrate source, but research shows that lactose remains an important carbohydrate source for most of these infants. Calcium, magnesium, and phosphorus requirements pose questions in both enterally and parenterally nourished infants. Studies of iron usage suggest that VLBW infants fed either human milk or formula should receive iron supplements. Vitamin E may be helpful in preventing oxygen toxicity. Vitamin D deficiency contributes to bone demineralization and rickets. Controversy exists regarding the correlation between vitamin A nutrition and development of chronic lung disease. Guidelines have been developed for recommended intakes, but much needs to be learned to provide a sound scientific basis upon which to provide optimal nourishment for the high risk, LBW infant.
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PMID:Scientifically-based strategies for nutrition of the high-risk low birth weight infant. 212 45

In response to phosphorus starvation, Neurospora crassa makes several enzymes that are undetectable or barely detectable in phosphate-sufficient cultures. The nuc-1+ gene, whose product regulates the synthesis of these enzymes, was cloned and sequenced. The nuc-1+ gene encodes a protein of 824 amino acids with a predicted molecular weight of 87,429. The amino acid sequence shows homology with two yeast proteins whose functions are analogous to that of the NUC-1 protein. Two nuc-1+ transcripts of 3.2 and 3.0 kilobases were detected; they were present in similar amounts during growth at low or high phosphate concentrations. The nuc-2+ gene encodes a product normally required for NUC-1 function, and yet a nuc-2 mutation can be complemented by overexpression of the nuc-1+ gene. This implies physical interactions between NUC-1 protein and the negative regulatory factor(s) PREG and/or PGOV. Analysis of nuc-2 and nuc-1; nuc-2 strains transformed by the nuc-1+ gene suggests that phosphate directly affects the level or activity of the negative regulatory factor(s) controlling phosphorus acquisition.
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PMID:Molecular analysis of nuc-1+, a gene controlling phosphorus acquisition in Neurospora crassa. 214 93

The work is concerned with studying the breakdown of proteins and RNA when a polyauxotrophic Escherichia coli strain is incubated in a salt solution without amino acids, phosphorus, nitrogen and glucose at 43 degrees C as well as the ability of starving bacterial cells to recommence protein and RNA synthesis (also in the course of phage T4 infection) and to reproduce bacteriophages T4, lambda and MS2. Within the first two hours of the incubation, 12% of proteins and 40% of RNA break down to acid-soluble fragments. Then protein degradation stops while RNA decomposition goes on, but at a lower rate. Within 4-6 h of starvation, the rate of protein and RNA synthesis drops down 4-5 times and the survival rate equals 40-60% when the cells are transferred onto a complete medium. The quantitative characteristics of phages T4, lambda and MS2 reproduction fall down in prestarved cells. The authors speculate that E. coli cells die off in the course of starvation not because some unique structure is destroyed, but owing to the fact that the activity of enzymes and ribosomes gradually declines. As a result, the synthetic activity of the cell drops down abruptly and irreversibly because the enzymes are inactivated and RNA breaks down, which eventually causes cell death.
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PMID:[Decreased synthetic activity as a possible cause of the death of Escherichia coli bacteria during amino acid starvation]. 244 Dec 35

Pseudomonas sp. strain PG2982 has the ability to use the phosphonate herbicide, glyphosate, as a sole phosphorus source (J. K. Moore, H. D. Braymer, and A. D. Larson, Appl. Environ. Microbiol. 46:316-320, 1983). Glyphosate uptake is maximal in the late log phase of growth and is induced by phosphate starvation. Uptake is inhibited by phosphate and arsenate, but not by the amino acids glycine and sarcosine. The Km and Vmax for glyphosate uptake were calculated to be 23 microM and 0.97 nmol/mg (dry weight) per min, respectively. A phosphate transport system with a broad substrate specificity may be responsible for glyphosate uptake.
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PMID:Phosphate starvation induces uptake of glyphosate by Pseudomonas sp. strain PG2982. 245 66

Phosphorus is the sixth most abundant element in the body after oxygen, hydrogen, carbon, nitrogen, and calcium. It comprises about 1% of the total body weight of humans. Eighty-five percent of it is stored in the bone in the form of hydroxyapatite crystal; 14% is in the soft tissues in the form of energy-storing bonds with nucleotides (ATP, GTP), nucleic acids in chromosomes and ribosomes, 2,3-DPG in the red blood cells, and phospholipids in the cells' membranes. Less than 1% is in the extracellular fluids. Phosphate balance is maintained by multiple systems. The gut is responsible for the absorption of two thirds of the 4-30 mg/kg/day of phosphate intake. Absorption sites are all along the gut; in humans the most active site is the jejunum. The kidney filters 90% of the plasma phosphate and reabsorbs it in the tubuli. In states of hypophosphatemia the kidney can reabsorb the filtered phosphates very efficiently, reducing the amount excreted in the urine virtually to zero. The healthy kidney can excrete high loads of phosphate and rid the body of phosphate overload. Through the vitamin D-PTH axis the endocrine system regulates the phosphate balance by influencing the kidney, gut, and bone. Other hormones, including thyroid, insulin, glucagon, glucocorticosteroid, and thyrocalcitonin, play a lesser role in regulation of phosphate metabolism. Because of the complex control of phosphate homeostasis, various clinical conditions may lead to hypophosphatemia. These include nutritional repletion, gastrointestinal malabsorption, use of phosphate binders, starvation, diabetes mellitus, and increased urinary losses due to tubular dysfunction. The clinical picture of phosphate depletion is manifested in different organs and is due mainly to the fall in intracellular levels of ATP and decreased availability of oxygen to the tissues, secondary to 2,3-DPG depletion. The various manifestations of phosphate depletion are listed in Table 2. The treatment of hypophosphatemia consists of administering enteral or parenteral phosphate salts. An important aspect of dealing with the potentially serious effects of phosphate depletion is to prevent the depletion from happening in the first place. Hyperphosphatemia can occur in renal failure, hemolysis, tumor lysis syndrome, and rhabdomyolysis. The treatment of hyperphosphatemia usually consists of fluid administration (in the absence of kidney failure). In chronic hyperphosphatemia, phosphate binders such as aluminum and magnesium salts can reduce the phosphate load. The use of these phosphate binders is limited by their potential side effects.
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PMID:Consequences of phosphate imbalance. 306 Jan 61

The 31P nuclear magnetic resonance (NMR) spectrum of the digestive gland-gonad complex (DGG) of the schistosome vector Biomphalaria glabrata was characterized and the effects of infection by Schistosoma mansoni noted. The in vivo spectrum was comprised of 11 peaks, 5 downfield and 6 upfield of an external 85% phosphoric acid standard. Based on a variety of analytical procedures, the upfield peaks from the standard were demonstrated to be composed of carbamoyl phosphate + a mixture of 3 phosphatides and sphingomyelin, the gamma + beta phosphorus resonances of nucleotide triphosphate (NTP) and nucleotide diphosphate (NDP), respectively, the alpha phosphorus resonances of NTP + NDP, NAD(H) + the phosphorus resonance of uridine phosphate from uridine diphosphoglucose (UDPG), the phosphorus resonance of glucose phosphate from UDPG and, last, the beta phosphorus resonance of NTP. The downfield peaks were assigned as glycerophosphoryl choline, intracellular inorganic phosphate (Pi), sugar phosphates + phosphoryl choline, aminoethyl phosphonate (AEP), and ceramide AEP. T1 values for the in vivo NMR components were determined by inversion recovery. Infection produced distinct alterations in the levels of nonnucleotide components of the in vivo 31P NMR spectrum and the spectra of tissue extracts. Specifically, the levels of phosphonate, phospholipids, and carbamoyl phosphate were markedly reduced, and the relative level of Pi was increased. The potential significance of these changes to the parasite-host relationship was discussed. In contrast, starvation resulted in a decreased level of phosphonate only. The pH of the intact DGG was estimated by titrating the inorganic phosphate component of tissue extracts. The mean pH was 6.9 for both control and infected material.
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PMID:Characterization of the 31P NMR spectrum of the schistosome vector Biomphalaria glabrata and of the changes following infection by Schistosoma mansoni. 357 67

It has been suggested that adaptation to starvation may be impaired in patients with malignant disease and that this may contribute to the development of cancer cachexia. We have investigated this by comparing the body composition, as well as the tissue composition of weight loss, of a group of 49 patients with gastrointestinal carcinomas and 91 patients with benign gastrointestinal disease all of whom had sustained a weight loss greater than 10% of their recalled pre-illness weight. Total body protein was calculated from total body nitrogen measured by in vivo neutron activation analysis which also provided absolute values of sodium, chlorine, phosphorus, and calcium. The masses of muscle and nonmuscle protein were estimated using a validated compartmental analysis. Total body fat was derived using anthropometry. Total body water was estimated from the difference between body weight and the sum of body protein, fat, and minerals. The loss of body weight incurred by patients with both benign and malignant disease was primarily muscle mass and body fat. Both groups of patients retained nonmuscle protein. All patients manifested, with increasing weight loss, a progressive loss of muscle protein, fat, and water, which must represent the tissue composition of weight loss. No significant differences between patients with benign or malignant disease were demonstrated for any of the body composition parameters measured. The results of this study do not support the hypothesis that adaptation to starvation in patients with cancer is in anyway different from that which occurs in patients with benign disease.
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PMID:Body composition in malignant disease. 382 8

We have investigated the physiological conditions under which meiosis and the ensuing sporulation of Saccharomyces cerevisiae are initiated. Initiation of sporulation occurs in response to carbon, nitrogen, phosphorus, or sulfur deprivation, and also, when met auxotrophs are partially starved for methionine, but not after starvation of other amino acid auxotrophs. It also occurs after partial starvation of pur or gua auxotrophs for guanine but not after starvation of ura auxotrophs for uracil. Under all these sporulation conditions the concentrations of both guanine nucleotides (GTP) and S-adenosylmethionine (SAM) decrease whereas those of other nucleotides show no trend. We show that the decrease of guanine nucleotides is essential for the initiation of meiosis and sporulation: when a gua auxotroph, also lacking one of the two SAM synthetases, is starved for guanine but supplemented with 0.1 mM methionine, GTP decreases while SAM slightly increases and yet the cells sporulate.
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PMID:Partial deprivation of GTP initiates meiosis and sporulation in Saccharomyces cerevisiae. 390 31

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