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
Query: UMLS:C0020639 (
hypoproteinemia
)
1,134
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The AA. reports that
lysine
deficiency in rats results in poor growth, low weight of heart and liver, anemia,
hypoproteinemia
and low concentration of haemoglobin. Rats fed supplemented
lysine
diet did not have any pathological condition in comparison with normal rats receiving standard laboratory diet.
...
PMID:[Essential amino acids and rat growth. I. Effect of lysine deficiency on hematopoiesis and rat growth]. 12 64
Male weanling rats were fed a 72% rice diet containing no detectable carnitine and limiting in threonine and
lysine
. Such dietary conditions may simulate protein malnutrition in man. Under these conditions growth impairment, anemia,
hypoproteinemia
, and fatty liver developed. The study focused principally on the fatty liver syndrome which was corrected to varying extents depending on degrees of supplementation with carnitine,
lysine
, threonine, and appropriate combinations of these nutrients. Such reduction in fatty liver accumulation was accounted for principally by the lowering of triglycerides, but also in part of total cholesterol levels. All the data, which also included monitoring carnitine uptake by the tissues and measurement of plasma triglycerides, were consistent with the view that fatty liver accumulation occurs in amino acid deficient diets because (a) of an impairment in the synthesis of the lipoprotein complex mandatory for triglyceride secretion from the liver and (b) from a deficiency of carnitine needed for the intramitochondrial transport of fatty acids prerequisite for their oxidation.
...
PMID:Dietary lysine and carnitine: relation to growth and fatty livers in rats. 124 84
The objective of this study was to determine the effect of a
lysine
-deficient diet on carnitine status in adult rats and subsequently on ethanol metabolism. Adult male rats were fed either the AIN-76 diet (NS), the AIN-76 diet with wheat gluten (WG) replacing casein, the WG diet plus 0.8% L-
lysine
(LS), or the LS diet plus 0.5% L-carnitine (CS) for 30 days. On the 31st day the rats were given an oral dose of ethanol and blood-ethanol concentrations (BEC) were monitored for the next 8 hours. One week later the rats were given a second dose of ethanol and urine was collected until killed, 3 hours post-ethanol administration (PEA). Besides growth retardation and
hypoproteinemia
, BEC were significantly elevated in the WG group compared to the other group at hours 3-8 PEA. There were no significant differences in BEC between the LS and CS groups; however, their BEC were significantly higher than that of the NS group. The BEC were inversely related to liver alcohol dehydrogenase (ADH) activities which were significantly lower in WG, LS and CS groups than in the NS group. Plasma, liver and urine carnitine values were significantly higher in the CS group than in the NS, WG and LS groups, wherein the values were similar. It is concluded that the WG diet reduced ADH activity and attenuated ethanol metabolism without significantly altering blood, liver and urinary carnitines in the adult rat.
...
PMID:Wheat gluten-based diet retarded ethanol metabolism by altering alcohol dehydrogenase and not carnitine status in adult rats. 846 15
In hyponatremia related to syndrome of inappropriate antidiuretic hormone (SIADH), hypouricemia is explained primarily by the high uric acid clearance rate that results from the decrease in tubular uric acid reabsorption. This modification of tubular handling of uric acid is considered to be induced by the increase in the "effective vascular volume". This study was designed to determine if V1-receptor stimulation participates in the development of a high uric acid clearance rate as in SIADH, in which the antidiuretic hormone acts on V1 and V2 receptors. Therefore, the urate clearance rate was measured in seven volunteers with 1-desamino-8-D-arginine vasopressin (dDAVP)-induced hyponatremia, with dDVAP stimulating exclusively the V2 receptors (Group I), and in six patients with SIADH (Group II) during both normo- and hyponatremia. As expected, in both groups, the serum uric acid concentration decreased during hyponatremia, but did so to a larger extent in the patients with SIADH (-53% versus -29%, P < 0.02). Despite similar levels of hyponatremia (126 +/- 5 mmol/L and 125 +/- 5.5 mmol/L), of
hypoproteinemia
(64 +/- 5 g/L and 63 +/- 5 g/L) and of salt excretion (FENa, 0.66 +/- 0.28% and 0.73 +/- 0.25%), the urate clearance (8.3 +/- 3.3 mL/min) and the fractional excretion of filtered uric acid (5.7 +/- 2%) in Group I were not significantly different during hyponatremia than during normonatremia (6.4 +/- 1.5 mL/min and 5.4 +/- 0.9%). On the other hand, in Group II, both parameters were increased (17.8 +/- 2.9 mL/min and 19.6 +/- 5.3%; P < 0.001) and both values were higher than in the dDAVP-induced hyponatremia (P < 0.01). Additionally, the administration of a potent V1-receptor agonist (triglycyl-
lysine
-vasopressin) in a patient with central diabetes insipidus with preexisting dDAVP-induced hyponatremia produced a rapid increase of urate clearance. Because dDAVP acts only on the V2 receptors, these data suggest that the higher urate clearance observed during hyponatremia related to SIADH is not only the consequence of an increased "effective vascular volume," but that V1-receptor stimulation also contributes to it, by a mechanism that remains to be determined.
...
PMID:Evidence in hyponatremia related to inappropriate secretion of ADH that V1 receptor stimulation contributes to the increase in renal uric acid clearance. 873 18
Plant proteins have a reduced content of essential amino acids in comparison to animal proteins. A significant reduction of limiting amino acids (methionine,
lysine
, tryptophan) means lower protein synthesis. In subjects with predominant or exclusive consumption of plant food a higher incidence of
hypoproteinemia
due to significant reduction of methionine and
lysine
intakes was observed. On the other hand, lower intake of these amino acids provides a preventive effect against cardiovascular disease via cholesterol regulation by an inhibited hepatic phospholipid metabolism. Vegetarians have a significantly higher intake of non-essential amino acids arginine and pyruvigenic amino acids glycine, alanine, serine. When plant protein is high in non-essential amino acids, down-regulation of insulin and up-regulation of glucagon is a logical consequence. The action of glucagon in the liver is mediated by stimulation of adenyl cyclase that raises cyclic-AMP (adenosine-3,5-monophosphate) concentrations. Cyclic-AMP down-regulates the synthesis of a number of enzymes required for de novo lipogenesis and cholesterol synthesis, up-regulates key gluconeogenic enzymes and the LDL receptors and decreases the IGF-1 activity (insulin-like growth factor). Cyclic-AMP thus provides a reduction of atherosclerosis risk factors as well as a retardation of cancer development. A sufficient consumption of plant proteins has the protective effects against chronic degenerative diseases (Tab. 2, Ref. 26).
...
PMID:Health benefits and risks of plant proteins. 1620 43
When blood plasma proteins are depleted by bleeding with return of the washed red blood cells (plasmapheresis) it is possible to bring dogs to a steady state of
hypoproteinemia
and a uniform plasma protein production on a basal low protein diet. These dogs are clinically normal. Introduction of variables into their standardized life gives insight into the production of plasma protein. Casein retested as the basal protein in the ration may show high yield of plasma protein, equal to 33 per cent of the protein fed. This equals the potency of liver protein (17 to 33 per cent) and approaches the utilization of plasma protein by mouth (40 per cent). Zein has no effect upon plasma protein regeneration but when it is supplemented with cystine, tryptophane,
lysine
, and glycine, there is a doubling of the liver basal plasma protein production and a retention of the fed protein nitrogen. Threonine does not modify the above reaction. Liver protein supplemented with cystine, leucine, glutamic acid, and glycine in the basal diet yields double the amount of new formed plasma protein compared with liver alone. This combination is then as potent as plasma protein itself when given by mouth-40 per cent utilization. Tyrosine or
lysine
, arginine, and isoleucine do not modify the above responses. Methionine is not as effective as cystine in supplementing gelatin and tyrosine to produce plasma protein. Cystine, leucine, and glutamic acid appear to be of primary importance in the building of new plasma protein in these experiments. Plasma protein formation is dependent upon materials coming from the body reserve and from the diet. Given an exhaustion of the reserve store there is very little plasma protein produced during a protein fast (3 to 6 gm. per week). A turpentine abscess does not modify this fasting plasma protein reaction. Homologous plasma given by vein will promptly correct experimental
hypoproteinemia
due to bleeding. It will maintain nitrogen equilibrium and replenish protein stores. Even during
hypoproteinemia
plasma protein may promptly pass out of the circulation to supply body needs for protein. Perhaps the most significant concept which derives from all these experiments is the fluidity of the body protein (including plasma protein)-a ready give and take between the protein depots-a "dynamic equilibrium" of body protein.
...
PMID:BLOOD PLASMA PROTEIN PRODUCTION AND UTILIZATION : THE INFLUENCE OF AMINO ACIDS AND OF STERILE ABSCESSES. 1987 Sep 63
When blood plasma proteins are depleted by bleeding with return of the washed red cells (plasmapheresis) it is possible to bring dogs to a steady state of
hypoproteinemia
and a constant level of plasma protein production if the diet protein intake is controlled and limited. Such dogs are outwardly normal but have a lowered resistance to infection and to certain intoxications. When the protein intake of such dogs is completely replaced by the growth mixture (Rose) of crystalline amino acids, plasma protein production is excellent, weight and nitrogen balance are maintained. This growth mixture consists of ten amino acids, threonine, valine, leucine, isoleucine, tryptophane,
lysine
, phenylalanine, methionine, histidine, arginine, and is as effective as most diet proteins in plasma protein production. The above amino acid mixture in aqueous solution may be given by vein with equally good plasma protein production and no apparent clinical disturbance even when given rapidly. Cystine may replace methionine in the above mixture with equally good plasma protein production for 7 to 10 days but at the expense of the body tissues, that is, with weight loss and a negative nitrogen balance. The addition of cystine to the protein-free, otherwise adequate diet may result in the production of considerable new plasma protein during a period as long as 1 week (cystine effect). This reaction may depend upon the amino acid constitution of the preceding diet protein in that it occurred following a liver feeding but did not occur after pancreas feeding. Arginine is required in the diet of the protein depleted dog for fabrication of plasma protein. It is apparently not needed for nitrogen balance for as long as 1 or 2 weeks. The omission of either threonine or valine from the growth mixture is quickly followed by a sharp decline in plasma protein formation and by a negative nitrogen balance. When histidine, arginine, and most of the
lysine
are omitted from the growth mixture, nitrogen balance and weight may be maintained for as long as 1 week but plasma protein production falls off markedly. The findings indicate that the growth mixture of amino acids should be a valuable addition to transfusion and infusion therapy in disease states associated with deficient nitrogen intake or tissue injury and accelerated nitrogen loss, including shock, burns, and major operative procedures.
...
PMID:TEN AMINO ACIDS ESSENTIAL FOR PLASMA PROTEIN PRODUCTION EFFECTIVE ORALLY OR INTRAVENOUSLY. 1987 Dec 82
When blood plasma proteins are depleted by bleeding with return of red cells suspended in saline (plasmapheresis) it is possible to bring dogs to a steady state of
hypoproteinemia
and a constant level of plasma protein production if the diet nitrogen intake is controlled and limited. Such dogs are outwardly normal but have a lowered resistance to infection and to certain intoxications. The ten growth essential amino acids of Rose plus glycine will maintain nitrogen balance and produce as much new plasma protein as will good diet proteins. This good utilization is demonstrated over periods of several months when the amino acids are given either orally or parenterally. There is no evidence of toxicity in general nor to unnatural forms of these synthetic amino acids in particular. Given parenterally appropriate mixtures of these amino acids are well tolerated even upon rapid injection. The minimal daily requirements for a 10 kilo dog may be given intravenously in 10 minutes without reaction. Subcutaneously a 10 per cent solution may be given rapidly without reaction. Among various mixtures tested Vt approximates a minimum for a 10 kilo dog. It contains in grams (dl-threonine 0.7, dl-valine 1.5, l-(-) leucine 1.5, dl-isoleucine 1.4, dl-
lysine
hydrochloride 1.5, l(-) tryptophane 0.4, dl-phenylalanine 1.0, dl-methionine 0.6, l(+)-histidine hydrochloride 0.5, l(+)-arginine hydrochloride 0.5, and glycine 1.0. The presence of glycine improves tolerance to rapid intravenous injection, but excess glycine does not improve utilization of the mixture. Over a long period this mixture appears suboptimal in quantity. Doubled it is more than ample. Of two casein digests tested the one prepared by enzymatic hydrolysis provided good nitrogen retention and fairly good plasma protein production but was much less tolerable upon intravenous injection than certain mixtures of pure amino acids. The other one prepared by acid hydrolysis and tryptophane fortification afforded bare nitrogen equilibrium and produced virtually no plasma protein. Skin lesions observed after 10 to 20 weeks of synthetic diet probably reflect a deficiency of some member or members of the vitamin B(2) group. A persistent slight weight loss in the face of a strongly positive nitrogen balance may accompany this deficiency.
...
PMID:AMINO ACID MIXTURES EFFECTIVE PARENTERALLY FOR LONG CONTINUED PLASMA PROTEIN PRODUCTION. CASEIN DIGESTS COMPARED. 1987 90
When blood plasma proteins are depleted by bleeding with return of red cells suspended in saline (plasmapheresis) it is possible to bring dogs to a steady state of
hypoproteinemia
and a constant level of plasma protein production if the diet nitrogen intake is controlled and limited. Such dogs are outwardly normal but have a lowered resistance to infection and intoxication and probably to vitamin deficiency. When the diet nitrogen is provided by certain mixtures of the ten growth essential amino acids plus glycine, given intravenously at a rapid rate, plasma protein production is good. The same mixture absorbed subcutaneously at a slower rate may be slightly better utilized. Fed orally the same mixture is better utilized and associated with a lower urinary nitrogen excretion. An ample amino acid mixture for the daily intake of a 10 kilo dog may contain in grams dl-threonine 1.4, dl-valine 3, dl-leucine 3, dl-isoleucine 2, l(+)-
lysine
.HCl.H(2)O 2.2, dl-tryptophane 0.3, dl-phenylalanine 2, dl-methionine 1.2, l(+)-histidine.HCl.H(2)O 1, l(+)-arginine.HCl 1, and glycine 2. Half this quantity is inadequate and not improved by addition of a mixture of alanine, serine, norleucine, proline, hydroxyproline, and tyrosine totalling 1.4 gm. Aspartic acid appears to induce vomiting when added to a mixture of amino acids. The same response has been reported for glutamic acid (8). Omission from the intake of leucine or of leucine and isoleucine results in negative nitrogen balance and rapid weight loss but plasma protein production may be temporarily maintained. It is possible that leucine may be captured from red blood cell destruction. Tryptophane deficiency causes an abrupt decline in plasma protein production. No decline occurred during 2 weeks of histidine deficiency but the urinary nitrogen increased to negative balance. Plasma protein production may be impaired during conditions of dietary deficiency not related to the protein or amino acid intake. Skin lesions and liver function impairment are described. Unidentified factors present in liver and yeast appear to be involved.
...
PMID:PLASMA PROTEIN PRODUCTION INFLUENCED BY AMINO ACID MIXTURES AND LACK OF ESSENTIAL AMINO ACIDS : A DEFICIENCY STATE RELATED TO UNKNOWN FACTORS. 1987 90
Given healthy dogs fed abundant iron and protein-free or low protein diets with sustained anemia and
hypoproteinemia
, we can study the capacity of these animals to produce simultaneously new hemoglobin and plasma protein. Reserve stores of blood protein-building materials are measurably depleted and levels of 6 to 8 gm. per cent for hemoglobin and 4 to 5 gm. per cent for plasma protein can be maintained for weeks or months depending upon the intake of food proteins or amino acid mixtures. These dogs are very susceptible to infection and various poisons. Dogs tire of these diets and loss of appetite terminates many experiments. Under these conditions (double depletion) standard growth mixtures of essential amino acids are tested to show the response in blood protein output and urinary nitrogen balance. As a part of each tabulated experiment one of the essential amino acids is deleted from the complete growth mixture to compare such response with that of the whole mixture. Methionine, threonine, phenylalanine, and tryptophane when singly eliminated from the complete amino acid mixture do effect a sharp rise in urinary nitrogen. This loss of urinary nitrogen is corrected when the individual amino acid is replaced in the mixture. Histidine,
lysine
, and valine have a moderate influence upon urinary nitrogen balance toward nitrogen conservation. Leucine, isoleucine, and arginine have minimal or no effect upon urinary nitrogen balance when these individual amino acids are deleted from the complete growth mixture of amino acids during 3 to 4 week periods. Tryptophane and to a less extent phenylalanine and threonine when returned to the amino acid mixture are associated with a conspicuous preponderance of plasma protein output over the hemoglobin output (Table 4). Arginine,
lysine
, and histidine when returned to the amino acid mixture are associated with a large preponderance of hemoglobin output. Various amino acid mixtures under these conditions may give a positive urinary nitrogen balance and a liberal output of blood proteins but there is always weight loss, however we may choose to explain this loss. These experiments touch on the complex problems of parenteral nutrition, experimental and clinical.
...
PMID:PLASMA PROTEIN AND HEMOGLOBIN PRODUCTION : DELETION OF INDIVIDUAL AMINO ACIDS FROM GROWTH MIXTURE OF TEN ESSENTIAL AMINO ACIDS. SIGNIFICANT CHANGES IN URINARY NITROGEN. 1987 12
1
