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Query: UMLS:C0038187 (
starvation
)
24,951
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Higher omega-oxidation activities in the diabetic mammal and the starved one suggest that omega-oxidation mechanism plays an important role under these conditions. Dicarboxylic acid that is the final product of omega-oxidation can be metabolized further by beta-oxidation, subsequently, formation of succinyl-CoA and short-chain dicarboxylic acid might be increased in the liver. The physiological significance of omega-oxidation might consist in supplying the substrate of TCA cycle for utilization of acetyl-CoA and excreting the short-chain dicarboxylate in urine resulting in the decrease of ketone bodies in the blood, especially in diabetes and
starvation
. On the bases of these information, it is important to investigate the metabolism of dicarboxylic acids. Generally, fatty acids must be activated before they enter the metabolic pathway. By in vitro studies with rat liver homogenate, we have recently demonstrated that octadecaned-ioic acid must be activated by ATP-Mg2+ and CoA as monocarboxylic acid is. However, it has not been studied to compare the activity of acyl-CoA synthetase on mono and dicarboxylic acid. So, in this report, we assayed the activity of acyl-CoA synthetase in beef liver preparations using palmitic or
hexadecanedioic acid
(C1;16) as substrate. The results are as follows 1) Activation capacity of the supernatant of sonicated mitochondria was less than that of sonicated microsome for either palmitate or hexadecanedioate. 2) Activation capacity for hexadecanedioate was less than that for palmitate in both supernatant of sonicated mitochondria and that of sonicated microsome. 3) In our experiment, it might be suggested that the subcellular distribution of hexadecanedioate activation is almost identical with that of palmitate activation.
...
PMID:[Acyl-CoA synthetase activity of long-chain mono and dicarboxylic acid in beef liver preparations (author's transl)]. 94 21
The conversion of radioactive C6-C16-monocarboxylic acids to urinary adipic, suberic, sebacic and 3-hydroxybutyric acids was investigated in vivo in unstarved, starved and diabetic ketotic rats. Hexanoic, octanoic and decanoic acids were converted to C6-, C6-C8- and C6-C10-dicarboxylic acids, respectively, in fed and 72-h-starved rats. Lauric acid was converted to C6-C8-dicarboxylic acids in starved rats but not in unstarved rats. Decanoic and lauric acids were converted to relatively high amounts of C6-C8-dicarboxylic acids compared with myristic acid in myristic acid in ketotic diabetic rats, while radioactivity from [1-14C]-and [16-(14)] palmitic acid was not incorporated into C6-C8-dicarboxylic acids in diabetic ketotic rats. C6-C12-monocarboxylic acids in hydrolysed rat adipose tissue wee determined by gas-liquid chromatography-mass spectrometry (selected ion monitoring). Decanoic and lauric acids were found in amounts of 7.6-9.1 and 85.9-137.5 micrometers/100 mg tissue, respectively, whereas the amounts of hexanoic and octanoic acids were negligible. It is concluded that the biological origin of the C6-C8-dicarboxylic aciduria seen in ketotic rats are C10-C14-monocarboxylic acids, which are initially omega-oxidised solely or partly as free acids and subsequently beta-oxidised to adipic and suberic acids. The in vitro omega-oxidation of C6-C16-monocarboxylic acids to corresponding dicarboxylic acids in the 100,000 Xg supernatant fraction of rat liver homogenate was measured by selected ion monitoring. 0.09, 0.14, 16.1, 5.8, 7.0 and -6.9% of, respectively, hexanoic, octanoic, decanoic, lauric, myristic and palmitic acid were omega-oxidised to dicarboxylic acids of corresponding chain lengths after 90 min of incubation, when correction for the production of dicarboxylic acids in control assays was made. An in vitro production of C12-C16-dicarboxylic acids was detected in all assays ()including control assays), probably formed from"endogenous' monocarboxylic acids preexistent in the homogenate. Ths "endogenous' production of dicarboxylic acids was inhibited by C10-C16-monocarboxylic acids, where palmitic acid had the strongest effect. In fact, palmitic acid inhibited its own omega-oxidation when added in concentrations above 0.6 mM.
Starvation
of rats for 72 h did not alter the "endogenous' in vitro production of
hexadecanedioic acid
.
...
PMID:The biological origin of ketotic dicarboxylic aciduria. In vivo and in vitro investigations of the omega-oxidation of C6-C16-monocarboxylic acids in unstarved, starved and diabetic rats. 679 96
