ビタミン 60 巻, 9 号

細胞質アセチル-CoA水解酵素の発見と生理的意義

A rat liver acetyl-coenzyme A hydrolase, which appears to have an extra-mitochondrial location, has escaped previous detection presumably due to its extreme cold lability and to its ATP-sensitivity. This enzyme activity is highly regulated by nucleotides. The enzyme is activated by ATP and completely in-hibited by ADP and has various forms (tetramer, dimer and monomer). In the presence of ATP or ADP, but not AMP, at room temperature, the dimeric form (Mr 135,000) of the enzyme reassociates to the tetrameric form (Mr 240,000) and removal of nucleotides from the tetrameric enzyme causes its dissociation, mainly into the enzymatically active dimeric form and partly into the inactive monomer. Formation of the monomer is greater whetn the dimeric and tetrameric forms are treated at low temperature. ATP (2mM), phosphate (0.9M) and pyrophosphate (0.45M) enhance reactivation of the enzyme on rewarming, judged by recovery of catalytic activity and restoration of dimer and tetramer forms. The apparent Km values for acetyl-CoA of the dimeric and tetrameric forms are different, being 170μM and 60μM, respectively. Increase in cytosolic acetyl-CoA hydrolase activity was observed in opposite metabolic states: namely, during fatty acid oxidation (hypolipidemic acid administration, starvation and diabetes) and during fatty acid synthesis (refeeding on fat-free diet with a high carbohydrate content with or without 1% thyroid powder). Thus the enzyme activity may change in response or adaptation to unusual physiological states. Increase in cytosolic acetyl-CoA hydrolase, which hydrolyzes acetyl-CoA to CoASH and acetate, can be interpreted as an effective method for regulating the cytosolic acetyl-CoA and cytosolic free CoASH concentration, which is known to be important in both lipogenesis and lipolysis.

ビタミンD依存性カルシウム結合タンパク質様タンパク質のイムノブロッティング法による検索 : ニワトリおよびラット臓器における分布

The immunoblotting method, with use of antiserum raised to vitamin D-dependent calcium-binding protein (CaBP) purified from hen intestine, has been applied to detection of CaBP-like protein in various organs of the chicken and rat. In this study, "CaBP-like protein" is reffered to a protein which meets all of following characteristics examined by the immunoblotting method: Cross reaction with anti-hen intestinal CaBP antiserum; Mr&sime;28K; Differential mobility on SDS-polyacrylamide gel electrophoresis between the presence vs. absence of Ca^<2+> in the sample. CaBP-like protein, of Mr equal to purified hen intestinal CaBP, was detected in hen intestine, brain and kidney. In the 15-day-old chick embryo the CaBP-like protein was detected in the brain and kidney and its molecular weight (no information available so far) was found to be equal to that of purified hen intestinal CaBP. The similar protein was also detected in rat brain and kidney, whereas no evidence was obtained on the presence of this protein in rat intestine. These results substantially confirmed previous findings by other methods. In rat brain, in addition to the CaBP-like protein shown above, the immunoblotting method successfully detected another CaBP-like protein with Mr 30K slightly higher than hen intestinal CaBP, indicating the heterogeneity of CaBP-like protein. Undoubtedly, the present method is more convenient for detection of CaBP-like protein with accuracy than previous methods such as radioimmunoassay and Ca-binding assay, because multiple characteristics of this protein are obtainable through this single-handed method.