维生素B12缺乏大鼠肾脏和肝脏中丙酸的糖异生作用。
Gluconeogenesis from propionate in kidney and liver of the vitamin B12-deficient rat.
作者信息
Weidemann M J, Hems R, Williams D L, Spray G H, Krebs H A
出版信息
Biochem J. 1970 Mar;117(1):177-81. doi: 10.1042/bj1170177.
Abstract
- Kidney-cortex slices and the perfused livers of vitamin B(12)-deficient rats removed propionate from the incubation and perfusion media at 33 and 17% respectively of the rates found with tissues from rats receiving either a normal or a vitamin B(12)-supplemented diet. There was a corresponding fall in the rates of glucose synthesis from propionate in both tissues. 2. The addition of hydroxocobalamin or dimethylbenzimidazolylcobamide coenzyme to kidney-cortex slices from vitamin B(12)-deficient rats in vitro failed to restore the normal capacity for propionate metabolism. 3. Although the vitamin B(12)-deficient rat excretes measurable amounts of methylmalonate, no methylmalonate production could be detected (probably because of the low sensitivity of the method) when kidney-cortex slices or livers from deficient rats were incubated or perfused with propionate. 4. The addition of methylmalonate (5mm) to kidney-cortex slices from rats fed on a normal diet inhibited gluconeogenesis from propionate by 25%. 5. Methylmalonate formation is normally only a small fraction of the flux through methylmalonyl-CoA. This fraction increases in vitamin B(12)-deficient tissues (as shown by the urinary excretion of methylmalonate) presumably because the concentration of methylmalonyl-CoA rises as a result of low activity of methylmalonyl-CoA mutase (EC 5.4.99.2). Slow removal of methylmalonyl-CoA might depress propionate uptake owing to the reversibility of the steps leading to methylmalonyl-CoA formation.
摘要
- 维生素B12缺乏大鼠的肾皮质切片和灌注肝脏分别以接受正常饮食或补充维生素B12饮食大鼠组织所发现速率的33%和17%,从孵育和灌注培养基中去除丙酸盐。两种组织中由丙酸盐合成葡萄糖的速率相应下降。2. 在体外向维生素B12缺乏大鼠的肾皮质切片中添加羟钴胺素或二甲基苯并咪唑基钴胺辅酶,未能恢复丙酸盐代谢的正常能力。3. 尽管维生素B12缺乏的大鼠排泄出可测量量的甲基丙二酸,但当用丙酸盐孵育或灌注缺乏大鼠的肾皮质切片或肝脏时,未检测到甲基丙二酸的产生(可能是由于该方法灵敏度低)。4. 向喂食正常饮食大鼠的肾皮质切片中添加甲基丙二酸(5mmol/L)可使丙酸盐的糖异生减少25%。5. 甲基丙二酸的形成通常只是通过甲基丙二酰辅酶A通量的一小部分。这一比例在维生素B12缺乏的组织中增加(如甲基丙二酸的尿排泄所示),推测是因为甲基丙二酰辅酶A变位酶(EC 5.4.99.2)活性低导致甲基丙二酰辅酶A浓度升高。由于导致甲基丙二酰辅酶A形成步骤的可逆性,甲基丙二酰辅酶A的缓慢清除可能会抑制丙酸盐的摄取。
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本文引用的文献
1
Biochemical aspects of bovine ketosis.牛酮病的生化方面。
Biochem J. 1968 May;107(5):683-9. doi: 10.1042/bj1070683.
2
MAMMALIAN METHYLMALONYL ISOMERASE AND VITAMIN B(12) COENZYMES.哺乳动物甲基丙二酰异构酶与维生素B12辅酶
Proc Natl Acad Sci U S A. 1960 Oct;46(10):1312-8. doi: 10.1073/pnas.46.10.1312.
3
ISOLATION AND PROPERTIES OF B(12) COENZYMES CONTAINING BENZIMIDAZOLE OR DIMETHYLBENZIMIDAZOLE.含苯并咪唑或二甲基苯并咪唑的B(12)辅酶的分离与性质
Proc Natl Acad Sci U S A. 1959 Apr;45(4):521-5. doi: 10.1073/pnas.45.4.521.
4
Microdiffusion of acetic acid as an assay for acetylcholinesterase.用于乙酰胆碱酯酶测定的乙酸微量扩散法。
J Biol Chem. 1955 Jul;215(1):263-8.
5
PREPARATION AND PROPERTIES OF 5,6-MONOEPOXYVITAMIN A ACETATE, 5,6-MONOEPOXYVITAMIN A ALCOHOL, 5,6-MONOEPOXYVITAMIN A ALDEHYDE AND THEIR CORRESPONDING 5,8-MONOEPOXY (FURANOID) COMPOUNDS.5,6-单环氧维生素A醋酸酯、5,6-单环氧维生素A醇、5,6-单环氧维生素A醛及其相应的5,8-单环氧(呋喃型)化合物的制备与性质
Biochem J. 1965 Apr;95(1):17-26. doi: 10.1042/bj0950017.
6
Methylmalonic acid excretion: an index of vitamin-B12 deficiency.甲基丙二酸排泄:维生素B12缺乏的一个指标。
Lancet. 1962 Oct 27;2(7261):853-6. doi: 10.1016/s0140-6736(62)90631-1.
7
Primary metabolic defect supervening on vitamin B12 deficiency in the sheep.绵羊维生素B12缺乏继发的原发性代谢缺陷。
Nature. 1961 Jun 17;190:1085-91. doi: 10.1038/1901085a0.
8
The reduction of acetoacetate to beta-hydroxybutyrate in animal tissues.动物组织中乙酰乙酸还原为β-羟基丁酸的过程。
Biochem J. 1961 Jan;78(1):95-106. doi: 10.1042/bj0780095.
9
Gluconeogenesis in the perfused rat liver.灌注大鼠肝脏中的糖异生作用。
Biochem J. 1966 Nov;101(2):284-92. doi: 10.1042/bj1010284.
10
A method for the colorimetric determination of urinary methylmalonic acid in pernicious anemia.一种用于比色测定恶性贫血患者尿中甲基丙二酸的方法。
J Lab Clin Med. 1965 Oct;66(4):667-76.
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