Synthesis of fatty acids from acetyl CoA A: need NADPH B: need NAD+ C: produce malonyl CoA in the first step D: occur in mitochondria E: It's the reverse reactions of fatty acid oxidation
Synthesis of fatty acids from acetyl CoA A: need NADPH B: need NAD+ C: produce malonyl CoA in the first step D: occur in mitochondria E: It's the reverse reactions of fatty acid oxidation
The inhibition of carnitine acyltransferase I by malonyl-CoA ensures that the oxidation of fatty acids is inhibited whenever the liver is amply supplied with glucose as fuel and is actively making triacylglycerols from excess glucose.
The inhibition of carnitine acyltransferase I by malonyl-CoA ensures that the oxidation of fatty acids is inhibited whenever the liver is amply supplied with glucose as fuel and is actively making triacylglycerols from excess glucose.
If fatty acid synthesis and β oxidation were to proceed simultaneously, the two processes would constitute a futile cycle, wasting energy. We noted earlier that β oxidation is blocked by malonyl-CoA, which inhibits carnitine acyltransferase I. Thus, during fatty acid synthesis, production of the first intermediate, malonyl-CoA, shuts down β oxidation at the level of a transport system in the inner mitochondrial membrane. This control mechanism illustrates another advantage of segregating synthetic and degradative pathways in different cellular compartments.
If fatty acid synthesis and β oxidation were to proceed simultaneously, the two processes would constitute a futile cycle, wasting energy. We noted earlier that β oxidation is blocked by malonyl-CoA, which inhibits carnitine acyltransferase I. Thus, during fatty acid synthesis, production of the first intermediate, malonyl-CoA, shuts down β oxidation at the level of a transport system in the inner mitochondrial membrane. This control mechanism illustrates another advantage of segregating synthetic and degradative pathways in different cellular compartments.
丙酮酸氧化脱羧生成的物质是 A: 丙酰CoA B: 乙酰CoA C: 羟基戊二酰CoA D: 乙酰乙酰CoA E: 琥珀酰CoA
丙酮酸氧化脱羧生成的物质是 A: 丙酰CoA B: 乙酰CoA C: 羟基戊二酰CoA D: 乙酰乙酰CoA E: 琥珀酰CoA
含奇数碳原子的脂肪酸链经过β-氧化的产物是______。 A: 丙酰CoA B: 乙酰CoA C: 乙酰CoA和丙二酸单酰CoA D: 乙酰CoA和丙酰CoA
含奇数碳原子的脂肪酸链经过β-氧化的产物是______。 A: 丙酰CoA B: 乙酰CoA C: 乙酰CoA和丙二酸单酰CoA D: 乙酰CoA和丙酰CoA
丙酮酸氧化脱羧生成的物质是( ) A: 丙酰CoA B: 乙酰CoA C: 乙酰乙酰CoA D: 琥珀酰CoA
丙酮酸氧化脱羧生成的物质是( ) A: 丙酰CoA B: 乙酰CoA C: 乙酰乙酰CoA D: 琥珀酰CoA
能产生乙酰CoA的物质是:①乙酰乙酰CoA②脂酰CoA③β-羟-β-甲基戊二酸单酰CoA④柠檬酸
能产生乙酰CoA的物质是:①乙酰乙酰CoA②脂酰CoA③β-羟-β-甲基戊二酸单酰CoA④柠檬酸
乙酰CoA羧化酶的变构激活剂是______。 A: 棕榈酰CoA B: 硬脂酰CoA C: 长链脂酰CoA D: 柠檬酸
乙酰CoA羧化酶的变构激活剂是______。 A: 棕榈酰CoA B: 硬脂酰CoA C: 长链脂酰CoA D: 柠檬酸
[单选题]合成胆固醇的直接原料是. A: 乙酰CoA B: 乙酰乙酰CoA C: 脂肪酰CoA D: 丙二酸单酰CoA E: 脂酰CoA
[单选题]合成胆固醇的直接原料是. A: 乙酰CoA B: 乙酰乙酰CoA C: 脂肪酰CoA D: 丙二酸单酰CoA E: 脂酰CoA
52.合成酮体和胆固醇均需要 A: HMG CoA合酶 B: HMG CoA还原酶 C: HMG CoA裂解酶 D: 乙酰CoA
52.合成酮体和胆固醇均需要 A: HMG CoA合酶 B: HMG CoA还原酶 C: HMG CoA裂解酶 D: 乙酰CoA