(a)
Interpretation:
The site of process of fatty acid synthesis and degradation must be compared.
Concept introduction:
The fatty acids are degraded in a sequential manner, that is two carbon units at the carboxyl end of the molecule are removed in each step. The process of beta-oxidation of fatty acids degrades the fatty acids. The process of fatty acid synthesis is a stepwise process, which occurs by the addition of two-carbon units. These carbon units are provided by the acetyl-CoA, derived from glucose oxidation.
(b)
Interpretation:
The acyl carrier of fatty acid synthesis and degradation must be compared.
Concept introduction:
The fatty acids are degraded in a sequential manner, that is two carbon units at the carboxyl end of the molecule are removed in each step. The process of beta-oxidation of fatty acids degrades the fatty acids. The process of fatty acid synthesis is a stepwise process, which occurs by the addition of two-carbon units. These carbon units are provided by the acetyl-CoA, derived from glucose oxidation.
(c)
Interpretation:
The reductants and oxidants of fatty acid synthesis and degradation must be compared.
Concept introduction:
The fatty acids are degraded in a sequential manner, that is, two carbon units at the carboxyl end of the molecule are removed in each step. The process of beta-oxidation of fatty acids degrades the fatty acids. The process of fatty acid synthesis is a stepwise process, which occurs by the addition of two-carbon units. These carbon units are provided by the acetyl-CoA, derived from glucose oxidation.
(d)
Interpretation:
The stereochemistry of intermediates of fatty acid synthesis and degradation must be compared.
Concept introduction:
The fatty acids are degraded in a sequential manner, that is, two carbon units at the carboxyl end of the molecule are removed in each step. The process of beta-oxidation of fatty acids degrades the fatty acids. The process of fatty acid synthesis is a stepwise process, which occurs by the addition of two-carbon units. These carbon units are provided by the acetyl-CoA, derived from glucose oxidation.
(e)
Interpretation:
The direction of fatty acid synthesis and degradation must be compared.
Concept introduction:
The fatty acids are degraded in a sequential manner, that is, two carbon units at the carboxyl end of the molecule are removed in each step. The process of beta-oxidation of fatty acids degrades the fatty acids. The process of fatty acid synthesis is a stepwise process, which occurs by the addition of two-carbon units. These carbon units are provided by the acetyl-CoA, derived from glucose oxidation.
(f)
Interpretation:
The organization of the enzyme system of fatty acid synthesis and degradation must be compared.
Concept introduction:
The fatty acids are degraded in a sequential manner, that is, two carbon units at the carboxyl end of the molecule are removed in each step. The process of beta-oxidation of fatty acids degrades the fatty acids. The process of fatty acid synthesis is a stepwise process, which occurs by the addition of two-carbon units. These carbon units are provided by the acetyl-CoA, derived from glucose oxidation.
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Chapter 22 Solutions
BIOCHEMISTRY-ACHIEVE (1 TERM)
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- A7. Consider what can be concluded about the catalytic site (substrate binding site) of phosphatase and the binding site of NaF from the type of inhibition shown by NaF for phosphatase and illustrate it schematically. The inhibition typre is pure noncompetitive inhibition.arrow_forwardDraw Gluconeogenesis. Please make sure to state all the enzymes and co-factors for each step of the pathway. note you are responsible for all the enzymes for each step, even though it is not stated on the slide.arrow_forwarda. Use the values in Problem 23.31 to calculate the energy change in the following reaction. fructose 1,6-bisphosphate + ADP--------> fructose 6-phosphate + ATP b. Is this reaction energetically favorable or unfavorable? c. Write this reaction using curved arrow symbolism. d. Can this reaction be used to synthesize ATP from ADP? Explain.arrow_forward
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