Chapt. 39 Ch. 39 Student Learning Outcomes : Explain basic synthesis of nonessential amino acids...
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Chapt. 39 Ch. 39 Student Learning Outcomes: •Explain basic synthesis of nonessential amino acids • Uses glucose derivatives (glycolysis, TCA) • N sources often other aa •Describe important cofactors: • PLP (from Vitamin B6) for transaminations • FH 4 (tetrahydrofolate) for 1C; • BH 4 (tetrahydrobiopterin) for hydroxylation •(Phe → Tyr) •Explain general regulation of amino acid synthesis (feedback inhibition, transcription inhibition) • Degradation of aa often distinct from synthesis path
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Overview Degradation of amino acids Fig. 2 Overview: degradation of amino acids: A.Gluconeogenic: Pyruvate, TCA intermediates B. Ketogenic: Acetyl CoA, ketone bodies
Transcript of Chapt. 39 Ch. 39 Student Learning Outcomes : Explain basic synthesis of nonessential amino acids...
Chapt. 39
Ch. 39Student Learning Outcomes:• Explain basic synthesis of nonessential amino acids
• Uses glucose derivatives (glycolysis, TCA)• N sources often other aa
• Describe important cofactors:• PLP (from Vitamin B6) for transaminations• FH4 (tetrahydrofolate) for 1C; • BH4 (tetrahydrobiopterin) for hydroxylation
• (Phe → Tyr)• Explain general regulation of amino acid synthesis
(feedback inhibition, transcription inhibition)• Degradation of aa often distinct from synthesis path
Overview synthesis of nonessential amino acids
Fig. 39.1*
Overview synthesis of nonessential amino acids:• Met donates the S to Cys• C skeletons come from glucose, glycolysis, TCA compounds• Aa that can be synthesized are often used for other N cmpds:
• Gly → purine, pyrimidine• Asp → purine, pyrimidine• Gln → neurotransmitter
Overview Degradation of amino acids
Fig. 2
Overview: degradation of amino acids:A.Gluconeogenic: Pyruvate, TCA intermediatesB. Ketogenic: Acetyl CoA, ketone bodies
Some genetic disorders of amino acid metabolismDegradation path enzyme disease symptomsPhe phe hydroxylase (PAH) PKU classic mental retardation
homogentisate oxidase alcaptonuria black urine, arthritis
Tyr fumarylacetoacetate hydrolase tyrosinemia I liver failure, deathtyrosine aminotransferase tyrosinemia II neurological
Met cystathionase cystathionuria benigncystathionine b-synthase homocystinemia cardiovascular, neurological
Gly glycine transaminase oxaluria type 1 renal failure (Gly → oxalate) Ca-oxalate stones
Metabolism of Phe/Tyr
Fig. 39.15
Phe and Tyr:• PKU from absence PAH (autosomal
recessive); 1/104 births; all babies tested;give special diet of low Phe (essential aa)
High Phe in blood → neurological
• Tyr is made from Phevarious defects in degradation
neurological, liver failure
Cysteine metabolism
Figs. 39.6 Cys
Cysteine metabolism:• C, N from Ser, S from Met• Met donates S to Cys via Homocys
• Removal of –CH3
• Cystathionine precursor of Cys• Feedback regulation of synthase
• Adjust for dietary Cys• Lack of synthase → homocyst(e)inemia
