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Transcript
3/30/2017 Nitrogen Metabolism Pratt and Cornely Chapter 18 Overview • Nitrogen assimilation • Amino acid biosynthesis – Nonessential aa – Essential aa • Nucleotide biosynthesis • Amino Acid Catabolism • Urea Cycle Juicy Steak Part 2 1 3/30/2017 Nitrogen fixation • Bacteria • Nitrogenase • Costly—16 ATP per N2 molecule Assimilation into Amino Acids • In microorganisms/plants: assimilation of ammonia is key—synthesis of most amino acids – Glutamine synthetase incorporates amino group – Coupled to glutamate synthase: reductive amination of ‐ketoglutarate to glutamate 2 3/30/2017 Net Reaction • ‐KG + NH3 +ATP + NADPH Glu + ADP + NADP+ • Ultimately, this is incorporation of ammonia into an amino acid • Glutamate can then be used to distribute nitrogen into other amino acids (transamination) Assimilation into Amino Acids • In humans: acquire nitrogen in amino acids – Amino acids in diet – Glutamate distributes amino group to new amino acids through transamination – No need for glutamate synthase – Glutamine synthetase used for different purpose: to “mop up” ammonia 3 3/30/2017 Transamination • Transfers assimilated nitrogen into all other amino acids • Requires PLP cofactor 4 3/30/2017 Biosynthesis • Dietary consideration • Ambiguous – Stage of life (Arg) – Precursor (Tyr, Cys) • Mechanism of biosynthesis can be grouped Amino Acid Biosynthesis * * * * * * * * * * * 5 3/30/2017 Non‐essential Amino Acid Biosynthesis • Transamination – Pyruvatealanine – Oxaloacetateaspartate – ‐ketoglutarateglutamate • Amidation – Glutamine (glutamine synthetase) – Asparagine (asparagine synthetase) Glutamate Backbone 6 3/30/2017 Serine/Glycine • 3‐phosphoglycerate Serine • Serineglycine – THF as a major one‐carbon transfer vitamin 7 3/30/2017 Cysteine • Serinecysteine by incorporating sulfur from homocysteine (Made from methionine) 8 3/30/2017 Phenylalanine • Monooxygenase uses O2 for hydroxylation – Other atom ends up in water – Requires a reducing cofactor called tetrahydrobiopterin • Also first step in catabolism of phenylalanine – PKU Neurotransmitters • Which amino acid? 9 3/30/2017 Nucleotide Biosynthesis • 5‐PRPP • Purine: base built onto ribose – Asp, Gly, Glu, THF, bicarbonate • IMP produced AMP/GMP Production • Branched pathway • AMP: amination • GMP: oxidation • Branch allows for reciprocal regulation 10 3/30/2017 Pyrimidines • Contrast • Base made first, then attached to 5PRPP • Not branched: UMP made to UTP then to CTP Ribonucleotide Reductase • Essential reaction: reduction to make dNDP • Very difficult reaction • Free radical • Enzyme is oxidized in the process – Reduced by thioredoxin – In turn, thioredoxin reduced by NADPH 11 3/30/2017 Production of TMP • dUTP must be converted to TMP quickly • Methylene donated from THF by thymidylate synthase • THF oxidized to DHF • Chemotherapy: dUMP analog 12 3/30/2017 Regenerating THF • DHF must be reduced to THF by DHF reductase • NADPH dependent • Chemotherapy target – DHF analogs such as methotrexate Catabolism • Salvage pathway through phosphorolysis • Purines made into uric acid (waste) • Pyrimidines broken down into catabolic intermediates 13 3/30/2017 Amino acid catabolism Ketogenic vs. Glucogenic 14 3/30/2017 Problem 35 • The catabolic pathways for the 20 amino acids vary considerably, but all amino acids are degraded to one of seven metabolites: pyruvate, ‐ketoglutarate, succinyl‐CoA, fumarate, oxaloacetate, acetyl CoA, or acetoacetate. What is the fate of each of these metabolites? 15 3/30/2017 Amino Acid Degradation • Transamination and deamination • Then carbon chain is metabolized • Examples: Pyruvate Producing A variety of enzymes convert 3‐C chains 16 3/30/2017 Glutamate Family • 25% of dietary intake Thr: Both Glucogenic and Ketogenic Many mammals: or aminoacetone pyruvate In humans: 17 3/30/2017 Glycine Cleavage system Branched Amino Acids • Major energy source in muscle • Steps of degradation – Transamination – Oxidative decarboxylation (Pyruvate DH) – Beta oxidation • Valine: succinyl CoA • Isoleucine: succinyl CoA and acetylCoA • Leucine: acetyl CoA and ketone body 18 3/30/2017 Problem 40 • Leucine is degraded to acetyl CoA and acetoacetate by a pathway whose first two steps are identical to those of valine degradation (Figure 18‐11). The third step is the same as the first step of fatty acid oxidation. The fourth step involves an ATP‐ dependent carboxylation, the fifth step is a hydration, and the last step is a cleavage reaction to give products. Draw the intermediates of leucine degradation. 19 3/30/2017 Aromatic Amino Acids • Monoxygenases and Dioxygenases • First recognition of inborn errors of metabolism Problem51 • List all the reactions in this chapter that generate free ammonia. 20 3/30/2017 Ammonia Processing • Most tissues: glutamine synthetase “mops up” ammonium generated in metabolism – glutamine then sent through blood to liver – Deaminated in liver to give glutamic acid • glutaminase Ammonia Processing • Muscle: The alanine‐glucose cycle • Glutamate also accepts amino group from other amino acids 21 3/30/2017 Glutamate Dehydrogenase • Reversible reaction • Grabs free ammonia and releases it in liver mitochondria Role of Liver Mitochondia • Sequester toxic ammonia • Make less toxic, execrable form • Urea Cycle bicarbonate O H2N ammonia (f rom glutamate) NH2 aspartate (can be derived f rom glutamate via transmination) 22 3/30/2017 Carbamoyl phosphate • Cost of 2 ATP – Phosphate leaving group • Activation of ammonia for – Excretion – biosynthesis Problem 52 • Which three mammalian enzymes can potentially “mop up” excess NH4+? 23 3/30/2017 Urea Cycle Chemistry of Urea Cycle • Catalytic ornithine + ATP + AMP • Fumarate • Urea = 4 ATP 24 3/30/2017 Compartmentalization Urea Cycle Regulation • Carbamoyl phosphate synthetase • Amino acid catabolism boosts acetyl CoA and glutamate levels • Produces activator 25 3/30/2017 Problem 55 • An inborn error of metabolism results in the deficiency of argininosuccinase. What could be added to the diet to boost urea production aid in ammonia secretion? (Argininosuccinate can be excreted.) Solving Metabolic Problems • Arginosuccinase deficiency • Low protein diet – Minimize ammonium excreted • High arginine diet – Provide carrier X 26 3/30/2017 Nitrogen Flow Overview Summary: Main Players • Glutamate: in liver, receives nitrogen from AA, then ammonia is released in liver mitochondria • Glutamine: ammonia transport; biosynthesis • Alanine: ammonia transport • Aspartate: nitrogen donor to urea • Arginine: urea cycle 27
