N-Acetylglutamate synthase

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N-Acetylglutamate synthase
File:4kzt.jpg
N-acetylglutamate synthase/kinase tetramer, Maricaulis maris
Identifiers
SymbolNAGS
Entrez162417
HUGO17996
OMIM608300
RefSeqNM_153006
UniProtQ8N159
Other data
EC number2.3.1.1
LocusChr. 17 q21.31

N-acetylglutamate synthase (NAGS) is an enzyme that catalyses the production of N-Acetylglutamate (NAG) from glutamate and acetyl-CoA.

Put simply NAGS catalyzes the following reaction:

acetyl-CoA + L-glutamate → CoA + N-acetyl-L-glutamate

NAGS, a member of the N-acetyltransferase family of enzymes, is present in both prokaryotes and eukaryotes, although its role and structure differ widely depending on the species. NAG can be used in the production of ornithine and arginine, two important amino acids, or as an allosteric cofactor for carbamoyl phosphate synthase (CPS1). In mammals, NAGS is expressed primarily in the liver and small intestine, and is localized to the mitochondrial matrix.[1]

File:N-Acetylglutamate Synthase Chemical Equation.png
Overall reaction scheme for N-acetylglutamate (NAG) synthesis via N-acetylglutamate synthase (NAGS)

Biological function

Most prokaryotes (bacteria) and lower eukaryotes (fungi, green algae, plants, etc.) produce NAG through orinithine acetyltransferase (OAT), which is part of a ‘cyclic’ ornithine production pathway. NAGS is therefore used in a supportive role, replenishing NAG reserves as required. In some plants and bacteria, however, NAGS catalyzes the first step in a ‘linear’ arginine production pathway.[2]

The protein sequences of NAGS between prokaryotes, lower eukaryotes and higher eukaryotes have shown a remarkable lack of similarity. Sequence identity between prokaryotic and eukaryotic NAGS is largely <30%,[3] while sequence identity between lower and higher eukaryotes is ~20%.[4]

Enzyme activity of NAGS is modulated by L-arginine, which acts as an inhibitor in plant and bacterial NAGS, but an effector in vertebrates.[5][6] While the role of arginine as an inhibitor of NAG in ornithine and arginine synthesis is well understood, there is some controversy as to the role of NAG in the urea cycle.[7][8] The currently accepted role of NAG in vertebrates is as an essential allosteric cofactor for CPS1, and therefore it acts as the primary controller of flux through the urea cycle. In this role, feedback regulation from arginine would act to signal NAGS that ammonia is plentiful within the cell, and needs to be removed, accelerating NAGS function. As it stands, the evolutionary journey of NAGS from essential synthetic enzyme to primary urea cycle controller is yet to be fully understood.[9]

Mechanism

File:Reaction mechanism for N-acetylglutamate synthase.png
A simplified reaction mechanism for N-Acetylglutamate synthase (NAGS)

Two mechanisms for N-acetyltransferase function have been proposed: a two-step, ping-pong mechanism involving transfer of the relevant acetyl group to an activated cysteine residue[10] and a one-step mechanism through direct attack of the amino nitrogen on the carbonyl group.[11] Studies conducted using NAGS derived from Neisseria gonorrhoeae suggest that NAGS proceeds through the previously described one-step mechanism.[12] In this proposal, the carbonyl group of acetyl-CoA is attacked directly by the α-amino nitrogen of glutamate. This mechanism is supported by the activation of the carbonyl through hydrogen bond polarization, as well as the absence of a suitable cysteine within the active site to act as an intermediate acceptor of the acetyl group.[13][14]

Clinical significance

Inactivity of NAGS results in N-acetylglutamate synthase deficiency, a form of hyperammonemia.[15] In many vertebrates, N-acetylglutamate is an essential allosteric cofactor of CPS1, the enzyme that catalyzes the first step of the urea cycle.[16] Without NAG stimulation, CPS1 cannot convert ammonia to carbamoyl phosphate, resulting in toxic ammonia accumulation.[17] Carbamoyl glutamate has shown promise as a possible treatment for NAGS deficiency.[15] This is suspected to be a result of the structural similarities between NAG and carabamoyl glutamate, which allows carbamoyl glutamate to act as an effective agonist for CPS1.[14]

References

  1. A.J Meijer, C Lof, I.C Ramos, A.J Verhoeven, "Control of ureagenesis", Eur. J. Biochem., 148 (1985), pp. 189–196
  2. Cunin, R., Glansdorff, N., Pierard, A. and Stalon, V. (1986) Biosynthesis and metabolism of arginine in bacteria. Microbiol. Rev. 50, 314–352
  3. Yu, Y. G., Turner, G. E. and Weiss, R. L. (1996) Acetylglutamate synthase from Neurospora crassa: structure and regulation of expression. Mol. Microbiol. 22, 545–554
  4. Caldovic, L., Mew, N. A., Shi, D., Morizono, H., Yudkoff, M., and Tuchmana, M. (2010) N-acetylglutamate synthase: structure, function and defects. Mol. Genet. Metab. 100(Suppl 1): S13–S19
  5. J Cybis, R.H Davis, Organization and control in the arginine biosynthetic pathway of Neurospora. J. Bacteriol., 123 (1975), pp. 196–202
  6. T Sonoda, M Tatibana, Purification of N-acetyl-l-glutamate synthetase from rat liver mitochondria and substrate and activator specificity of the enzyme. J. Biol. Chem., 258 (1983), pp. 9839–9844
  7. Meijer, A. J. and Verhoeven, A. J. (1984) N-Acetylglutamate and urea synthesis. Biochem. J. 223, 559–560
  8. Lund, P. and Wiggins, D. (1984) Is N-acetylglutamate a short-term regulator of urea synthesis? Biochem. J. 218, 991–994
  9. Caldovic, L., Tuchman, M., N-Acetylglutamate and its changing role through evolution. Biochem. J. (2003) 372 (279–290) doi:10.1042/BJ20030002
  10. Wong L. J., Wong S. S. Kinetic mechanism of the reaction catalyzed by nuclear histone acetyltransferase from calf thymus. Biochemistry. 1983 Sep 27;22(20):4637-41.
  11. Dyda, F., Klein, D. C., and Hickman, A. B. (2000) Annu. Rev. Biophys. Biomol. Struct. 29, 81-103
  12. Shi, D., Sagar, V., Jin, Z., Yu, X., Caldovic, L., Morizono, H., Allewell, N. M. and Tuchman, M. (2008) The Crystal Structure of N-Acetyl-L-glutamate Synthase from Neisseria gonorrhoeae Provides Insights into Mechanisms of Catalysis and Regulation. J. Bio. Chem. 283, 7176-7184
  13. Min, L., Jin, Z., Caldovic, L., Morizono, H., Allewell, N. M., Tuchman, M. and Shi, D. Mechanism of Allosteric Inhibition of N-Acetyl-L-glutamate Synthase by L-Arginine. J. Bio. Chem. 284, 4873-4880
  14. 14.0 14.1 Morizono, H., Caldovic, L., Shi, D. and Tuchman, M. Mammalian N-Acetylglutamate synthase. Mol Genet Metab. 2004 April; 81(Suppl 1): S4–11.
  15. 15.0 15.1 Caldovic, L., Morizono, H., Panglao, M. G., Cheng, S. F., Packman, S. and Tuchman, M. Null mutations in the N-acetylglutamate synthase gene associated with acute neonatal disease and hyperammonemia. Hum. Gen. April 2003, Vol. 112, 4, pp 364-368
  16. McCudden, C. R. and Powers-Lee, S. G. Required Allosteric Effector Site for N-Acetylglutamate on Carbamoyl-Phosphate Synthetase I. J. Bio. Chem. 271, 18285-18294
  17. Caldovic, L., Morizono, H., Daikhin, Y., Nissim, I., McCarter, R. J., Yudkoff, M. and Tuchman, M. Restoration of ureagenesis in N-acetylglutamate synthase deficiency by N-carbamylglutamate. J. Ped. Vol. 145, 4, October 2004, 552–554
  • Lehninger principles of biochemistry, 4th edition, David L. Nelson, Michael M. Cox

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