Carbamoyl phosphate synthetase III explained
Carbamoyl phosphate synthetase III (CPS III) is one of the three isoforms of the carbamoyl phosphate synthetase, an enzyme that catalyzes the active production of carbamoyl phosphate in many organisms.
CPS III (EC 6.3.5.5.) is a ligase (3.) that forms carbon-nitrogen bonds (6.3.) with glutamine as amido-N-donor (6.3.5.) (see BRENDA).
Context
Many aquatic organisms, including most of the fish species, are ammoniotelic, which means they produce ammonia as metabolic waste, that they generally excrete by diffusion through their gills. Similar to terrestrial vertebrates, some fish species also significantly include urea as metabolic waste. This phenomenon concerns larvae stages since they do not have gills to excrete ammonia from, but also the adult stage in some species. Based on the proportion of metabolic waste represented by urea, these species are partial or fully ureotelic.
Ureotelic species produce urea via the ornithine-urea cycle (OUC) in which CPS plays an important role. Carbamoyl phosphate synthetase I is mostly used by terrestrial vertebrates, and it appears that some aquatic species rely on CPS III to deal with urea production.[1] There are several potential advantages in excreting urea instead of ammonia for species living in specific environments. For example, it allows a better diffusion capacity than ammonia in alkaline waters,[2] and it decreases water loss, which can be crucial for species experiencing long periods out of the water such as lungfish species.[3] CPS III has been described in cichlids of the Alcolapia genus, lungfishes,[4] [5] the Gulf toadfish Opsanus beta,[6] the rainbow trout Oncorhyncus mykiss,[7] [8] the Atlantic halibut Hippoglossus hippoglossus,[9] the largemouth bass Micropterus salmoides,[10] the common carp Cyprinus carpio,[11] and in elasmobranchs such as the spiny dogfish Squalus acanthia[12] [13] for example. This enzyme thus seems to be distributed among fish showing different degree of ureotely.
Reaction pathway
Ornithine-urea cycle
CPS III is a precursor in the ornithine-urea cycle (OUC). This pathway occurs in organisms which do not directly excrete ammonia as a catabolic waste. The main function of the OUC is to convert highly toxic nitrogen waste (NH3) in urea, which shows less toxicity. This cycle includes five biochemical reactions, the first two of which occur in the mitochondrial matrix and the three others in the cytosol. In fishes, the urea cycle is only found in a few teleosts, mostly air breeders or species living in very specific environments such as alkaline water,[14] and in elasmobranchs.
CPS III is found in the mitochondria of some elasmobranch and in a few teleosts liver and/or extrahepatic tissues. It intervenes in the first reaction of the cycle of the OUC, which is crucial since it limits the rest of the cycle. CPS III thus plays a major role in regulating the amount of ammonia in the cell, by starting its conversion in urea for excretion while maintaining a minimum concentration to maintain amino acids synthesis.
Carbamoyl phosphate synthesis
The reaction catalyzed by CPS III is:[15] 2 ATP + -glutamine + HCO3- + H2O → 2 ADP + Pi + -glutamate + carbamoyl phosphate
This reaction occurs in the mitochondrial matrix and includes four steps:
- Bicarbonate (HCO3−) is phosphorylated using an ATP, generating carboxyphosphate (CHO6P2-)
- Glutamine (C5H10N2O3) is hydrolyzed into glutamate (C5H9NO4) and ammonia (NH3). 1. and 2. occur concurrently.
- Nucleophilic substitution of the ammonia on carboxyphosphate (substituting the -OH group by a -NH2 group) generating the intermediate product carbamate (CH2NO2−)
- Nucleophilic substitution of the carbamate on a second ATP, generating the product carbamoyl phosphate .
CPS III, like CPS I, shows N-acetylglutamate dependence, which means that this allosteric effector is required to perform the catalysis.
Structure
CPS III is composed of two subunits: a synthetase and a glutaminase. These two subunits seem to be fused by the N-terminal end of the synthetase[16] (Hong et al., 1994)
The 38 first amino acids of the sequence (N-terminal sequence) represent a mitochondrial signal sequence to signal import in the mitochondria.
The glutaminase subunit is located between Phe39 and Ile407 and is itself divided into two domains: an N-terminal domain between Phe39 and Asp165, and a C-terminal glutamine amide transferase domain (GAT) located between Thr166 and Ile407. The cysteine residue Cyst294 along with three histidine residues Hist337, Hist367, and Hist378, have been identified as crucial for the glutamine-dependent activity. In other words, these residues allow CPS III to use glutamine as a substrate.
The synthetase subunit stretches from Lys425 to Gln15032 (C-terminal end) and is also composed of two domains. The first one is located between Lys425 and Ile977 and the second one between Met978 and Gln1502. Each may contain an ATP binding site located between Arg719 and Asp768, and between Arg1260 and Ile1304. It is believed that the C-terminal region contains the binding site for the fixation of the allosteric effector N-acetylglutamate (NAG) which is required for CPS III to function. Two cysteines Cys1328 and Cys1338 have been identified in CPS I, which also use NAG as an allosteric effector, but not in CPS II, which activity is not affected by NAG. Thus, these two cysteine residues appear to probably play a crucial role in the allosteric activity of CPS III.
Evolution and relationship with CPS I and CPS II
CPS III is closer to CPS I than CPS II. These two enzymes work the same way and use the same allosteric effector. The difference between them is that CPS III uses glutamine as substrate while CPS I use ammonia.
It is believed that these enzymes evolved from each other. One hypothesis is that CPS II appeared first after the fusion of genes coding for a glutaminase and an ammonia-dependent synthetase. CPS III would then result from the duplication of the glutaminase sequence, creating a second glutamine binding site that evolved into the N-acetylglutamate allosteric site. The last type, CPS I would be the last one to appear after evolving in using ammonia as substrate instead of glutamine.[17] [18]
Notes and References
- Anderson PM . 3 Urea Cycle in Fish: Molecular and Mitochondrial Studies. January 1995 . Fish Physiology. 14. 57–83. Wood CM, Shuttleworth TJ . Academic Press. 10.1016/s1546-5098(08)60242-3 . 9780123504388.
- White LJ, Sutton G, Shechonge A, Day JJ, Dasmahapatra KK, Pownall ME . Adaptation of the carbamoyl-phosphate synthetase enzyme in an extremophile fish . Royal Society Open Science . 7 . 10 . 201200 . October 2020 . 33204476 . 7657897 . 10.1098/rsos.201200 . 2020RSOS....701200W.
- Chew SF, Ong TF, Ho L, Tam WL, Loong AM, Hiong KC, Wong WP, Ip YK . 6 . Urea synthesis in the African lungfish Protopterus dolloi--hepatic carbamoyl phosphate synthetase III and glutamine synthetase are upregulated by 6 days of aerial exposure . The Journal of Experimental Biology . 206 . Pt 20 . 3615–24 . October 2003 . 12966053 . 10.1242/jeb.00619 . 9687376. free .
- Laberge T, Walsh PJ . Phylogenetic aspects of carbamoyl phosphate synthetase in lungfish: a transitional enzyme in transitional fishes . Comparative Biochemistry and Physiology. Part D, Genomics & Proteomics . 6 . 2 . 187–94 . June 2011 . 21482211 . 10.1016/j.cbd.2011.03.001.
- Loong AM, Chng YR, Chew SF, Wong WP, Ip YK . Molecular characterization and mRNA expression of carbamoyl phosphate synthetase III in the liver of the African lungfish, Protopterus annectens, during aestivation or exposure to ammonia . Journal of Comparative Physiology B: Biochemical, Systemic, and Environmental Physiology . 182 . 3 . 367–79 . April 2012 . 22038021 . 10.1007/s00360-011-0626-7 . 6766714.
- Kong H, Kahatapitiya N, Kingsley K, Salo WL, Anderson PM, Wang YS, Walsh PJ . Induction of carbamoyl phosphate synthetase III and glutamine synthetase mRNA during confinement stress in gulf toadfish (Opsanus beta) . The Journal of Experimental Biology . 203 . Pt 2 . 311–20 . January 2000 . 10607541 . 10.1242/jeb.203.2.311. free .
- Korte JJ, Salo WL, Cabrera VM, Wright PA, Felskie AK, Anderson PM . Expression of carbamoyl-phosphate synthetase III mRNA during the early stages of development and in muscle of adult rainbow trout (Oncorhynchus mykiss) . The Journal of Biological Chemistry . 272 . 10 . 6270–7 . March 1997 . 9045644 . 10.1074/jbc.272.10.6270 . free.
- Todgham AE, Anderson PM, Wright PA . Effects of exercise on nitrogen excretion, carbamoyl phosphate synthetase III activity and related urea cycle enzymes in muscle and liver tissues of juvenile rainbow trout (Oncorhynchus mykiss) . Comparative Biochemistry and Physiology. Part A, Molecular & Integrative Physiology . 129 . 2–3 . 527–39 . June 2001 . 11423323 . 10.1016/S1095-6433(01)00290-2.
- Terjesen BF, Rønnestad I, Norberg B, Anderson PM . Detection and basic properties of carbamoyl phosphate synthetase III during teleost ontogeny: a case study in the Atlantic halibut (Hippoglossus hippoglossus L.) . Comparative Biochemistry and Physiology. Part B, Biochemistry & Molecular Biology . 126 . 4 . 521–35 . August 2000 . 11026664 . 10.1016/S0305-0491(00)00221-2.
- Kong H, Edberg DD, Korte JJ, Salo WL, Wright PA, Anderson PM . Nitrogen excretion and expression of carbamoyl-phosphate synthetase III activity and mRNA in extrahepatic tissues of largemouth bass (Micropterus salmoides) . Archives of Biochemistry and Biophysics . 350 . 2 . 157–68 . February 1998 . 9473289 . 10.1006/abbi.1997.0522.
- Felskie AK, Anderson PM, Wright PA . 1998-02-01. Expression and Activity of Carbamoyl Phosphate Synthetase III and Ornithine Urea Cycle Enzymes in Various Tissues of Four Fish Species . Comparative Biochemistry and Physiology. Part B, Biochemistry & Molecular Biology. 119. 2. 355–364. 10.1016/S0305-0491(97)00361-1. 1096-4959.
- Hong J, Salo WL, Chen Y, Atkinson BG, Anderson PM . The promoter region of the carbamoyl-phosphate synthetase III gene of Squalus acanthias . Journal of Molecular Evolution . 43 . 6 . 602–9 . December 1996 . 8995057 . 10.1007/BF02202108 . 1996JMolE..43..602H . 6835045.
- Chana-Munoz A, Jendroszek A, Sønnichsen M, Kristiansen R, Jensen JK, Andreasen PA, Bendixen C, Panitz F . 6 . Multi-tissue RNA-seq and transcriptome characterisation of the spiny dogfish shark (Squalus acanthias) provides a molecular tool for biological research and reveals new genes involved in osmoregulation . PLOS ONE . 12 . 8 . e0182756 . 2017-08-23 . 28832628 . 5568229 . 10.1371/journal.pone.0182756 . 2017PLoSO..1282756C . free.
- Randall DJ, Wood CM, Perry SF, Bergman H, Maloiy GM, Mommsen TP, Wright PA . Urea excretion as a strategy for survival in a fish living in a very alkaline environment . Nature . 337 . 6203 . 165–6 . January 1989 . 2911349 . 10.1038/337165a0 . 1989Natur.337..165R . 4272256.
- Holden HM, Thoden JB, Raushel FM . Carbamoyl phosphate synthetase: an amazing biochemical odyssey from substrate to product . Cellular and Molecular Life Sciences . 56 . 5–6 . 507–22 . October 1999 . 11212301 . 10.1007/s000180050448 . 23446378. 11147029 .
- Hong J, Salo WL, Lusty CJ, Anderson PM . Carbamyl phosphate synthetase III, an evolutionary intermediate in the transition between glutamine-dependent and ammonia-dependent carbamyl phosphate synthetases . Journal of Molecular Biology . 243 . 1 . 131–40 . October 1994 . 7932737 . 10.1006/jmbi.1994.1638 .
- Devaney MA, Powers-Lee SG . Immunological cross-reactivity between carbamyl phosphate synthetases I, II, and III . The Journal of Biological Chemistry . 259 . 2 . 703–6 . January 1984 . 10.1016/S0021-9258(17)43514-9 . 6363405 . free .
- Lindley TE, Laberge T, Hall A, Hewett-Emmett D, Walsh PJ, Anderson PM . Sequence, expression and evolutionary relationships of carbamoyl phosphate synthetase I in the toad Xenopus laevis . Journal of Experimental Zoology Part A: Ecological Genetics and Physiology . 307 . 3 . 163–75 . March 2007 . 17397070 . 10.1002/jez.a.364 .