Malate synthase
malate synthase | |||||||||
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Identifiers | |||||||||
EC no. | 2.3.3.9 | ||||||||
CAS no. | 9013-48-3 | ||||||||
Databases | |||||||||
IntEnz | IntEnz view | ||||||||
BRENDA | BRENDA entry | ||||||||
ExPASy | NiceZyme view | ||||||||
KEGG | KEGG entry | ||||||||
MetaCyc | metabolic pathway | ||||||||
PRIAM | profile | ||||||||
PDB structures | RCSB PDB PDBe PDBsum | ||||||||
Gene Ontology | AmiGO / QuickGO | ||||||||
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In enzymology, a malate synthase (EC 2.3.3.9) is an enzyme that catalyzes the chemical reaction
- acetyl-CoA + H2O + glyoxylate (S)-malate + CoA
The 3 substrates of this enzyme are acetyl-CoA, H2O, and glyoxylate, whereas its two products are (S)-malate and CoA. This enzyme participates in pyruvate metabolism and glyoxylate and dicarboxylate metabolism.
Nomenclature
This enzyme belongs to the family of transferases, specifically acyltransferases that convert acyl groups into alkyl groups on transfer. The systematic name of this enzyme class is acetyl-CoA:glyoxylate C-acetyltransferase (thioester-hydrolysing, carboxymethyl-forming). Other names in common use include L-malate glyoxylate-lyase (CoA-acetylating), glyoxylate transacetylase, glyoxylate transacetase, glyoxylic transacetase, malate condensing enzyme, malate synthetase, malic synthetase, and malic-condensing enzyme.
Structure
Malate synthases fall into two major families, isoforms A and G. Isoform G is monomeric with a size of about 80-kD and found exclusively in bacteria.[2] Isoform A is about 65 kD per subunit and can form homomultimers in eukaryotes.[3] This enzyme contains a central TIM barrel sandwiched between an N-terminal alpha-helical clasp and an alpha/beta domain stemming from two insertions into the TIM barrel sequence. The enzyme terminates with a C-terminal five-helix plug. The active site, where the acetyl-CoA and glyoxylate bind to the enzyme, lies between the TIM barrel and C-terminal plug.[4] Upon binding, the acetyl-CoA molecule forms a J-shape inserted into the binding pocket, by an intramolecular hydrogen bond between N7 of the adenine ring and a hydroxyl group on the pantetheine tail.[4] In addition, a critical magnesium ion within the active site coordinates with glyoxylate, glutamic acid 427, aspartic acid 455, and two water molecules.[4] The amino acids interacting with acetyl CoA upon binding are highly conserved.[2] Sequence identity is high within each class of isoforms, but between both classes sequence identity drops to about 15%.[5] The alpha/beta domain, which has no apparent function, is not seen in isoform A.[6]
Mechanism
The mechanism of malate synthase is an aldol reaction followed by thioester hydrolysis. Initially, aspartate 631 acts as a catalytic base, abstracting a proton from the alpha carbon of acetyl-CoA and creating an enolate that is stabilized by arginine 338.[6] This is considered to be the rate-determining step of the mechanism.[7] Then, the newly formed enolate acts as a nucleophile that attacks the aldehyde of glyoxylate, imparting a negative charge on the oxygen which is stabilized by arginine 338 and the coordinating magnesium cation. This malyl-CoA intermediate then undergoes hydrolysis at the acyl-CoA portion, generating a carboxylate anion.[2] The enzyme finally releases malate and coenzyme A.
Function
The citric acid cycle (also known as the tricarboxylic acid cycle or the Krebs cycle) is used by aerobic organisms to produce energy via the oxidation of acetyl-CoA, which is derived from pyruvate (a product of glycolysis). The citric acid cycle accepts acetyl-CoA and metabolizes it to form carbon dioxide. A related cycle, called the glyoxylate cycle, is found in many bacteria and plants. In plants, the glyoxylate cycle takes place in glyoxysomes.[8] In this cycle, isocitrate lyase and malate synthase skip over the decarboxylation steps of the citric acid cycle. In other words, malate synthase works together with isocitrate lyase in the glyoxylate cycle to bypass two oxidative steps of Krebs cycle and permit carbon incorporation from acetate or fatty acids in many microorganisms.[9] Together, these two enzymes serve to produce succinate (which exits the cycle to be used for synthesis of sugars) and malate (which remains in the glyoxylate cycle). During this process, acetyl-CoA and water are used as substrates. As a result, the cell does not lose 2 molecules of carbon dioxide as it does in the Krebs cycle. The glyoxylate cycle, facilitated by malate synthase and isocitrate lyase, allows plants and bacteria to subsist on acetyl-CoA or other two carbon compounds. For example, Euglena gracilis, a single-celled eukaryotic alga, consumes ethanol to form acetyl-CoA and subsequently, carbohydrates.[10] Within germinating plants, the glyoxylate cycle allows the conversion of reserve lipids into carbohydrates within glyoxysomes.[11]
Evolutionary history
Malate synthase is found as an octamer of identical subunits (each roughly 60kDa) in some plants, including maize. It is found as a homotetramer in the fungus Candida and as a homodimer in eubacteria. Malate synthase is fused to the C-terminus of isocitrate lyase in C. elegans, resulting in a single bifunctional protein. While there is currently not sufficient sequence information to determine the exact evolutionary history of malate synthase, plant, fungal, and C. elegans sequences are distinct and show no homologues from archaebacteria.[12]
Activity in humans
Traditionally, malate synthases are described in bacteria as part of the glyoxylate cycle, and malate synthase activity had not been reported for a human protein prior to a study by Strittmatter, et al. In this study, CLYBL was found to be a human mitochondrial enzyme with malate synthase activity. It is found in multiple eukaryotic taxa and is conserved in bacteria. CLYBL differs from other malate synthases in that it lacks a large portion of the C-terminal domain and shows lower specific activity and efficiency.[13] CLYBL is linked to the vitamin B12 metabolism pathway because it is strongly co-expressed with MUT, MMAA, and MMAB, three members of the mitochondrial B12 pathway.[13] Furthermore, a loss of function polymorphism, that leads to a loss of the CLYBL protein, is simultaneously associated with low levels of B12 in human plasma.[13] While the exact mechanism of CLYBL’s involvement in B12 metabolism is not well understood, it is thought to convert citramalyl-CoA into pyruvate and acetyl-CoA. Without this conversion, itaconyl-CoA, a precursor to citramalyl-CoA, builds up in the cell leads to the inactivation of vitamin B12. This inactivation inhibits the methionine cycle, which leads to reduced serine, glycine, one-carbon, and folate metabolism.[14][15]
Clinical significance
Because the glyoxylate cycle occurs in bacteria and fungi, studying the mechanisms of malate synthase (as well as isocitrate lyase) is important for understanding human, animal, and plant pathogenesis. Studying malate synthase can shed light on the metabolic pathways that allow pathogens to survive inside a host as well as elucidate possible treatments.[16] Many studies have been conducted on malate synthase activity in pathogens, including Mycobacterium tuberculosis, Pseudomonas aeruginosa, Brucella melitensis, and Escherichia coli.
Mycobacterium tuberculosis
Malate synthase and the glyoxylate pathway is especially important to M. tuberculosis, allowing long-term persistence of its infection.[2] When cells of M. tuberculosis become phagocytosed, the bacterium upregulates genes encoding the glyoxylate shunt enzymes.[17] Mycobacterium tuberculosis is one of the most well studied pathogens in connection to the enzyme malate synthase. The structure and kinetics of Mycobacterium tuberculosis malate synthase have been well categorized.[18][2] Malate synthase is essential to Mycobacterium tuberculosis survival because it allows the bacteria to assimilate acetyl-CoA into long-chain carbohydrates and survive in harsh environments. Beyond this, malate synthase prevents toxicity from buildup of glyoxylate produced by isocitrate lyase.[19] Downregulation of malate synthase results in reduced stress tolerance, persistence, and growth of Mycobacterium tuberculosis inside macrophages.[20] The enzyme can be inhibited by small molecules (although inhibition is microenvironment dependent), which suggests that these may be used as new chemotherapies.[21]
Pseudomonas aeruginosa
Pseudomonas aeruginosa causes severe infections in humans and is labeled as a critical threat by the World Health Organization because of its resistance to multiple therapies. The glyoxylate shunt is essential for Pseudomonas aeruginosa growth in a host organism. In 2017, McVey, et al. examined the 3D structure of P. aeruginosa malate synthase G. They found that it is a monomer composed of four domains and is highly conserved in other pathogens. They further utilized computational analysis to identify two binding pockets that may serve as drug targets.[22]
Brucella melitensis
Brucella melitensis is a pathogenic bacterium that causes fever and inflammation of the epididymis in sheep and cattle and can be transmitted to humans through the consumption of unpasteurized milk. Malate synthase has been identified as a potential virulence factor in this bacterium. In 2016, Adi, et al. constructed a 3D crystallized structure of the protein to identify catalytic domains and investigate potential inhibitors. They identified five inhibitors with non-oral toxicity that served as drugs against the bacteria, suggesting possible treatment routes for brucellosis.[23]
Escherichia coli
In Escherichia coli, the genes encoding the enzymes required for the glyoxylate cycle are expressed from the polycistronic ace operon. This operon contains genes coding for malate synthase (aceB), isocitrate lyase (aceA), and isocitrate dehydrogenase kinase/phosphatase (aceK).[24]
Structural Studies
As of early 2018, several structures have been solved for malate synthases, including those with PDB accession codes 2GQ3, 1D8C, 3OYX, 3PUG, 5TAO, 5H8M, 2JQX, 1P7T, and 1Y8B.[25]
References
- ^ PDB: 5T8G; Huang HL, Krieger IV, Parai MK, Gawandi VB, Sacchettini JC (December 2016). "Mycobacterium tuberculosis Malate Synthase Structures with Fragments Reveal a Portal for Substrate/Product Exchange". The Journal of Biological Chemistry. 291 (53): 27421–32. doi:10.1074/jbc.m116.750877. PMC 5207166. PMID 27738104.
- ^ a b c d e Smith CV, Huang CC, Miczak A, Russell DG, Sacchettini JC, Höner zu Bentrup K (January 2003). "Biochemical and structural studies of malate synthase from Mycobacterium tuberculosis". The Journal of Biological Chemistry. 278 (3): 1735–43. doi:10.1074/jbc.M209248200. PMID 12393860.
- ^ Durchschlag H, Biedermann G, Eggerer H (February 1981). "Large-scale purification and some properties of malate synthase from baker's yeast". European Journal of Biochemistry. 114 (2): 255–62. doi:10.1111/j.1432-1033.1981.tb05144.x. PMID 7011808.
- ^ a b c Anstrom DM, Kallio K, Remington SJ (September 2003). "Structure of the Escherichia coli malate synthase G:pyruvate:acetyl-coenzyme A abortive ternary complex at 1.95 A resolution". Protein Science. 12 (9): 1822–32. doi:10.1110/ps.03174303. PMC 2323980. PMID 12930982.
- ^ Serrano JA, Bonete MJ (August 2001). "Sequencing, phylogenetic and transcriptional analysis of the glyoxylate bypass operon (ace) in the halophilic archaeon Haloferax volcanii". Biochimica et Biophysica Acta (BBA) - Gene Structure and Expression. 1520 (2): 154–62. doi:10.1016/s0167-4781(01)00263-9. PMID 11513957.
- ^ a b Howard BR, Endrizzi JA, Remington SJ (March 2000). "Crystal structure of Escherichia coli malate synthase G complexed with magnesium and glyoxylate at 2.0 A resolution: mechanistic implications". Biochemistry. 39 (11): 3156–68. doi:10.1021/bi992519h. PMID 10715138.
- ^ Clark JD, O'Keefe SJ, Knowles JR (August 1988). "Malate synthase: proof of a stepwise Claisen condensation using the double-isotope fractionation test". Biochemistry. 27 (16): 5961–71. doi:10.1021/bi00416a020. PMID 2847778.
- ^ Stryer L, Berg JM, Tymoczko JL (2003). Biochemistry (fifth ed.). New York: Freeman. ISBN 978-0-7167-4684-3. OCLC 48055706.
- ^ Kornberg HL, Sadler JR (December 1961). "The metabolism of C2-compounds in micro-organisms. VIII. A dicarboxylic acid cycle as a route for the oxidation of glycollate by Escherichia coli". The Biochemical Journal. 81 (3): 503–13. doi:10.1042/bj0810503. PMC 1243371. PMID 14458448.
- ^ Nakazawa M (2017). "C2 metabolism in Euglena". Euglena: Biochemistry, Cell and Molecular Biology. Advances in Experimental Medicine and Biology. Vol. 979. pp. 39–45. doi:10.1007/978-3-319-54910-1_3. ISBN 978-3-319-54908-8. PMID 28429316.
- ^ Cioni M, Pinzauti G, Vanni P (1981). "Comparative biochemistry of the glyoxylate cycle". Comparative Biochemistry and Physiology B. 70: 1–26. doi:10.1016/0305-0491(81)90118-8.
- ^ Schnarrenberger C, Martin W (February 2002). "Evolution of the enzymes of the citric acid cycle and the glyoxylate cycle of higher plants. A case study of endosymbiotic gene transfer". European Journal of Biochemistry. 269 (3): 868–83. doi:10.1046/j.0014-2956.2001.02722.x. PMID 11846788.
- ^ a b c Strittmatter L, Li Y, Nakatsuka NJ, Calvo SE, Grabarek Z, Mootha VK (May 2014). "CLYBL is a polymorphic human enzyme with malate synthase and β-methylmalate synthase activity". Human Molecular Genetics. 23 (9): 2313–23. doi:10.1093/hmg/ddt624. PMC 3976331. PMID 24334609.
- ^ Shen H, Campanello GC, Flicker D, Grabarek Z, Hu J, Luo C, Banerjee R, Mootha VK (November 2017). "The Human Knockout Gene CLYBL Connects Itaconate to Vitamin B12". Cell. 171 (4): 771–782.e11. doi:10.1016/j.cell.2017.09.051. PMC 5827971. PMID 29056341.
- ^ Reid MA, Paik J, Locasale JW (November 2017). "A Missing Link to Vitamin B12 Metabolism". Cell. 171 (4): 736–737. doi:10.1016/j.cell.2017.10.030. PMID 29100069.
- ^ Dunn MF, Ramírez-Trujillo JA, Hernández-Lucas I (October 2009). "Major roles of isocitrate lyase and malate synthase in bacterial and fungal pathogenesis". Microbiology. 155 (Pt 10): 3166–75. doi:10.1099/mic.0.030858-0. PMID 19684068.
- ^ Höner Zu Bentrup K, Miczak A, Swenson DL, Russell DG (December 1999). "Characterization of activity and expression of isocitrate lyase in Mycobacterium avium and Mycobacterium tuberculosis". Journal of Bacteriology. 181 (23): 7161–7. doi:10.1128/JB.181.23.7161-7167.1999. PMC 103675. PMID 10572116.
- ^ Quartararo CE, Blanchard JS (August 2011). "Kinetic and chemical mechanism of malate synthase from Mycobacterium tuberculosis". Biochemistry. 50 (32): 6879–87. doi:10.1021/bi2007299. PMC 3153559. PMID 21728344.
- ^ Puckett S, Trujillo C, Wang Z, Eoh H, Ioerger TR, Krieger I, Sacchettini J, Schnappinger D, Rhee KY, Ehrt S (March 2017). "Glyoxylate detoxification is an essential function of malate synthase required for carbon assimilation in Mycobacterium tuberculosis". Proceedings of the National Academy of Sciences of the United States of America. 114 (11): E2225–E2232. Bibcode:2017PNAS..114E2225P. doi:10.1073/pnas.1617655114. PMC 5358392. PMID 28265055.
- ^ Singh KS, Sharma R, Keshari D, Singh N, Singh SK (September 2017). "Down-regulation of malate synthase in Mycobacterium tuberculosis H37Ra leads to reduced stress tolerance, persistence and survival in macrophages". Tuberculosis. 106: 73–81. doi:10.1016/j.tube.2017.07.006. PMID 28802408. S2CID 38331939.
- ^ May EE, Leitão A, Tropsha A, Oprea TI (December 2013). "A systems chemical biology study of malate synthase and isocitrate lyase inhibition in Mycobacterium tuberculosis during active and NRP growth". Computational Biology and Chemistry. 47: 167–80. doi:10.1016/j.compbiolchem.2013.07.002. PMC 4010430. PMID 24121675.
- ^ McVey AC, Medarametla P, Chee X, Bartlett S, Poso A, Spring DR, Rahman T, Welch M (October 2017). "Structural and Functional Characterization of Malate Synthase G from Opportunistic Pathogen Pseudomonas aeruginosa". Biochemistry. 56 (41): 5539–5549. doi:10.1021/acs.biochem.7b00852. PMID 28985053.
- ^ Adi PJ, Yellapu NK, Matcha B (December 2016). "Modeling, molecular docking, probing catalytic binding mode of acetyl-CoA malate synthase G in Brucella melitensis 16M". Biochemistry and Biophysics Reports. 8: 192–199. doi:10.1016/j.bbrep.2016.08.020. PMC 5613768. PMID 28955956.
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