Trypanothione synthase

The 3 substrates of this enzyme are glutathione, glutathionylspermidine, and ATP, whereas its 3 products are N1,N8-bis(glutathionyl)spermidine, ADP, and phosphate.^[1]

This reaction is especially important for protozoa in the order kinetoplastida as the molecule of N1,N8-bis(glutathionyl)spermidine, also known as trypanothione, is homologous to the function of glutathione in most other prokaryotic and eukaryotic cells. This means that it is a key intermediate in maintaining thiol redox within the cell and defending against harmful oxidative effects in such protozoa.^[2]

This enzyme belongs to the family of ligases, specifically those forming carbon-nitrogen bonds as acid-D-ammonia (or amine) ligases (amide synthases). The systematic name of this enzyme class is glutathionylspermidine:glutathione ligase (ADP-forming).

Structure

The active bifunctional enzyme of trypanothione synthase is found as a 74.4 KDa monomer consisting of 652 residues with two catalytic domains.^[3]^[4] Its C-terminal domain is a synthetase and has an ATP-grasp family fold that is usually found in carbon-nitrogen ligases. The N-terminal domain is a cysteine, histidine-dependent aminohydrolase amidase. Structurally the synthetase and amidase domains are bound together by three residues of Glu-650-Asp-651-Glu-652 through hydrogen bonding and salt bridge interactions with basic side chains in order for the protein to properly fold. These three residues also block the catalytic Cys-59 in the amidase domain.^[3]

It is currently known that the synthetase active site is shaped in the fashion of a triangular cavity that binds the three substrates such that the end of each molecule is nestled in a vertex of the triangle.^[3] The particular residues of Arg-553 and Arg-613 have been found to key for synthetic function, however further research into the structure of trypanothione synthase must be done in order to fully understand the enzyme's active sites.^[5]

Function

Synthesis of Trypanothione

The main function of trypanothione synthase is to use the free energy generated from ATP hydrolysis to conjugate glutathione and spermidine to form the intermediate of glutathionylspermidine and then the final product of trypanothione.^[5] It also catalyzes the reverse reaction as well, albeit at a much lower rate. Under conditions found to be the optimum for both the forward and backwards reactions, trypanothione synthase from trypanosoma cruzi was found to have an amidase activity that was only about 1% of the forwards synthetase activity.^[6] This low activity can be explained by the blocking of the catalytic Cys in the amidase active site in order for the protein to properly fold.

In parasitic kinetoplastids trypanothione synthase activity is key to survival. Due to the need for trypanothione in order to defend against oxidative stresses, and maintain thiol and ribonucleotide metabolism. It was observed that induced knockout of trypanothione synthase through RNA interference caused a reduced growth rate of twofold among trypanosoma brucei due to the immediate disruption of flux through thiol redox.^[7] In other similar experiments which observed cell death after knocking out trypanothione synthase, it was shown that after two hours of being exposed to hydrogen peroxide in order to mimic the oxidant attack of phagocytes, the cells which did not contain working trypanothione synthase had a much higher death rate than wild type T. brucei.^[8]

Mechanism

The current believed mechanism for synthetase activity is that first glutathione and Mg²⁺-ATP bind to the enzyme in a ternary complex where glutathione becomes activated by ATP and forms glutathionyl phosphate.^[9] ADP then leaves the active site and the activated phosphate still bound to the enzyme in what is equivalent to a substituted enzyme reacts with glutathionylspermidine to form trypanothione.

Regulation

The regulation of trypanothione synthase is currently thought to be driven by conformational changes caused by allosteric interactions as the enzyme must regulate the relative levels of spermidine, glutathionylspermidine, glutathione and trypanothione in the cell.^[6] Evidence for this regulation is that the residues which allow the synthase domain to block the amidase active site are highly conserved among different species of kinetoplastids, indicating that they are key in the enzyme's function and that the binding of certain substrates might cause conformational shifts that would open up the amidase active site.

Clinical Significance

Many diseases such as Human African trypanosomiasis, Nagana disease in cattle, and Chagas disease are caused by kinetoplastid parasites.^[7]^[8]^[10] Such diseases infect an estimated 15 to 20 million people per year worldwide and kill 100000 to 150000 of those infected.^[7] Current treatments for these diseases were generally made almost 100 years ago and in that time many of the parasites have developed resistance, in addition, many of the original treatments are highly toxic.^[10] Targeting trypanothione synthase could be a novel way of preventing and curing these diseases through disruption of the parasites' metabolism. Scientists believe that the thiol metabolic pathway is an especially good target for anti-parasitic drug production as trypanothione based thiol redox is absent in humans and it is thought that thiol redox is key in the mechanisms some parasites have in order to obtain drug resistance .^[11]

References

↑ Smith K, Nadeau K, Bradley M, Walsh C, Fairlamb AH (1992). "Purification of glutathionylspermidine and trypanothione synthetases from Crithidia fasciculata". Protein. Sci. 1 (7): 874–83. doi:10.1002/pro.5560010705. PMC 2142158. PMID 1304372.
↑ Tetaud E, Manai F, Barrett MP, Nadeau K, Walsh CT, Fairlamb AH (July 1998). "Cloning and characterization of the two enzymes responsible for trypanothione biosynthesis in Crithidia fasciculata". J. Biol. Chem. 273 (31): 19383–90. doi:10.1074/jbc.273.31.19383. PMID 9677355.
1 2 3 Fyfe PK, Oza SL, Fairlamb AH, Hunter WN (June 2008). "Leishmania trypanothione synthetase-amidase structure reveals a basis for regulation of conflicting synthetic and hydrolytic activities". J. Biol. Chem. 283 (25): 17672–80. doi:10.1074/jbc.M801850200. PMC 2427367. PMID 18420578.
↑ Oza SL, Shaw MP, Wyllie S, Fairlamb AH (January 2005). "Trypanothione biosynthesis in Leishmania major". Mol. Biochem. Parasitol. 139 (1): 107–16. doi:10.1016/j.molbiopara.2004.10.004. PMID 15610825.
1 2 Oza SL, Wyllie S, Fairlamb AH (September 2006). "Mapping the functional synthetase domain of trypanothione synthetase from Leishmania major". Mol. Biochem. Parasitol. 149 (1): 117–20. doi:10.1016/j.molbiopara.2006.05.001. PMID 16765464.
1 2 Oza SL, Tetaud E, Ariyanayagam MR, Warnon SS, Fairlamb AH (September 2002). "A single enzyme catalyses formation of Trypanothione from glutathione and spermidine in Trypanosoma cruzi". J. Biol. Chem. 277 (39): 35853–61. doi:10.1074/jbc.M204403200. PMID 12121990.
1 2 3 Ariyanayagam MR, Oza SL, Guther ML, Fairlamb AH (October 2005). "Phenotypic analysis of trypanothione synthetase knockdown in the African trypanosome". Biochem. J. 391 (Pt 2): 425–32. doi:10.1042/BJ20050911. PMC 1276942. PMID 16008527.
1 2 Comini MA, Guerrero SA, Haile S, Menge U, Lünsdorf H, Flohé L (May 2004). "Validation of Trypanosoma brucei trypanothione synthetase as drug target". Free Radic. Biol. Med. 36 (10): 1289–302. doi:10.1016/j.freeradbiomed.2004.02.008. PMID 15110394.
↑ Comini M, Menge U, Wissing J, Flohé L (February 2005). "Trypanothione synthesis in crithidia revisited". J. Biol. Chem. 280 (8): 6850–60. doi:10.1074/jbc.M404486200. PMID 15537651.
1 2 Torrie LS, Wyllie S, Spinks D, et al. (December 2009). "Chemical validation of trypanothione synthetase: a potential drug target for human trypanosomiasis". J. Biol. Chem. 284 (52): 36137–45. doi:10.1074/jbc.M109.045336. PMC 2794729. PMID 19828449.
↑ Wyllie S, Oza SL, Patterson S, Spinks D, Thompson S, Fairlamb AH (November 2009). "Dissecting the essentiality of the bifunctional trypanothione synthetase-amidase in Trypanosoma brucei using chemical and genetic methods". Mol. Microbiol. 74 (3): 529–40. doi:10.1111/j.1365-2958.2009.06761.x. PMC 2784880. PMID 19558432.

Enzymes: CO CS and CN ligases (EC 6.1-6.3)

6.1: Carbon-Oxygen	Aminoacyl tRNA synthetase Alanine Arginine Asparagine Aspartate Cysteine D-alanine—poly(phosphoribitol) ligase Glutamate Glutamine Glycine Histidine Isoleucine Leucine Lysine Methionine Phenylalanine Proline Serine Threonine Tryptophan Tyrosine Valine

6.2: Carbon-Sulfur	Succinyl coenzyme A synthetase Acetyl—CoA synthetase Long-chain-fatty-acid—CoA ligase

6.3: Carbon-Nitrogen	Glutamine synthetase Ubiquitin ligase Cullin Von Hippel–Lindau tumor suppressor UBE3A Mdm2 Anaphase-promoting complex UBR1 Glutathione synthetase CTP synthetase Adenylosuccinate synthase Argininosuccinate synthase Holocarboxylase synthetase GMP synthase Asparagine synthetase Carbamoyl phosphate synthetase I II Glutamate–cysteine ligase

Enzymes

Activity	Active site Binding site Catalytic triad Oxyanion hole Enzyme promiscuity Catalytically perfect enzyme Coenzyme Cofactor Enzyme catalysis Enzyme kinetics Lineweaver–Burk plot Michaelis–Menten kinetics

Regulation	Allosteric regulation Cooperativity Enzyme inhibitor

Classification	EC number Enzyme superfamily Enzyme family List of enzymes

Types	EC1 Oxidoreductases (list) EC2 Transferases (list) EC3 Hydrolases (list) EC4 Lyases (list) EC5 Isomerases (list) EC6 Ligases (list)

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