Cyanase Explained

cyanase
Ec Number:4.2.1.104
Cas Number:37289-24-0
Go Code:0008824
Symbol:Cyanate_lyase
Cyanate lyase, C-terminal domain
Pfam:PF02560
Interpro:IPR003712
Scop:1dw9
Cdd:cd00559

The enzyme cyanase (also known as cyanate hydratase or cyanate lyase), catalyses the bicarbonate dependent metabolism of cyanate to produce ammonia and carbon dioxide.[1] [2] The systematic name of this enzyme is carbamate hydrolyase. In E. coli, cyanase is an inducible enzyme and is encoded for by the cynS gene.[3] Cyanate is a toxic anion, and cyanase catalyzes the metabolism into the benign products of carbon dioxide and ammonia.

Enzyme Reaction

Cyanase catalyzes the metabolic conversion of toxic cyanate to carbamate (H2NCOO). The enzyme does this by first catalyzing the conversion of cyanate to carbamate, which then spontaneously decomposes to carbon dioxide and ammonia:[4]

  1. cyanate (OCN) + HCO3 + H+

\rightleftharpoons

carbamate (H2NCOO) + CO2
  1. carbamate (H2NCOO) + H+

\rightleftharpoons

NH3 + CO2 (spontaneous)The resulting net reaction is:

cyanate (OCN) + HCO3 + 2 H+

\rightleftharpoons

NH3 + 2 CO2

The kinetic mechanism is a rapid equilibrium where bicarbonate and cyanate both act as substrates. Bicarbonate acts a recycling substrate to cyanase in the production carbamate which then decomposes to complete the metabolism, rather than metabolism via a hydrolysis reaction as formerly believed.[5]

A positively charged active site forms a pocket with two anion binding sites, bonded via ionic interaction. Positively charged amino acids that make up the protein help form this site between subunits.[6] This adjacent anion binding site structure accommodates a complex of cyanate and bicarbonate, allowing the carbamate producing reaction to proceed.

Enzyme Structure

Some bacteria can overcome the toxicity of environmental cyanate by degrading it via this enzyme.[7] Cyanate hydratase is found in bacteria and plants. Cyanase is functionally active as a homodecamer, composed of 5 complexes of dimers. Each of these monomer subunits is 17 kDa and supports half-site binding of substrates.[8] The cyanase monomer is composed of two domains. The N-terminal domain shows structural similarity to the DNA-binding alpha-helix bundle motif. The C-terminal domain has an 'open fold' with no structural homology to other proteins. The dimer structure reveals the C-terminal domains to be intertwined, and a decamer is formed by a pentamer of these dimers. The active site of the enzyme is located between dimers and is composed of residues from four adjacent subunits of the homodecamer.[8]

Connecting these two domains in the monomer is the single cysteine residue.[9] The disulfide bond links 156 amino acid units. Forming the larger complexes of the pentamer and decamer requires the presence of cyanate, or a substrate analog like azide. The final native enzyme complex is a complex of 5 dimers.

The crystallization of cyanase shows that cyanase crystals are triclinic with one homodecamer in the asymmetric unit.[10]

The active site of cyanase accommodates two anions, bicarbonate and cyanate. Three catalytic residues, Arg96, Glu99, and Ser122, form this pocket that stabilizes the anions with ionic interactions. The positively charged and polar amino acid residues allow the active site to bind anions. The active site sits between dimers, noted by the Arg96 in each monomer to be in close proximity.

[11] [10]

The structure of cyanase has been shown to be similar in its prokaryotic and eukaryotic forms.[12]

Enzyme Activity

Cyanase is regulated both transcriptionally and in its enzymatic activity.[13] Transcription of cyanase is elevated with the presence of extracellular cyanate, a toxic ion, but also down regulated by the presence of excess arginine, the catalytic amino acid. Cyanase requires the product of the reaction catalyzed by cyanate permease. Activity of cyanase is also dependent on the concentration of its substrates, cyanate and bicarbonate.

Because bicarbonate is itself a recycling substrate and the kinetics of cyanase include a rapid and random equilibrium, bicarbonate can also act as an enzyme inhibitor. At low concentrations, bicarbonate shows uncompetitive inhibition, where it binds to the one of enzyme's anionic binding sites, and inhibit cyanate binding, or bicarbonate can bind once more so that the enzyme complex is bound to two bicarbonates in its double anion active site. At higher concentrations, the trend moves toward non-competitive inhibition, where the incorrect, dead-end complex must decompose to the initial separated units before the binding action can begin again.

This random equilibrium of cyanate and bicarbonate complexing with the enzyme causing substrate inhibition is referred to as ping pong inhibition.

Functional Relevance

Cyanase is an important enzyme for plants and microbacteria as cyanate is a toxic substance that is prevalent in many environments. Further cyanase activity has been found to be encoded in cynH, a gene only found in marine cyanobacteria.[14] There is a dodecapeptide, a partial region near the N-terminus of cyanate, that as a novel cationic α-helical antimicrobial peptide, known by CL 14-25.[15]

Cyanase is also important as an energy metabolizer to fix Nitrogen in nitrifiers. Cyanate is an important source of reduced nitrogen in aquatic and terrestrial ecosystems, and although it is a toxic ion, it can be converted to ammonium and carbon dioxide by a cyanase enzyme, supplying energetic Nitrogen compounds to the organism.[16] The activity of cyanase is heavily dependent on the present of bicarbonate, and to overcome this bottleneck, a combined application of cyanase and carbonic anhydrase has been used in a study.[17] [18]

Notes and References

  1. Qian D, Jiang L, Lu L, Wei C, Li Y . Biochemical and structural properties of cyanases from Arabidopsis thaliana and Oryza sativa . PLOS ONE . 6 . 3 . e18300 . March 2011 . 21494323 . 3070753 . 10.1371/journal.pone.0018300 . 2011PLoSO...618300Q . free .
  2. Anderson PM, Sung YC, Fuchs JA . The cyanase operon and cyanate metabolism . FEMS Microbiology Reviews . 7 . 3–4 . 247–52 . December 1990 . 2094285 . 10.1111/j.1574-6968.1990.tb04920.x . free .
  3. Chin CC, Anderson PM, Wold F . The amino acid sequence of Escherichia coli cyanase . The Journal of Biological Chemistry . 258 . 1 . 276–82 . January 1983 . 10.1016/S0021-9258(18)33253-8 . 6336748 . free .
  4. Web site: IUBMB Enzyme Nomenclature: EC 4.2.1.104.
  5. Johnson WV, Anderson PM . Bicarbonate is a recycling substrate for cyanase . The Journal of Biological Chemistry . 262 . 19 . 9021–5 . July 1987 . 10.1016/S0021-9258(18)48040-4 . 3110153 . free .
  6. Anderson PM, Little RM . Kinetic properties of cyanase . Biochemistry . 25 . 7 . 1621–6 . April 1986 . 3518792 . 10.1021/bi00355a026 .
  7. Sung YC, Fuchs JA . Characterization of the cyn operon in Escherichia coli K12 . The Journal of Biological Chemistry . 263 . 29 . 14769–75 . October 1988 . 10.1016/S0021-9258(18)68104-9 . 3049588 . free .
  8. Walsh MA, Otwinowski Z, Perrakis A, Anderson PM, Joachimiak A . Structure of cyanase reveals that a novel dimeric and decameric arrangement of subunits is required for formation of the enzyme active site . Structure . 8 . 5 . 505–14 . May 2000 . 10801492 . 3366510 . 10.1016/S0969-2126(00)00134-9 . free .
  9. Little RM, Anderson PM . Structural properties of cyanase. Denaturation, renaturation, and role of sulfhydryls and oligomeric structure in catalytic activity . The Journal of Biological Chemistry . 262 . 21 . 10120–6 . July 1987 . 10.1016/S0021-9258(18)61086-5 . 3301828 . free .
  10. Butryn A, Stoehr G, Linke-Winnebeck C, Hopfner KP . Serendipitous crystallization and structure determination of cyanase (CynS) from Serratia proteamaculans . Acta Crystallographica Section F . 71 . Pt 4 . 471–6 . April 2015 . 25849512 . 10.1107/S2053230X15004902 . 4388186 .
  11. Xu. Y.. Cyanase from Serratia proteamaculans. Worldwide Protein Data Bank. October 2, 2017. RCSB PDB. 10.2210/pdb6b6m/pdb. en.
  12. Schlachter CR, Klapper V, Wybouw N, Radford T, Van Leeuwen T, Grbic M, Chruszcz M . Structural Characterization of a Eukaryotic Cyanase from Tetranychus urticae . Journal of Agricultural and Food Chemistry . 65 . 27 . 5453–5462 . July 2017 . 28613863 . 10.1021/acs.jafc.7b01333 .
  13. Elleuche S, Pöggeler S . A cyanase is transcriptionally regulated by arginine and involved in cyanate decomposition in Sordaria macrospora . Fungal Genetics and Biology . 45 . 11 . 1458–69 . November 2008 . 18796334 . 10.1016/j.fgb.2008.08.005 .
  14. Kamennaya NA, Post AF . Characterization of cyanate metabolism in marine Synechococcus and Prochlorococcus spp . Applied and Environmental Microbiology . 77 . 1 . 291–301 . January 2011 . 21057026 . 3019706 . 10.1128/AEM.01272-10 . 2011ApEnM..77..291K .
  15. Takei N, Takahashi N, Takayanagi T, Ikeda A, Hashimoto K, Takagi M, Hamada T, Saitoh E, Ochiai A, Tanaka T, Taniguchi M . Antimicrobial activity and mechanism of action of a novel cationic α-helical dodecapeptide, a partial sequence of cyanate lyase from rice . Peptides . 42 . 55–62 . April 2013 . 23270672 . 10.1016/j.peptides.2012.12.015 . 56770 .
  16. Palatinszky M, Herbold C, Jehmlich N, Pogoda M, Han P, von Bergen M, Lagkouvardos I, Karst SM, Galushko A, Koch H, Berry D, Daims H, Wagner M . Cyanate as an energy source for nitrifiers . Nature . 524 . 7563 . 105–8 . August 2015 . 26222031 . 10.1038/nature14856 . 4539577 . 2015Natur.524..105P .
  17. Ranjan B, Pillai S, Permaul K, Singh S . A novel strategy for the efficient removal of toxic cyanate by the combinatorial use of recombinant enzymes immobilized on aminosilane modified magnetic nanoparticles . Bioresource Technology . 253 . 105–111 . April 2018 . 29331825 . 10.1016/j.biortech.2017.12.087 .
  18. Kebeish R, Al-Zoubi O . Expression of the cyanobacterial enzyme cyanase increases cyanate metabolism and cyanate tolerance in Arabidopsis . Environmental Science and Pollution Research International . 24 . 12 . 11825–11835 . April 2017 . 28343358 . 10.1007/s11356-017-8866-z . 10098182 .