4aho Citations

Structural insights into the recovery of aldolase activity in N-acetylneuraminic acid lyase by replacement of the catalytically active lysine with γ-thialysine by using a chemical mutagenesis strategy.

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Timms N, Windle CL, Polyakova A, Ault JR, Trinh CH, Pearson AR, Nelson A, Berry A
OpenAccess logo Chembiochem 14 474-81 (2013)
Related entries: 4ah7, 4ahp, 4ahq, 4ama

Cited: 17 times
EuropePMC logo PMID: 23418011

Abstract

Chemical modification has been used to introduce the unnatural amino acid γ-thialysine in place of the catalytically important Lys165 in the enzyme N-acetylneuraminic acid lyase (NAL). The Staphylococcus aureus nanA gene, encoding NAL, was cloned and expressed in E. coli. The protein, purified in high yield, has all the properties expected of a class I NAL. The S. aureus NAL which contains no natural cysteine residues was subjected to site-directed mutagenesis to introduce a cysteine in place of Lys165 in the enzyme active site. Subsequently chemical mutagenesis completely converted the cysteine into γ-thialysine through dehydroalanine (Dha) as demonstrated by ESI-MS. Initial kinetic characterisation showed that the protein containing γ-thialysine regained 17 % of the wild-type activity. To understand the reason for this lower activity, we solved X-ray crystal structures of the wild-type S. aureus NAL, both in the absence of, and in complex with, pyruvate. We also report the structures of the K165C variant, and the K165-γ-thialysine enzyme in the presence, or absence, of pyruvate. These structures reveal that γ-thialysine in NAL is an excellent structural mimic of lysine. Measurement of the pH-activity profile of the thialysine modified enzyme revealed that its pH optimum is shifted from 7.4 to 6.8. At its optimum pH, the thialysine-containing enzyme showed almost 30 % of the activity of the wild-type enzyme at its pH optimum. The lowered activity and altered pH profile of the unnatural amino acid-containing enzyme can be rationalised by imbalances of the ionisation states of residues within the active site when the pK(a) of the residue at position 165 is perturbed by replacement with γ-thialysine. The results reveal the utility of chemical mutagenesis for the modification of enzyme active sites and the exquisite sensitivity of catalysis to the local structural and electrostatic environment in NAL.

Articles - 4aho mentioned but not cited (1)

  1. Structural insights into the recovery of aldolase activity in N-acetylneuraminic acid lyase by replacement of the catalytically active lysine with γ-thialysine by using a chemical mutagenesis strategy. Timms N, Windle CL, Polyakova A, Ault JR, Trinh CH, Pearson AR, Nelson A, Berry A. Chembiochem 14 474-481 (2013)


Reviews citing this publication (1)

  1. Chemical Protein Modification through Cysteine. Gunnoo SB, Madder A. Chembiochem 17 529-553 (2016)

Articles citing this publication (15)

  1. Elucidation of a sialic acid metabolism pathway in mucus-foraging Ruminococcus gnavus unravels mechanisms of bacterial adaptation to the gut. Bell A, Brunt J, Crost E, Vaux L, Nepravishta R, Owen CD, Latousakis D, Xiao A, Li W, Chen X, Walsh MA, Claesen J, Angulo J, Thomas GH, Juge N. Nat Microbiol 4 2393-2404 (2019)
  2. Chemoselective Installation of Amine Bonds on Proteins through Aza-Michael Ligation. Freedy AM, Matos MJ, Boutureira O, Corzana F, Guerreiro A, Akkapeddi P, Somovilla VJ, Rodrigues T, Nicholls K, Xie B, Jiménez-Osés G, Brindle KM, Neves AA, Bernardes GJL. J Am Chem Soc 139 18365-18375 (2017)
  3. Synthetic phosphorylation of p38α recapitulates protein kinase activity. Chooi KP, Galan SR, Raj R, McCullagh J, Mohammed S, Jones LH, Davis BG. J Am Chem Soc 136 1698-1701 (2014)
  4. Post-translational site-selective protein backbone α-deuteration. Galan SRG, Wickens JR, Dadova J, Ng WL, Zhang X, Simion RA, Quinlan R, Pires E, Paton RS, Caddick S, Chudasama V, Davis BG. Nat Chem Biol 14 955-963 (2018)
  5. Chemical generation and modification of peptides containing multiple dehydroalanines. Morrison PM, Foley PJ, Warriner SL, Webb ME. Chem Commun (Camb) 51 13470-13473 (2015)
  6. Extending enzyme molecular recognition with an expanded amino acid alphabet. Windle CL, Simmons KJ, Ault JR, Trinh CH, Nelson A, Pearson AR, Berry A. Proc Natl Acad Sci U S A 114 2610-2615 (2017)
  7. Linker-free incorporation of carbohydrates into in vitro displayed macrocyclic peptides. Jongkees SAK, Umemoto S, Suga H. Chem Sci 8 1474-1481 (2017)
  8. Letter Structure and inhibition of N-acetylneuraminate lyase from methicillin-resistant Staphylococcus aureus. North RA, Watson AJ, Pearce FG, Muscroft-Taylor AC, Friemann R, Fairbanks AJ, Dobson RC. FEBS Lett 590 4414-4428 (2016)
  9. Precise Probing of Residue Roles by Post-Translational β,γ-C,N Aza-Michael Mutagenesis in Enzyme Active Sites. Dadová J, Wu KJ, Isenegger PG, Errey JC, Bernardes GJL, Chalker JM, Raich L, Rovira C, Davis BG. ACS Cent Sci 3 1168-1173 (2017)
  10. Evaluation of fluoropyruvate as nucleophile in reactions catalysed by N-acetyl neuraminic acid lyase variants: scope, limitations and stereoselectivity. Stockwell J, Daniels AD, Windle CL, Harman TA, Woodhall T, Lebl T, Trinh CH, Mulholland K, Pearson AR, Berry A, Nelson A. Org Biomol Chem 14 105-112 (2016)
  11. Structural basis for substrate specificity and mechanism of N-acetyl-D-neuraminic acid lyase from Pasteurella multocida. Huynh N, Aye A, Li Y, Yu H, Cao H, Tiwari VK, Shin DW, Chen X, Fisher AJ. Biochemistry 52 8570-8579 (2013)
  12. Protonation states of active-site lysines of penicillin-binding protein 6 from Escherichia coli and the mechanistic implications. Kumarasiri M, Zhang W, Shi Q, Fisher JF, Mobashery S. Proteins 82 1348-1358 (2014)
  13. Circular dichroism spectroscopic study on structural alterations of histones induced by post-translational modifications in DNA damage responses: lysine-9 methylation of H3. Izumi Y, Matsuo K, Fujii K, Yokoya A, Taniguchi M, Namatame H. J Radiat Res 59 108-115 (2018)
  14. A platform for chemical modification of mandelate racemase: characterization of the C92S/C264S and γ-thialysine 166 variants. Nagar M, Kumar H, Bearne SL. Protein Eng Des Sel 31 135-145 (2018)
  15. Features and structure of a cold active N-acetylneuraminate lyase. Gurung MK, Altermark B, Helland R, Smalås AO, Ræder ILU. PLoS One 14 e0217713 (2019)


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