Enhanced thermal and alkaline stability of L-lysine decarboxylase CadA by combining directed evolution and computation-guided virtual screening

Yang Xi , Lidan Ye , Hongwei Yu

Bioresources and Bioprocessing ›› 2022, Vol. 9 ›› Issue (1) : 24

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Bioresources and Bioprocessing ›› 2022, Vol. 9 ›› Issue (1) : 24 DOI: 10.1186/s40643-022-00510-w
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Enhanced thermal and alkaline stability of L-lysine decarboxylase CadA by combining directed evolution and computation-guided virtual screening

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Abstract

As an important monomer for bio-based nylons PA5X, cadaverine is mainly produced by enzymatic decarboxylation of L-lysine. A key issue with this process is the instability of L-lysine decarboxylase (CadA) during the reaction due to the dissociation of CadA subunits with the accumulation of alkaline cadaverine. In this work, we attempted to improve the thermal and alkaline stability of CadA by combining directed evolution and computation-guided virtual screening. Interestingly, site 477 residue located at the protein surface and not the decamer interface was found as a hotspot in directed evolution. By combinatorial mutagenesis of the positive mutations obtained by directed evolution and virtual screening with the previously reported T88S mutation, K477R/E445Q/T88S/F102V was generated as the best mutant, delivering 37% improvement of cadaverine yield at 50 ºC and pH 8.0. Molecular dynamics simulations suggested the improved rigidity of regional structures, increased number of salt bridges, and enhancement of hydrogen bonds at the multimeric interface as possible origins of the improved stability of the mutant. Using this four-point mutant, 160.7 g/L of cadaverine was produced from 2.0 M Lysine hydrochloride at 50 °C without pH regulation, with a conversion of 78.5%, whereas the wild type produced 143.7 g/L cadaverine, corresponding to 70% conversion. This work shows the combination of directed evolution and virtual screening as an efficient protein engineering strategy.

Keywords

Cadaverine / L-lysine decarboxylase / Stability / Directed evolution / Virtual screening

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Yang Xi, Lidan Ye, Hongwei Yu. Enhanced thermal and alkaline stability of L-lysine decarboxylase CadA by combining directed evolution and computation-guided virtual screening. Bioresources and Bioprocessing, 2022, 9(1): 24 DOI:10.1186/s40643-022-00510-w

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Akbulut N, Tuzlakoğlu Öztürk M, Pijning T, . Improved activity and thermostability of Bacillus pumilus lipase by directed evolution. J Biotechnol, 2013, 164: 123-129.

[2]

Arabnejad H, Lago MD, Jekel PA, . A robust cosolvent-compatible halohydrin dehalogenase by computational library design. Protein Eng Des Sel, 2017, 30: 175-189.

[3]

Arnold FH. Directed evolution: bringing new chemistry to life. Angew Chem Int Ed, 2018, 57: 4143-4148.

[4]

Badieyan S, Bevan DR, Zhang C. Study and design of stability in GH5 cellulases. Biotechnol Bioeng, 2012, 109: 31-44.

[5]

Bayramoglu G, Salih B, Arica MY. Catalytic activity of immobilized chymotrypsin on hybrid silica-magnetic biocompatible particles and its application in peptide synthesis. Appl Biochem Biotechnol, 2020, 190: 1224-1241.

[6]

Bednar D, Beerens K, Sebestova E, . FireProt: Energy- and Evolution-Based Computational Design of Thermostable Multiple-Point Mutants. PLoS Comput Biol, 2015, 11.

[7]

Bhatia SK, Kim YH, Kim HJ, . Biotransformation of lysine into cadaverine using barium alginate-immobilized Escherichia coli overexpressing CadA. Bioprocess Biosyst Eng, 2015, 38: 2315-2322.

[8]

Chen CW, Lin J, Chu YW. iStable: off-the-shelf predictor integration for predicting protein stability changes. BMC Bioinformatics, 2013, 14: S5.

[9]

Chen CW, Lin MH, Liao CC, . iStable 2.0: Predicting protein thermal stability changes by integrating various characteristic modules. Comp Struct Biotechnol J, 2020, 18: 622-630.

[10]

Eijsink VGH, Bjørk A, Gåseidnes S, . Rational engineering of enzyme stability. J Biotechnol, 2004, 113: 105-120.

[11]

Fecker LF, Beier H, Berlin J. Cloning and characterization of a lysine decarboxylase gene from Hafnia alvei. Mol Gen Genet, 1986, 203: 177-184.

[12]

Gribenko AV, Patel MM, Liu J, . Rational stabilization of enzymes by computational redesign of surface charge–charge interactions. Proc Natl Acad Sci U S A, 2009, 106: 2601-2606.

[13]

Hong EY, Lee SG, Park BJ, . Simultaneously enhancing the stability and catalytic activity of multimeric lysine decarboxylase CadA by engineering interface regions for enzymatic production of cadaverine at high concentration of lysine. Biotechnol J, 2017, 12: 1700278.

[14]

Jeong S, Yeon YJ, Choi E-G, . Alkaliphilic lysine decarboxylases for effective synthesis of cadaverine from L-lysine. Korean J Chem Eng, 2016, 33: 1530-1533.

[15]

Jiang H, Xia XX, Feng Y, . Development of a robust system for high-throughput colorimetric assay of diverse amino acid decarboxylases. Process Biochem, 2017, 60: 27-34.

[16]

Kanjee U, Gutsche I, Alexopoulos E, . Linkage between the bacterial acid stress and stringent responses: the structure of the inducible lysine decarboxylase: linkage between the bacterial acid stress and stringent responses. Embo J, 2011, 30: 931-944.

[17]

Kim HJ, Kim YH, Shin JH, . Optimization of direct lysine decarboxylase biotransformation for cadaverine production with whole-cell biocatalysts at high lysine concentration. J Microbiol Biotechnol, 2015, 25: 1108-1113.

[18]

Kim YH, Kim HJ, Shin J-H, . Application of diethyl ethoxymethylenemalonate (DEEMM) derivatization for monitoring of lysine decarboxylase activity. J Mol Catal B-Enzym, 2015, 115: 151-154.

[19]

Kind S, Wittmann C. Bio-based production of the platform chemical 1,5-diaminopentane. Appl Microbiol Biotechnol, 2011, 91: 1287-1296.

[20]

Kind S, Neubauer S, Becker J, . From zero to hero—production of bio-based nylon from renewable resources using engineered Corynebacterium glutamicum. Metab Eng, 2014, 25: 113-123.

[21]

Kou F, Zhao J, Liu J, . Characterization of a new lysine decarboxylase from Aliivibrio salmonicida for cadaverine production at alkaline pH. J Mol Catal B-Enzym, 2016, 133: S88-S94.

[22]

Kou F, Zhao J, Liu J, . Enhancement of the thermal and alkaline pH stability of Escherichia coli lysine decarboxylase for efficient cadaverine production. Biotechnol Lett, 2018, 40: 719-727.

[23]

Kumar CV. Methods in enzymology nanoarmoring of enzymes with carbon nanotubes and magnetic nanoparticles, 2020, 1, Academic Press, Cambridge, MA San Diego, CA Oxford London: Elsevier.
[24]

Lemonnier M, Lane D. Expression of the second lysine decarboxylase gene of Escherichia coli. Microbiology, 1998, 144: 751-760.

[25]

Leong YK, Chen CH, Huang SF, . High-level l-lysine bioconversion into cadaverine with enhanced productivity using engineered Escherichia coli whole-cell biocatalyst. Biochem Eng J, 2020, 157.

[26]

Li G, Fang X, Su F, . Enhancing the thermostability of Rhizomucor miehei lipase with a limited screening library by rational-design point mutations and disulfide bonds. Appl Environ Microbiol, 2018, 84: e02129-e2217.

[27]

Ma W, Chen K, Li Y, . Advances in cadaverine bacterial production and its applications. Engineering, 2017, 3: 308-317.

[28]

Meng Q, Capra N, Palacio CM, . Robust ω-transaminases by computational stabilization of the subunit interface. ACS Catal, 2020, 10: 2915-2928.

[29]

Nagatani RA, Gonzalez A, Shoichet BK, . Stability for function trade-offs in the enolase superfamily “catalytic module”. Biochemistry, 2007, 46: 6688-6695.

[30]

Parthasarathy S, Murthy MRN. Protein thermal stability: insights from atomic displacement parameters (B values). Protein Eng, 2000, 13: 9-13.

[31]

Parthiban V, Gromiha MM, Schomburg D. CUPSAT: prediction of protein stability upon point mutations. Nucleic Acids Res, 2006, 34: W239-W242.

[32]

Phan APH, Ngo TT, Lenhoff HM. Spectrophotometric assay for lysine decarboxylase. Anal Biochem, 1982, 120: 193-197.

[33]

Reetz MT. The importance of additive and non-additive mutational effects in protein engineering. Angew Chem Int Ed, 2013, 52: 2658-2666.

[34]

Reetz MT, Soni P, Acevedo JP, Sanchis J. Creation of an amino acid network of structurally coupled residues in the directed evolution of a thermostable enzyme. Angew Chem Int Ed, 2009, 48: 8268-8272.

[35]

Romero-Rivera A, Garcia-Borràs M, Osuna S. Computational tools for the evaluation of laboratory-engineered biocatalysts. Chem Commun, 2017, 53: 284-297.

[36]

Sáez-Jiménez V, Fernández-Fueyo E, Medrano FJ, . Improving the pH-stability of versatile peroxidase by comparative structural analysis with a naturally-stable manganese peroxidase. PLoS ONE, 2015, 10.

[37]

Schneider J, Wendisch VF. Biotechnological production of polyamines by bacteria: recent achievements and future perspectives. Appl Microbiol Biotechnol, 2011, 91: 17-30.

[38]

Sheldon RA, Pereira PC. Biocatalysis engineering: the big picture. Chem Soc Rev, 2017, 46: 2678-2691.

[39]

Strickler SS, Gribenko AV, Gribenko AV, . Protein stability and surface electrostatics: a charged relationship. Biochemistry, 2006, 45: 2761-2766.

[40]

Sun Z, Liu Q, Qu G, . Utility of B-factors in protein science: interpreting rigidity, flexibility, and internal motion and engineering thermostability. Chem Rev, 2019, 119: 1626-1665.

[41]

Tokuriki N, Stricher F, Serrano L, Tawfik DS. How protein stability and new functions trade off. PLoS Comput Biol, 2008, 4.

[42]

Wang C, Zhang K, Zhongjun C, . Directed evolution and mutagenesis of lysine decarboxylase from Hafnia alvei AS1.1009 to improve its activity toward efficient cadaverine production. Biotechnol Bioprocess Eng, 2015, 20: 439-446.

[43]

Watson N, Dunyak DS, Rosey EL, Slonczewski JL. Identification of elements involved in transcriptional regulation of the Escherichia coli cad operon by external pH. J Bacteriol, 1992, 174: 530-540.

[44]

Whitley M, Lee A. Frameworks for understanding long-range intra-protein communication. Curr Protein Pept Sci, 2009, 10: 116-127.

[45]

Wijma HJ, Floor RJ, Janssen DB. Structure- and sequence-analysis inspired engineering of proteins for enhanced thermostability. Curr Opin Struct Biol, 2013, 23: 588-594.

[46]

Wijma HJ, Floor RJ, Jekel PA, . Computationally designed libraries for rapid enzyme stabilization. Protein Eng Des Sel, 2014, 27: 49-58.

[47]

Wu J-P, Li M, Zhou Y, . Introducing a salt bridge into the lipase of Stenotrophomonas maltophilia results in a very large increase in thermal stability. Biotechnol Lett, 2015, 37: 403-407.

[48]

Yang C, Ye L, Gu J, . Directed evolution of mandelate racemase by a novel high-throughput screening method. Appl Microbiol Biotechnol, 2017, 101: 1063-1072.

[49]

Yokot K, Satou K, Ohki S. Comparative analysis of protein thermostability: differences in amino acid content and substitution at the surfaces and in the core regions of thermophilic and mesophilic proteins. Sci Technol Adv Mater, 2006, 7: 255-262.

[50]

Yu H, Dalby PA. Coupled molecular dynamics mediate long- and short-range epistasis between mutations that affect stability and aggregation kinetics. Proc Natl Acad Sci U S A, 2018, 115: E11043-E11052.

[51]

Yu H, Huang H. Engineering proteins for thermostability through rigidifying flexible sites. Biotechnol Adv, 2014, 32: 308-315.

[52]

Yu K, Hu S, Huang J, Mei LH. A high-throughput colorimetric assay to measure the activity of glutamate decarboxylase. Enzyme Microb Technol, 2011, 49: 272-276.

[53]

Zhou N, Zhang A, Wei G, . Cadaverine production from L-lysine with chitin-binding protein-mediated lysine decarboxylase immobilization. Front Bioeng Biotechnol, 2020, 8: 103.

Funding

National Key Research and Development Program of China(2020YFA0908400)

Natural Science Foundation of Zhejiang Province(LZ20B060002)

National Natural Science Foundation of China(32171412)

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