Structure-oriented substrate specificity engineering of aldehyde-deformylating oxygenase towards aldehydes carbon chain length

Bao, Luyao; Li, Jianjun; Jia, Chunmei; Li, Mei; Lü, Xuefeng

doi:10.1186/s13068-016-0596-9

Cited by 35 publications

(36 citation statements)

References 38 publications

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“…8. It has been shown in previous studies that the ligand approaches the diiron cluster from opposite side of the His-148 residue with its headgroup binding directly to the Fe2, which is the preferred iron for substrate binding (21,35). We also observed similar interactions in the case of the Np-ADO at 300 K where ligand appeared to be bound to the Fe2 (Fig.…”

Section: Protein Engineering For Improved Thermostability Of Adosupporting

confidence: 84%

“…The role of cysteine residues has been investigated in ADO from Nostoc punctiforme PCC 73102, and it was shown that Cys-71 is involved in maintaining the activity, structure, and stability of ADO (39). Certain amino acid residues present in the vicinity of the substrate channel were identified for successfully changing the substrate chain length selectivity of ADO (21). The ADO belongs to the nonheme dinuclear iron oxygenase family of enzymes that includes methane monooxygenase, type I ribonucleotide reductase, and ferritin (3, 35, 40 -42).…”

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confidence: 99%

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A consensus-guided approach yields a heat-stable alkane-producing enzyme and identifies residues promoting thermostability

Shakeel

Gupta

Fatma

et al. 2018

Journal of Biological Chemistry

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Aldehyde-deformylating oxygenase (ADO) is an essential enzyme for production of long-chain alkanes as drop-in biofuels, which are compatible with existing fuel systems. The most active ADOs are present in mesophilic cyanobacteria, especially Given the potential applications of thermostable enzymes in biorefineries, here we generated a thermostable (Cts)-ADO based on a consensus of ADO sequences from several thermophilic cyanobacterial strains. Using an design pipeline and a metagenome library containing 41 hot-spring microbial communities, we created Cts-ADO. Cts-ADO displayed a 3.8-fold increase in pentadecane production on raising the temperature from 30 to 42 °C, whereas ADO from (Np-ADO) exhibited a 1.7-fold decline. 3D structure modeling and molecular dynamics simulations of Cts- and Np-ADO at different temperatures revealed differences between the two enzymes in residues clustered on exposed loops of these variants, which affected the conformation of helices involved in forming the ADO catalytic core. In Cts-ADO, this conformational change promoted ligand binding to its preferred iron, Fe2, in the di-iron cluster at higher temperature, but the reverse was observed in Np-ADO. Detailed mapping of residues conferring Cts-ADO thermostability identified four amino acids, which we substituted individually and together in Np-ADO. Among these substitution variants, A161E was remarkably similar to Cts-ADO in terms of activity optima, kinetic parameters, and structure at higher temperature. A161E was located in loop L6, which connects helices H5 and H6, and supported ligand binding to Fe2 at higher temperatures, thereby promoting optimal activity at these temperatures and explaining the increased thermostability of Cts-ADO.

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Section: Protein Engineering For Improved Thermostability Of Adosupporting

confidence: 84%

mentioning

confidence: 99%

A consensus-guided approach yields a heat-stable alkane-producing enzyme and identifies residues promoting thermostability

Shakeel

Gupta

Fatma

et al. 2018

Journal of Biological Chemistry

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“…The importance of rationally designing enzyme libraries with amino acid diversity in specific regions has also been recently demonstrated in a variety of examples that involve optimization of substrate access tunnels of enzyme active sites to improve activity and stability . Several computational tools have been generated for identifying and engineering substrate access tunnels for diverse applications in enzyme engineering, including altering substrate selectivity (see references within a recent review).…”

Section: Design Methods For Improving Directed Evolution Of Protein Amentioning

confidence: 99%

Directed evolution methods for overcoming trade‐offs between protein activity and stability

2019

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Engineered proteins are being widely developed and employed in applications ranging from enzyme catalysts to therapeutic antibodies. Directed evolution, an iterative experimental process composed of mutagenesis and library screening, is a powerful technique for enhancing existing protein activities and generating entirely new ones not observed in nature. However, the process of accumulating mutations for enhanced protein activity requires chemical and structural changes that are often destabilizing, and low protein stability is a significant barrier to achieving large enhancements in activity during multiple rounds of directed evolution. Here we highlight advances in understanding the origins of protein activity/stability trade-offs for two important classes of proteins (enzymes and antibodies) as well as innovative experimental and computational methods for overcoming such trade-offs. These advances hold great potential for improving the generation of highly active and stable proteins that are needed to address key challenges related to human health, energy and the environment. K E Y W O R D Saffinity, antibody, catalysis, enzyme, protein design, protein engineering

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“…The reaction is dependent on an external reducing system to provide altogether four electrons for the (i) activation of the di-iron center for oxygen binding, (ii) hemiacetal radical formation, and (iii) generation of the product complex ( Paul et al, 2013 ; Rajakovich et al, 2015 ). Characteristically, ADO has relatively broad substrate specificity towards different aldehydes, with the highest activity towards the native linear C16 and C18 precursors ( Khara et al, 2013; Bao et al, 2016 ; Zhang et al, 2016 ). This feature is accompanied by a low apparent catalytic turnover rate with reported k cat values below 0.02 s −1 in different contexts in vitro and in vivo ( Khara et al, 2013; Andre et al, 2013; Bao et al, 2016 ).…”

Section: Introductionmentioning

confidence: 99%

“…Characteristically, ADO has relatively broad substrate specificity towards different aldehydes, with the highest activity towards the native linear C16 and C18 precursors ( Khara et al, 2013; Bao et al, 2016 ; Zhang et al, 2016 ). This feature is accompanied by a low apparent catalytic turnover rate with reported k cat values below 0.02 s −1 in different contexts in vitro and in vivo ( Khara et al, 2013; Andre et al, 2013; Bao et al, 2016 ). Kinetic characterization has also revealed that the affinity towards the aldehyde substrates is poor, especially for the shorter precursors, with K M values in the millimolar range ( Bao et al, 2016 ).…”

Section: Introductionmentioning

confidence: 99%

Comparison of orthologous cyanobacterial aldehyde deformylating oxygenases in the production of volatile C3-C7 alkanes in engineered E. coli

Patrikainen

Carbonell

Thiel

et al. 2017

Metabolic Engineering Communications

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Aldehyde deformylating oxygenase (ADO) is a unique enzyme found exclusively in photosynthetic cyanobacteria, which natively converts acyl aldehyde precursors into hydrocarbon products embedded in cellular lipid bilayers. This capacity has opened doors for potential biotechnological applications aiming at biological production of diesel-range alkanes and alkenes, which are compatible with the nonrenewable petroleum-derived end-products in current use. The development of production platforms, however, has been limited by the relative inefficiency of ADO enzyme, promoting research towards finding new strategies and information to be used for rational design of enhanced pathways for hydrocarbon over-expression. In this work we present an optimized approach to study different ADO orthologs derived from different cyanobacterial species in an in vivo set-up in Escherichia coli. The system enabled comparison of alternative ADOs for the production efficiency of short-chain volatile C3-C7 alkanes, propane, pentane and heptane, and provided insight on the differences in substrate preference, catalytic efficiency and limitations associated with the enzymes. The work concentrated on five ADO orthologs which represent the most extensively studied cyanobacterial species in the field, and revealed distinct differences between the enzymes. In most cases the ADO from Nostoc punctiforme PCC 73102 performed the best in respect to yields and initial rates for the production of the volatile hydrocarbons. At the other extreme, the system harboring the ADO form Synechococcus sp. RS9917 produced very low amounts of the short-chain alkanes, primarily due to poor accumulation of the enzyme in E. coli. The ADOs from Synechocystis sp. PCC 6803 and Prochlorococcus marinus MIT9313, and the corresponding variant A134F displayed less divergence, although variation between chain-length preferences could be observed. The results confirmed the general trend of ADOs having decreasing catalytic efficiency towards precursors of decreasing chain-length, while expanding the knowledge on the species-specific traits, which may aid future pathway design and structure-based engineering of ADO for more efficient hydrocarbon production systems.

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Structure-oriented substrate specificity engineering of aldehyde-deformylating oxygenase towards aldehydes carbon chain length

Cited by 35 publications

References 38 publications

A consensus-guided approach yields a heat-stable alkane-producing enzyme and identifies residues promoting thermostability

A consensus-guided approach yields a heat-stable alkane-producing enzyme and identifies residues promoting thermostability

Directed evolution methods for overcoming trade‐offs between protein activity and stability

Comparison of orthologous cyanobacterial aldehyde deformylating oxygenases in the production of volatile C3-C7 alkanes in engineered E. coli

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