Xavier Garrabou scite author profile

Designing catalysts that achieve the rates and selectivities of natural enzymes is a long-standing goal in protein chemistry. Here, we show that an ultrahigh-throughput droplet-based microfluidic screening platform can be used to improve a previously optimized artificial aldolase by an additional factor of 30 to give a >10 rate enhancement that rivals the efficiency of class I aldolases. The resulting enzyme catalyses a reversible aldol reaction with high stereoselectivity and tolerates a broad range of substrates. Biochemical and structural studies show that catalysis depends on a Lys-Tyr-Asn-Tyr tetrad that emerged adjacent to a computationally designed hydrophobic pocket during directed evolution. This constellation of residues is poised to activate the substrate by Schiff base formation, promote mechanistically important proton transfers and stabilize multiple transition states along a complex reaction coordinate. The emergence of such a sophisticated catalytic centre shows that there is nothing magical about the catalytic activities or mechanisms of naturally occurring enzymes, or the evolutionary process that gave rise to them.

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A Mutant D‐Fructose‐6‐Phosphate Aldolase (Ala129Ser) with Improved Affinity towards Dihydroxyacetone for the Synthesis of Polyhydroxylated Compounds

Castillo

et al. 2010

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A mutant of d-fructose-6-phosphate aldolase (FSA) of Escherichia coli, FSA A129S, with improved catalytic efficiency towards dihydroxyacetone (DHA), the donor substrate in aldol addition reactions, was explored for synthetic applications. The k cat /K M value for DHA was 17-fold higher with FSA A129S than that with FSA wild type (FSA wt). On the other hand, for hydroxyacetone as donor substrate FSA A129S was found to be 3.5-fold less efficient than FSA wt. Furthermore, FSA A129S also accepted glycolaldehyde (GA) as donor substrate with 3.3-fold lower affinity than FSA wt. This differential selectivity of both FSA wt and FSA A129S for GA makes them complementary biocatalysts allowing a control over donor and acceptor roles, which is particularly useful in carboligation multi-step cascade synthesis of polyhydroxylated complex compounds. Production of the mutant protein was also improved for its convenient use in synthesis. Several carbohydrates and nitrocyclitols were efficiently prepared, demonstrating the versatile potential of FSA A129S as biocatalyst in organic synthesis.

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Speeding up enzyme discovery and engineering with ultrahigh-throughput methods

Bunzel

Garrabou

Pott

et al. 2018

Current Opinion in Structural Biology

117

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Asymmetric Self‐ and Cross‐Aldol Reactions of Glycolaldehyde Catalyzed by D‐Fructose‐6‐phosphate Aldolase

et al. 2009

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Current Trends in Asymmetric Synthesis with Aldolases

Clapés¹,

Garrabou²

2011

Adv Synth Catal

127

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Biocatalytic carbon-carbon bond formation by means of aldolases offers an exceptionally stereoselective and green tool for this strategic reaction in synthetic organic chemistry. Recent developments have shown that aldolases are particularly suitable catalysts for asymmetric framework construction and preparation of innovative molecules, which are valuable for investigations in drug discovery. Finding novel carboligases with unprecedented activities and engineering those available for improved substrate tolerance and stereoselectivity towards new synthetic challenges are fostering the advances in this field. Extensive knowledge of the precise reaction mechanism and the enzyme-substrate interactions arising from biochemical and structural studies are leading to the development of novel catalysts by rational strategies, as well as to de novo computational design of enzymes. Besides, a number of industrially-oriented processes with aldolases have been developed towards the production of drug precursors and dietary commodities.

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Xavier Garrabou

Emergence of a catalytic tetrad during evolution of a highly active artificial aldolase

A Mutant D‐Fructose‐6‐Phosphate Aldolase (Ala129Ser) with Improved Affinity towards Dihydroxyacetone for the Synthesis of Polyhydroxylated Compounds

Speeding up enzyme discovery and engineering with ultrahigh-throughput methods

Asymmetric Self‐ and Cross‐Aldol Reactions of Glycolaldehyde Catalyzed by D‐Fructose‐6‐phosphate Aldolase

Current Trends in Asymmetric Synthesis with Aldolases

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