Title: Ultrahigh-Throughput Directed Evolution of a Metal-Free alpha/beta-Hydrolase with a Cys-His-Asp Triad into an Efficient Phosphotriesterase Schnettler JD, Klein OJ, Kaminski TS, Colin PY, Hollfelder F Ref: Journal of the American Chemical Society, :, 2022 : PubMed
Finding new mechanistic solutions for biocatalytic challenges is key in the evolutionary adaptation of enzymes, as well as in devising new catalysts. The recent release of man-made substances into the environment provides a dynamic testing ground for observing biocatalytic innovation at play. Phosphate triesters, used as pesticides, have only recently been introduced into the environment, where they have no natural counterpart. Enzymes have rapidly evolved to hydrolyze phosphate triesters in response to this challenge, converging onto the same mechanistic solution, which requires bivalent cations as a cofactor for catalysis. In contrast, the previously identified metagenomic promiscuous hydrolase P91, a homologue of acetylcholinesterase, achieves slow phosphotriester hydrolysis mediated by a metal-independent Cys-His-Asp triad. Here, we probe the evolvability of this new catalytic motif by subjecting P91 to directed evolution. By combining a focused library approach with the ultrahigh throughput of droplet microfluidics, we increase P91's activity by a factor of =360 (to a k(cat)/K(M) of =7 x 10(5) M(-1) s(-1)) in only two rounds of evolution, rivaling the catalytic efficiencies of naturally evolved, metal-dependent phosphotriesterases. Unlike its homologue acetylcholinesterase, P91 does not suffer suicide inhibition; instead, fast dephosphorylation rates make the formation of the covalent adduct rather than its hydrolysis rate-limiting. This step is improved by directed evolution, with intermediate formation accelerated by 2 orders of magnitude. Combining focused, combinatorial libraries with the ultrahigh throughput of droplet microfluidics can be leveraged to identify and enhance mechanistic strategies that have not reached high efficiency in nature, resulting in alternative reagents with novel catalytic machineries.
The recent massive release of new, man-made substances into the environment requires bioremediation, but a very limited number of enzymes evolved in response are available. When environments have not encountered the potentially hazardous materials in their evolutionary history, existing enzymes have to be repurposed. The recruitment of accidental, typically low-level promiscuous activities provides a head start that, after gene duplication, can adapt and provide a selectable advantage. This evolutionary scenario raises the question whether it is possible to adaptively improve the low-level activity of enzymes recruited from non- (or only recently) contaminated environments quickly to the level of evolved bioremediators.
Here we address the evolution of phosphotriesterases (enzymes for hydrolysis of organophosphate pesticides or chemical warfare agents) in such a scenario: In a previous functional metagenomics screening we had identified a promiscuous phosphotriesterase activity of the alpha/beta-hydrolase P91, with an unexpected Cys-His-Asp catalytic triad as the active site motif. We now probe evolvability of P91 using ultrahigh-throughput screening in microfluidic droplets, and test for the first time whether the unique catalytic motif of a cysteine-containing triad can adapt to achieve rates that rival existing phosphotriesterases. These mechanistically distinct enzymes achieve their high rates based on catalysis involving a metal-ion cofactor. A focussed, combinatorial library of P91 (> 105 members) was screened on-chip in microfluidic droplets by quantification of the reaction product, fluorescein. Within only two rounds of evolution P91's phosphotriesterase activity was increased ~ 400-fold to a kcat/KM of ~ 10 6 M-1 s-1, matching the catalytic efficiencies of naturally evolved metal-dependent phosphotriesterases. In contrast to its homologue acetylcholinesterase that suffers suicide inhibition, P91 shows fast de-phosphorylation rates and is rate-limited by the formation of the covalent adduct rather than by its hydrolysis. Our analysis highlights how the combination of focussed, combinatorial libraries with the ultrahigh throughput of droplet microfluidics can be leveraged to identify and enhance mechanistic strategies that have not reached high efficiency in Nature, resulting in alternative reagents with a novel catalytic machinery.
Unculturable bacterial communities provide a rich source of biocatalysts, but their experimental discovery by functional metagenomics is difficult, because the odds are stacked against the experimentor. Here we demonstrate functional screening of a million-membered metagenomic library in microfluidic picolitre droplet compartments. Using bait substrates, new hydrolases for sulfate monoesters and phosphotriesters were identified, mostly based on promiscuous activities presumed not to be under selection pressure. Spanning three protein superfamilies, these break new ground in sequence space: promiscuity now connects enzymes with only distantly related sequences. Most hits could not have been predicted by sequence analysis, because the desired activities have never been ascribed to similar sequences, showing how this approach complements bioinformatic harvesting of metagenomic sequencing data. Functional screening of a library of unprecedented size with excellent assay sensitivity has been instrumental in identifying rare genes constituting catalytically versatile hubs in sequence space as potential starting points for the acquisition of new functions.
