A multifunctional surfactant catalyst inspired by hydrolases

Nothling, Mitchell D.; Xiao, Zeyun; Hill, Nicholas S.; Blyth, Mitchell T.; Bhaskaran, Ayana; Sani, Marc‐Antoine; Espinosa-Gomez, Andrea; Ngov, Kevin; White, Jonathan M.; Buscher, Tim; Separovic, Frances; O’Mara, Megan L.; Coote, Michelle L.; Connal, Luke A.

doi:10.1126/sciadv.aaz0404

Cited by 46 publications

(30 citation statements)

References 73 publications

(91 reference statements)

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“…Synthetic esterases are one of the most studied enzyme-mimicking cataysts. , Recent examples, built on peptide or purely abiotic scaffolds, commonly contain either a Lewis acidic metal ion such as zinc to activate water ,− or a catalytic triad to mimic those found in serine proteases. − Although these studies used different reaction conditions, the catalytic efficiency of MINP( 1 + 5e ) ( k cat / K m = 343 M –1 s –1 at pH 7, 25 °C) compared favorably with those of previously reported systems for PNPA hydrolysis ( k cat / K m = 2–100 M –1 s –1 at pH 6.2–8.0, 22–25 °C), and was close to that (450 M –1 s –1 ) of a synthetic esterase (formed from amyloid fibrils) at pH 8, 38 °C, under high pressure (200 MPa) . The catalytic turnover number (TON) of MINP( 1 + 5e ) was >510 (Figure b), also significantly higher than those in the literature (mostly >10–20). − …”

mentioning

confidence: 73%

Selective Hydrolysis of Aryl Esters under Acidic and Neutral Conditions by a Synthetic Aspartic Protease Mimic

Bose

Zhao

2021

ACS Catal.

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Aspartic proteases use a pair of carboxylic acids to activate water molecules for nucleophilic attack. Here we report a nanoparticle catalyst with a similar catalytic motif capable of generating a hydroxide ion in its active site even under acidic reaction conditions. The synthetic enzyme accelerated the hydrolysis of para-nitrophenyl acetate (PNPA) by 91 000 times and could also hydrolyze nonactivated aryl esters at pH 7. The distance between the two acids and, in particular, the flexibility of the catalytic groups in the active site controlled the catalytic efficiency. The synthetic enzyme readily detected the addition of a single methyl on the acyl group of the substrate, as well as the substitution pattern on the phenyl ring.

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confidence: 73%

Selective Hydrolysis of Aryl Esters under Acidic and Neutral Conditions by a Synthetic Aspartic Protease Mimic

Bose

Zhao

2021

ACS Catal.

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“…It has been shown that catalytic triads from serine proteases (H, S, and D residues) that have been incorporated in a designed lipopeptide-like molecule lead to an effective hydrolase. 197 The peptide surfactant coassembles with conventional cationic surfactants into spherical micelles. Other researchers have explored the use of peptides as agents to bind and template nanoparticles such as gold and silver nanoparticles with a diversity of catalytic properties.…”

Section: Peptide Catalysts With Metal Nanoparticlesmentioning

confidence: 99%

Section: Peptide Catalysts With Metal Nanoparticlesmentioning

confidence: 99%

Biocatalysts Based on Peptide and Peptide Conjugate Nanostructures

Hamley

2021

Biomacromolecules

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Peptides and their conjugates (to lipids, bulky N-terminals, or other groups) can self-assemble into nanostructures such as fibrils, nanotubes, coiled coil bundles, and micelles, and these can be used as platforms to present functional residues in order to catalyze a diversity of reactions. Peptide structures can be used to template catalytic sites inspired by those present in natural enzymes as well as simpler constructs using individual catalytic amino acids, especially proline and histidine. The literature on the use of peptide (and peptide conjugate) α-helical and β-sheet structures as well as turn or disordered peptides in the biocatalysis of a range of organic reactions including hydrolysis and a variety of coupling reactions (e.g., aldol reactions) is reviewed. The simpler design rules for peptide structures compared to those of folded proteins permit ready ab initio design (minimalist approach) of effective catalytic structures that mimic the binding pockets of natural enzymes or which simply present catalytic motifs at high density on nanostructure scaffolds. Research on these topics is summarized, along with a discussion of metal nanoparticle catalysts templated by peptide nanostructures, especially fibrils. Research showing the high activities of different classes of peptides in catalyzing many reactions is highlighted. Advances in peptide design and synthesis methods mean they hold great potential for future developments of effective bioinspired and biocompatible catalysts.

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“…Further, recent design of minimal peptide based soft nanostructures has been exploited to mimic the advanced function of evolved hydrolytic enzymes. [75][76][77][78][79][80][81][82][83][84][85][86][87][88][89][90][91] In this regard, Stupp and co-workers have designed a peptide amphiphile (histidine groups linked with the N-terminal of KLLLAAA-palmitoyl) with exposed histidine groups that selfassembled to form fibrillar nanostructures which showed excellent hydrolytic activity of the model substrate 2,4-dinitrophenyl acetate. The work highlighted that supramolecular assemblies could expose catalytic residues towards the solvent to feature esterase like activity.…”

Section: Peptide Assemblies For Diverse Enzymatic Transformationsmentioning

confidence: 99%