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Abstract The chemiluminescent light‐emission pathway of phenoxy‐1,2‐dioxetane luminophores attracts growing interest within the scientific community. Dioxetane probes undergoing rapid flash‐type chemiexcitation exhibit higher detection sensitivity than those with a slow glow‐type chemiexcitation rate. We discovered that dioxetanes fused to non‐strained six‐member rings, with hetero atoms or inductive electron‐withdrawing groups, present both accelerated chemiexcitation rates and elevated chemical stability compared to dioxetanes fused to four‐member strained rings. DFT computational simulations supported the chemiexcitation acceleration observed by spiro‐fused six‐member rings with inductive electron‐withdrawing groups of dioxetanes. Specifically, a spiro‐dioxetane with a six‐member sulfone ring exhibited a chemiexcitation rate 293‐fold faster than that of spiro‐adamantyl‐dioxetane. A turn‐ON dioxetane probe for the detection of the enzyme β‐galactosidase, containing the six‐member sulfone unit, exhibited a S/N value of 108 in LB cell growth medium. This probe demonstrated a substantial increase in detection sensitivity towardsE. colibacterial cells expressing β‐galactosidase, with an LOD value that is 44‐fold more sensitive than that obtained by the adamantyl counterpart. The accelerated chemiexcitation and the elevated chemical stability presented by dioxetane containing a spiro‐fused six‐member ring with a sulfone inductive electron‐withdrawing group, make it an ideal candidate for designing efficient turn‐on chemiluminescent probes with exceptionally high detection sensitivity. 

A Cu or Fe-catalyzed radical ring expansion/coupling cascade was developed. It provides a new access to medium-sized and macrolactones with CN, N₃, SCN, and X groups. DFT calculations suggest a Cu(i)/Cu(ii)/Cu(iii) catalytic cycle for the cyanation. 

We herein report a phosphine-catalyzed (3 + 2) annulation of cyclopropenones with a wide variety of electrophilic π systems, including aldehydes, ketoesters, imines, isocyanates, and carbodiimides, offering products of butenolides, butyrolactams, maleimides, and iminomaleimides, respectively, in high yields with broad substrate scope. An α-ketenyl phosphorous ylide is validated as the key intermediate, which undergoes preferential catalytic cyclization with aldehydes rather than stoichiometric Wittig olefinations. This phosphine-catalyzed activation of cyclopropenones thus supplies a versatile C 3 synthon for formal cycloadditon reactions. 

Abstract De novo enzyme design has sought to introduce active sites and substrate-binding pockets that are predicted to catalyse a reaction of interest into geometrically compatible native scaffolds^1,2, but has been limited by a lack of suitable protein structures and the complexity of native protein sequence–structure relationships. Here we describe a deep-learning-based ‘family-wide hallucination’ approach that generates large numbers of idealized protein structures containing diverse pocket shapes and designed sequences that encode them. We use these scaffolds to design artificial luciferases that selectively catalyse the oxidative chemiluminescence of the synthetic luciferin substrates diphenylterazine³and 2-deoxycoelenterazine. The designed active sites position an arginine guanidinium group adjacent to an anion that develops during the reaction in a binding pocket with high shape complementarity. For both luciferin substrates, we obtain designed luciferases with high selectivity; the most active of these is a small (13.9 kDa) and thermostable (with a melting temperature higher than 95 °C) enzyme that has a catalytic efficiency on diphenylterazine (k_cat/K_m = 10⁶ M⁻¹ s⁻¹) comparable to that of native luciferases, but a much higher substrate specificity. The creation of highly active and specific biocatalysts from scratch with broad applications in biomedicine is a key milestone for computational enzyme design, and our approach should enable generation of a wide range of luciferases and other enzymes.