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Microfluidic deep mutational scanning of the human executioner caspases reveals differences in structure and regulation

Hridindu Roychowdhury, Philip A. Romero

2022Cell Death Discovery15 citationsDOIOpen Access PDF

Abstract

The human caspase family comprises 12 cysteine proteases that are centrally involved in cell death and inflammation responses. The members of this family have conserved sequences and structures, highly similar enzymatic activities and substrate preferences, and overlapping physiological roles. In this paper, we present a deep mutational scan of the executioner caspases CASP3 and CASP7 to dissect differences in their structure, function, and regulation. Our approach leverages high-throughput microfluidic screening to analyze hundreds of thousands of caspase variants in tightly controlled in vitro reactions. The resulting data provides a large-scale and unbiased view of the impact of amino acid substitutions on the proteolytic activity of CASP3 and CASP7. We use this data to pinpoint key functional differences between CASP3 and CASP7, including a secondary internal cleavage site, CASP7 Q196 that is not present in CASP3. Our results will open avenues for inquiry in caspase function and regulation that could potentially inform the development of future caspase-specific therapeutics.

Topics & Concepts

CaspaseProteasesBiologyCell biologyCysteineComputational biologyCaspase 2ApoptosisProgrammed cell deathBiochemistryEnzymeAutophagy in Disease and TherapyCRISPR and Genetic EngineeringEndoplasmic Reticulum Stress and Disease
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