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Publication Abstract from PubMed

Caspase-3 activation and function has been well defined during programmed cell death, but caspase activity, at low levels, is also required for developmental processes such as lymphoid proliferation and erythroid differentiation. Post-translational modification of caspase-3 is one method used by cells to fine-tune activity below the threshold required for apoptosis, but the allosteric mechanism that reduces activity is unknown. Phosphorylation of caspase-3 at a conserved allosteric site by p38-MAPK promotes survival in human neutrophils, and the modification of the loop is thought to be a key regulator in many developmental processes. We utilized phylogenetic, structural, and biophysical studies to define the interaction networks that facilitate the allosteric mechanism in caspase-3. We show that, within the modified loop, S150 evolved with the apoptotic caspases, while T152 is a more recent evolutionary event in mammalian caspase-3. Substitutions at S150 result in a pH-dependent decrease in dimer stability, and localized changes in the modified loop propagate to the active site of the same protomer through a connecting surface helix. Likewise, a cluster of hydrophobic amino acids connects the conserved loop to the active site of the second protomer. The presence of T152 in the conserved loop introduces a "kill switch" in mammalian caspase-3 while the more ancient S150 reduces without abolishing enzyme activity. These data reveal how evolutionary changes in a conserved allosteric site result in both a common pathway for lowering activity during development as well as introducing a more recent cluster-specific switch to abolish activity.

Modifications to a common phosphorylation network provide individualized control in caspases.,Thomas ME, Grinshpon R, Swartz P, Clark AC J Biol Chem. 2018 Feb 5. pii: RA117.000728. doi: 10.1074/jbc.RA117.000728. PMID:29414778^[3]

From MEDLINE®/PubMed®, a database of the U.S. National Library of Medicine.