Osteogenesis imperfecta mutations in plastin 3 lead to impaired calcium regulation of actin bundling

Mutations in actin-bundling protein plastin 3(PLS3)emerged as a cause of congenital osteoporosis,but neither the role of PLS3 in bone development nor the mechanisms underlying PLS3-dependent osteoporosis are understood.Of the over 20 identified osteoporosis-linked PLS3 mutations,we investigated all five that are expected to produce full-length protein.One of the mutations distorted an actin-binding loop in the second actin-binding domain of PLS3 and abolished F-actin bundling as revealed by cryo-EM reconstruction and protein interaction assays.Surprisingly,the remaining four mutants fully retained F-actin bundling ability.However,they displayed defects in Ca2+sensitivity:two of the mutants lost the ability to be inhibited by Ca2+;while the other two became hypersensitive to Ca2a.Each group of the mutants with similar biochemical properties showed highly characteristic cellular behavior.Wild-type PLS3 was distributed between lamellipodia and focal adhesions.In striking contrast,the Ca2+-hyposensitive mutants were not found at the leading edge but localized exclusively at focal adhesions/stress fibers,which displayed reinforced morphology.Consistently,the Ca2+-hypersensitive PLS3 mutants were restricted to lamellipodia,while chelation of Ca2+caused their redistribution to focal adhesions.Finally,the bundling-deficient mutant failed to co-localize with any F-actin structures in cells despite a preserved F-actin binding through a non-mutation-bearing actin-binding domain.Our findings revealed that severe osteoporosis can be caused by a mutational disruption of the Ca2+-controlled PLS3’s cycling between adhesion complexes and the leading edge.Integration of the structural,biochemical,and cell biology insights enabled us to propose a molecular mechanism of plastin activity regulation by Ca2+.