MMP13 mutation causes spondyloepimetaphyseal dysplasia, Missouri type (SEMDMO)
Ann M. Kennedy, … , Michael P. Whyte, Rajesh V. Thakker
Ann M. Kennedy, … , Michael P. Whyte, Rajesh V. Thakker
Published October 3, 2005
Citation Information: J Clin Invest. 2005;115(10):2832-2842. https://doi.org/10.1172/JCI22900.
View: Text | PDF
Research Article Bone biology

MMP13 mutation causes spondyloepimetaphyseal dysplasia, Missouri type (SEMDMO)

Abstract

MMPs, which degrade components of the ECM, have roles in embryonic development, tissue repair, cancer, arthritis, and cardiovascular disease. We show that a missense mutation of MMP13 causes the Missouri type of human spondyloepimetaphyseal dysplasia (SEMDMO), an autosomal dominant disorder characterized by defective growth and modeling of vertebrae and long bones. Genome-wide linkage analysis mapped SEMDMO to a 17-cM region on chromosome 11q14.3–23.2 that contains a cluster of 9 MMP genes. Among these, MMP13 represented the best candidate for SEMDMO, since it preferentially degrades collagen type II, abnormalities of which cause skeletal dysplasias that include Strudwick type SEMD. DNA sequence analysis revealed a missense mutation, F56S, that substituted an evolutionarily conserved phenylalanine residue for a serine in the proregion domain of MMP13. We predicted, by modeling MMP13 structure, that this F56S mutation would result in a hydrophobic cavity with misfolding, autoactivation, and degradation of mutant protein intracellularly. Expression of wild-type and mutant MMP13s in human embryonic kidney cells confirmed abnormal intracellular autoactivation and autodegradation of F56S MMP13 such that only enzymatically inactive, small fragments were secreted. Thus, the F56S mutation results in deficiency of MMP13, which leads to the human skeletal developmental anomaly of SEMDMO.

Authors

Ann M. Kennedy, Masaki Inada, Stephen M. Krane, Paul T. Christie, Brian Harding, Carlos López-Otín, Luis M. Sánchez, Anna A.J. Pannett, Andrew Dearlove, Claire Hartley, Michael H. Byrne, Anita A.C. Reed, M. Andrew Nesbit, Michael P. Whyte, Rajesh V. Thakker

×

Figure 7

Options: View larger image (or click on image) Download as PowerPoint
Analysis of expression of wild-type and mutant MMP13 cDNAs. All construc...
Analysis of expression of wild-type and mutant MMP13 cDNAs. All constructs have Myc tags. (A) Effects of monensin on secretion of WT and F56S MMP13. (B) Effects of E204A mutation. Two separate transfectants of F56S/E204A MMP13 are shown. (C) Activation of WT MMP13, with APMA, results in autodegradation and generation of lower-molecular-mass fragments. (D) Activation of WT MMP13 and E204A MMP13 are compared as in C. E204A MMP13 is not activated by APMA. (E) Secretion and autodegradation of mutant C77S MMP13. MMP13 mutants F56S and C77S are degraded to low-molecular-mass fragments. (F) Comparison of stable and transient transfectants. Protein products encoded by transient (HEK293T) and stable (HEK293) transfectants of WT and mutant F56S MMP13 cDNAs behaved similarly. (G) Transient cotransfection of Flag-tagged WT MMP13 cDNA into HEK293 cells stably expressing untagged WT or mutant F56S MMP13. Flag-tagged WT proMMP13 is normally secreted when expressed in cells stably transfected with empty vector or untagged WT MMP13 but is partially autoactivated and degraded (arrows) when expressed in cells stably expressing F56S MMP13. (H) Secretion and autodegradation of mutant F56S, F55T, and F222S MMP13. Transient transfection of F56S and F55T MMP13 cDNAs showed abundant low-molecular-mass fragments but no proenzyme. Transfection with F222S MMP13 cDNA revealed full-length proenzyme and low-abundance low-molecular-mass fragments (arrow). Results in all panels are based on experiments using conditioned medium unless otherwise stated.