Hypomorphism in human NSMCE2 linked to primordial dwarfism and insulin resistance
Felicity Payne, … , Mark O’Driscoll, Robert Semple
Felicity Payne, … , Mark O’Driscoll, Robert Semple
Published August 8, 2014
Citation Information: J Clin Invest. 2014;124(9):4028-4038. https://doi.org/10.1172/JCI73264.
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Research Article Endocrinology

Hypomorphism in human NSMCE2 linked to primordial dwarfism and insulin resistance

Abstract

Structural maintenance of chromosomes (SMC) complexes are essential for maintaining chromatin structure and regulating gene expression. Two the three known SMC complexes, cohesin and condensin, are important for sister chromatid cohesion and condensation, respectively; however, the function of the third complex, SMC5–6, which includes the E3 SUMO-ligase NSMCE2 (also widely known as MMS21) is less clear. Here, we characterized 2 patients with primordial dwarfism, extreme insulin resistance, and gonadal failure and identified compound heterozygous frameshift mutations in NSMCE2. Both mutations reduced NSMCE2 expression in patient cells. Primary cells from one patient showed increased micronucleus and nucleoplasmic bridge formation, delayed recovery of DNA synthesis, and reduced formation of foci containing Bloom syndrome helicase (BLM) after hydroxyurea-induced replication fork stalling. These nuclear abnormalities in patient dermal fibroblast were restored by expression of WT NSMCE2, but not a mutant form lacking SUMO-ligase activity. Furthermore, in zebrafish, knockdown of the NSMCE2 ortholog produced dwarfism, which was ameliorated by reexpression of WT, but not SUMO-ligase–deficient NSMCE. Collectively, these findings support a role for NSMCE2 in recovery from DNA damage and raise the possibility that loss of its function produces dwarfism through reduced tolerance of replicative stress.

Authors

Felicity Payne, Rita Colnaghi, Nuno Rocha, Asha Seth, Julie Harris, Gillian Carpenter, William E. Bottomley, Eleanor Wheeler, Stephen Wong, Vladimir Saudek, David Savage, Stephen O’Rahilly, Jean-Claude Carel, Inês Barroso, Mark O’Driscoll, Robert Semple

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Figure 5

Modeling of NSMCE2/MMS21 deficiency in zebrafish.

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Modeling of NSMCE2/MMS21 deficiency in zebrafish. Injection of splice-si...
Injection of splice-site MOs targeted to Nsmce2 markedly reduce body size compared with that of control-injected or uninjected WT embryos. (A) Representative images of some arbitrarily defined length categories: normal, –1 to 1 SD; short, –1 to –2 SD; dwarf, –2 to –3 SD; severe, < –3 SD. (B) Quantification of length of MO-injected zebrafish (uninjected, n = 18; control, n = 28; MO, n = 37). (CE) Coinjection of WT human NSMCE2/MMS21 mRNA (WT rescue) with nsmce2-targeting MOs attenuated the dwarf phenotype observed in the nsmce2 morphant alone (morph). In contrast, coinjection of either (C) human NSMCE2/MMS21 S116Lfs*18, (D) human NSMCE2/MMS21 A234Efs*4, or (E) SUMO LD human NSMCE2/MMS21 mRNAs together with nsmce2-targeting MOs did not affect the severity of the dwarf phenotype. Uninj, uninjected; con, control. Graphs show SD scores relative to those of uninjected WT zebrafish embryos from the same mating. n = 12–15 for each condition. P values were calculated by ANOVA with post-hoc Tukey test; **P < 0.01, ***P < 0.001.