The IFITM5 mutation in osteogenesis imperfecta type V is associated with an ERK/SOX9-dependent osteoprogenitor differentiation defect

Osteogenesis imperfecta (OI) type V is the second most common form of OI, distinguished by hyperplastic callus formation and calcification of the interosseous membranes in addition to bone fragility. All patients carry a dominant pathogenic variant (c.-14C>T) in IFITM5. Here, we generated a conditional Rosa26 knock-in mouse model to study the mechanistic consequences of the recurrent mutation. Expression of the mutant Ifitm5 in osteo-chondroprogenitor or chondrogenic cells resulted in low bone mass and growth retardation. Mutant limbs showed impaired endochondral ossification, cartilage overgrowth, and abnormal growth plate architecture. The cartilage phenotype correlates with the pathology reported in OI type V patients. Surprisingly, expression of mutant Ifitm5 in matrix-synthesizing or mature osteoblasts caused no obvious skeletal abnormalities. In contrast, earlier expression in osteo-chondroprogenitors was associated with increase in the skeletal progenitor population within the periosteum. Mutant IFITM5 disrupts early skeletal homeostasis in part by activating ERK signaling and downstream SOX9 protein, and inhibition of these pathways partially rescued the phenotype in mutant animals. . Tracing of chondrogenic cells expressing the mutant Ifitm5 using the Ai9 reporter showed retention of Ai9+ cells in the growth plate and delayed migration to the bone shaft. RNA sequencing demonstrated enrichment for chondrogenic markers in the bone. These data identify the contribution of a defect in osteo-chondroprogenitor differentiation and not osteoblast function as a driver in the pathogenesis of OI type V. We performed bulk RNA sequencing in Rosa26mIfitm5;Acan-Cre ERT2 mouse femurs to search for downstream transcriptomic changes in the long bones following activation of the mutant Ifitm5 allele in chondrocytes from P10-15. 3 mutant mice and 3 control mice were analyzed.