The chondrodysplasias are a group of >450 different phenotypes (1) that occur when endochondral bone growth is disrupted (2). The clinical presentation of chondrodysplasia varies from mild to lethal but is generally distinguished by disproportionate short stature. Multiple epiphyseal dysplasia (MED) is characterized by delayed and irregular endochondral ossification and early-onset osteoarthritis (3, 4). MED is genetically heterogeneous, and autosomal-dominant forms of the disease arise from mutations in the genes encoding matrilin 3, cartilage oligomeric matrix protein (COMP), and type IX collagen (3–5). Although present in other musculoskeletal tissues, matrilin 3, COMP, and type IX collagen are expressed primarily by chondrocytes and have been shown to interact with each other, both in vitro and in vivo (6–13). The matrilins are a family of 4 noncollagenous extracellular matrix (ECM) proteins. Each matrilin monomer comprises a C-terminal α-helical coiled-coil oligomerization domain, a varying number of epidermal growth factor–like domains, and 1 (matrilin 3) or 2 (matrilins 1, 2, and 4) von Willebrand factor A domains (6, 14). Matrilin proteins bind to numerous ECM components, including type II collagen, type IX collagen, aggrecan, COMP, biglycan, and decorin, and are believed to act as adaptor proteins in the ECM (6). More than 20 different missense mutations within the matrilin 3 gene have been shown to cause autosomal-dominant MED, and MATN3 mutations are believed to account for ∼20% of all cases of autosomal-dominant MED (5). The majority of MATN3 mutations affect residues that are located within the central β-sheet of the single A domain of matrilin 3 (5, 15–17), while a smaller proportion of mutations that affect residues in the α-helices of the same domain have recently been described (5, 18, 19). Several different cell culture model systems have been used in the past to study the effect of matrilin 3 mutations in vitro (15, 19, 20). The most striking effect of MATN3 mutations was the intracellular retention of mutant protein in cells in culture and also in patient cartilage. This distinctive finding was recently verified in a murine model of MED caused by a Matn3 V194D mutation, which replicated the human phenotype by exhibiting mild short-limbed dwarfism (21, 22). In this murine model, mutant matrilin 3 was retained within the endoplasmic reticulum (ER) of chondrocytes from the growth plates of endochondral bones. The retention of mutant matrilin 3 elicited a conventional unfolded protein response characterized by the up-regulation of classic chaperone proteins such as BiP/glucose-regulated protein 78-kd, calnexin, and calreticulin, as well as less-characterized ER stress–associated genes such as Creld2 and Armet/Manf (22). Despite intracellular retention of the majority of mutant matrilin 3 in vivo, a small proportion of mutant protein was secreted into the ECM, even in mice that were homozygous for the V194D mutation (21). The structural and/or functional effect of this mutant matrilin 3 in the ECM is not known, nor is the extent to which its presence in the ECM might contribute to the chondrodysplasia phenotype. Given the widespread literature describing the hetero-oligomerization of matrilin 3 with matrilin 1 (23–26), we considered the possibility that the secretion of mutant matrilin 3 may be dependent on its oligomerization into heterotetramers containing wild-type matrilin 1. We hypothesized that deletion of matrilin 1, which would abolish the formation of matrilin 1/matrilin 3 heterotetramers, would also eliminate the secretion of mutant matrilin 3 into the ECM and increase the severity of chondrodysplasia in mice with the Matn3 V194D mutation. A study testing this hypothesis would provide new insight into the disease mechanisms of MED and the role of hetero-oligomerization on the trafficking and secretion of matrilin 1/matrilin 3 proteins. We therefore crossed mice with the Matn3 V194D (Matn3m/m) mutation with Matn1−/− mice and generated a novel mouse line that was homozygous for the Matn3 V194D mutation and null for matrilin 1 (Matn1−/−Matn3m/m). We investigated the phenotypic, morphologic, and biochemical characterization of this novel murine model to determine the interdependency of matrilin 1 and matrilin 3 oligomerization on the trafficking and secretion of these proteins and their effect on disease severity.