1. Skeletal dysplasias resulting from mutations in cartilage structural proteins

IJMM

International Journal of Molecular Medicine

1107-3756 1791-244X

D.A. Spandidos

10.3892/ijmm.2015.2158

ijmm-35-06-1483

Articles

The utility of mouse models to provide information regarding the pathomolecular mechanisms in human genetic skeletal diseases: The emerging role of endoplasmic reticulum stress (Review)

BRIGGS

MICHAEL D.

BELL

PETER A.

PIROG

KATARZYNA A.

Institute of Genetic Medicine, Newcastle University, International Centre for Life, Newcastle upon Tyne, NE1 3BZ, UK

Correspondence to: Professor Michael Briggs, Institute of Genetic Medicine, Newcastle University, International Centre for Life, Central Parkway, Newcastle upon Tyne, NE1 3BZ, UK, E-mail: michael.briggs@newcastle.ac.uk

7 2015

30 03 2015

35 6 1483 1492 11 02 2015 30 03 2015

2015

This is an open-access article licensed under a Creative Commons Attribution-NonCommercial 3.0 Unported License. The article may be redistributed, reproduced, and reused for non-commercial purposes, provided the original source is properly cited.

Genetic skeletal diseases (GSDs) are an extremely diverse and complex group of rare genetic diseases that primarily affect the development and homeostasis of the osseous skeleton. There are more than 450 unique and well-characterised phenotypes that range in severity from relatively mild to severe and lethal forms. Although individually rare, as a group of related genetic diseases, GSDs have an overall prevalence of at least 1 per 4,000 children. Qualitative defects in cartilage structural proteins result in a broad spectrum of both recessive and dominant GSDs. This review focused on a disease spectrum resulting from mutations in the non-collagenous glycoproteins, cartilage oligomeric matrix protein (COMP) and matrilin-3, which together cause a continuum of phenotypes that are amongst the most common autosomal dominant GSDs. Pseudoachondroplasia (PSACH) and autosomal dominant multiple epiphyseal dysplasia (MED) comprise a disease spectrum characterised by varying degrees of disproportionate short stature, joint pain and stiffness and early-onset osteoarthritis. Over the past decade, the generation and deep phenotyping of a range of genetic mouse models of the PSACH and MED disease spectrum has allowed the disease mechanisms to be characterised in detail. Moreover, the generation of novel phenocopies to model specific disease mechanisms has confirmed the importance of endoplasmic reticulum (ER) stress and reduced chondrocyte proliferation as key modulators of growth plate dysplasia and reduced bone growth. Finally, new insight into related musculoskeletal complications (such as myopathy and tendinopathy) has also been gained through the in-depth analysis of targeted mouse models of the PSACH-MED disease spectrum.

skeletal dysplasia cartilage endoplasmic reticulum stress mouse models disease mechanisms pseudoachondroplasia multiple epiphyseal dysplasia

1. Skeletal dysplasias resulting from mutations in cartilage structural proteins

Qualitative (i.e., dominant-negative or antimorphic mutations) defects in cartilage structural proteins result in a diverse range of both recessive and dominant genetic skeletal dysplasias (Table I). These structural proteins include cartilage collagens (types II, IX and XI), proteoglycans (aggrecan) and glycoproteins [cartilage oligomeric matrix protein (COMP) and matrilin-3 (MATN3)] and many of the mutations are predicted to affect the folding and/or function of these important molecules. This review specifically concentrates on those diseases resulting from mutations in the non-collagenous glycoproteins, COMP and matrilin-3, which together cause a continuum of phenotypes that are amongst the most common autosomal dominant skeletal dysplasias.

The pseudoachondroplasia (PSACH) and multiple epiphyseal dysplasia (MED) disease spectrum: the generation and study of genetic mouse models. Originally believed to be different but clinically related phenotypes, it was gene and mutation identification in the 1990s that demonstrated that PSACH and some forms of MED were allelic diseases resulting from mutations in COMP (1). However, MED is genetically heterogeneous and autosomal dominant forms can also result from mutations in the genes encoding matrilin-3 and type IX collagen (2) (Table I).

Despite the first mutations being identified in COMP, MATN3 and the type IX collagen genes in the six years between 1995 and 2001 (Table I), very little progress has been made in understanding disease mechanisms despite numerous cell culture studies (reviewed in ref. 3). A lack of relevant pathological tissues (such as cartilage growth plate), and the obvious limitations of cell culture models to study long bone growth, meant that only small incremental increases in knowledge were possible.

Over the past eight years, however, a number of different genetic approaches have been used to generate mouse models of PSACH-MED that recapitulate the various phenotypes and allow disease mechanisms to be studied in detail in vivo (Table II). Moreover, the generation of novel phenocopies to model specific disease mechanisms have confirmed the importance of endoplasmic reticulum (ER) stress and chondrocyte proliferation as key modulators of growth plate dysplasia. Finally, new insight into related musculoskeletal complications (such as myopathy and tendinopathy), which may be of clinical utility, has also been gained through the in-depth analysis of targeted mouse models of the PSACH-MED disease spectrum.

2. Knock-in mouse models provide new insight into disease mechanisms

The application of homologous recombination and Cre-lox technology has allowed the generation of a series of mouse lines that genetically modelled phenotypes within the PSACH-MED disease spectrum, thereby allowing key pathological findings to be described and disease mechanisms to be studied in detail (Tables II and III).

In the first instance, an allelic series of PSACH models were generated representing the two major classes of COMP mutations: the type III repeat (T3) region and the carboxyl-terminal domain (CTD) (2,4). Type III repeat region mutations account for approximately 85% of all COMP-related PSACH-MED, whereas CTD mutations represent 15% of cases (2). The mutations that were selected to represent these two different classes were the common in-frame deletion of an aspartic acid residue from the C-type motif of repeat T3₇ (p.Asp469del), which accounts for 30% of all PSACH, and the recurrent p.Thr585Met missense mutation in the CTD (2,4). The p.Thr585Met mutation has been reported in four different studies and results in a phenotypic spectrum ranging from MED to mild PSACH (4). Previous studies using cell models consistently demonstrated the retention of mutant Asp469del COMP in the ER (3). By contrast, p.Thr585Met, along with several other CTD mutations, was efficiently secreted into the culture media of various cell models (5,6). These early cell model studies have suggested different disease mechanisms between these two classes of mutations that justified validation and in-depth analysis using relevant mouse models.

The p.Thr585Met (CompT585M) model of mild PSACH/severe MED

Individuals with p.Thr585Met [and several other CTD mutations (4)] often present with a mild form of PSACH and this was reflected in the Comp^T585M mouse model which showed only a 5% reduction in bone length at 9 weeks of age (7). This is consistent with previous family studies, which demonstrated that individuals with the Thr585Met mutation may have average stature, despite having significant epiphyseal and metaphyseal changes in the large joints (8).

Immunohistochemistry and electron microscopy confirmed a lack of mutant protein retention in the ER (Figs. 1 and 2), which is consistent with previous cell culture studies (5,6). However, there were severe disruptions to the morphology of the growth plate and to the size, shape and arrangement of individual chondrocytes and chondrons (7). The composition of the growth plate extracellular matrix (ECM) was also disrupted with changes to the localisation of several ECM proteins and the under-sulfation of proteoglycans (7). Proteomic interrogation confirmed changes to the extractability of several ECM proteins, including collagens [α1(XIV), α1(IX), α1(XI), α1(XII) and α6(VI)], laminin β2 and fibronectin (9). Finally, there was a significant reduction in chondrocyte proliferation that was accompanied by increased and spatially dysregulated apoptosis (7) (Table III).

The p.Asp469del (CompD469del) model of typical severe PSACH

p.Asp469del is the most common COMP mutation and invariably results in typically severe PSACH (4,5). Numerous cell culture studies have been undertaken on this archetypal mutation, which have consistently shown that p.Asp469del results in the retention of mutant COMP protein within the rough ER (rER) of cells, along with matrilin-3 and collagen type IX (10,11). Furthermore, cartilage samples from PSACH patients appear to have a disorganised ECM and there is an increase in cell death in vivo (12) that can be recapitulated in vitro by several different cell culture models (13,14).

Comp^D469del mice were normal at birth, but grew slower than their wild-type littermates and developed a progressive short-limb dwarfism, which was characterised by a 5–6% reduction in final tibia and femur lengths. Moreover, the mutant mice developed a hip dysplasia that was characterised by an increase in the angle of deflection from the vertical of the tuberosity of the ischium (15). The reductions in the final bone lengths of Comp^D469del mice were less than would be expected for a phenotypically exact model of typical severe PSACH and may be best explained by the mixed genetic background of the mutant mouse strain.

Notwithstanding the relatively mild reduction in final bone lengths of Comp^D469del mice, there was significant growth plate pathology that was illustrative of the hallmarks of PSACH (15) (Table III). In particular, chondrocyte columns were reduced in number and poorly organised in the growth plates of Comp^D469del mice, whilst mutant COMP was retained within the ER of chondrocytes at all stages of differentiation (15) (Fig. 1). The composition and appearance of the ECM was disrupted, with changes to the localisation of several ECM proteins, including the co-retention of matrilin-3 and type IX collagen (15). Proteomic interrogation confirmed changes to the extractability of several ECM proteins, including throm-bospondin-3 and -4, several collagens [α1(XIV), α1(IX) and α1(VI)], tenascin-C and -X and epiphycan (9). Most noticeably, chondrocyte proliferation was significantly reduced and apoptosis was greatly increased in the proliferative zone and spatially dysregulated throughout the entire growth plate (15) (Table III).

The p.Val194Asp (Matn3V194D) model of moderate MED

Missense mutations and small in-frame deletions in the von Willebrand Factor A (vWFA) domain of matrilin-3 cause moderate to severe forms of MED (2). The various missense mutations are distributed between the β-sheet (~85%) and α-helical (~15%) regions of the vWFA domain. Mutations in the β-sheet regions primarily disrupt the folding of the vWFA domain, resulting in the retention of mutant protein in the ER of cells (16). By contrast, some α-helical mutations allow the correct folding and secretion of mutant matrilin-3 (17); however, there are exceptions to these generalisations. The MATN3 mutation (p.Val.194Asp) selected for mouse model generation was the first EDM5 mutation to be identified and is an archetypal example (18).

Matn3^V194D mice were normal at birth but developed short-limbed dwarfism that was characterised by a final reduction in tibia length of 12–13% (19). There was a significant retention of mutant matrilin-3 in the growth plate chondrocytes, which were abnormal in shape and resulted in poorly organised chondrons and chondrocyte columns (Figs. 1 and 2). Chondrocyte proliferation was significantly reduced and whilst there was no overall increase in apoptosis it was noticeably dysregulated with increased cell death occurring throughout the entire hypertrophic zone (19) (Table III). Changes to the appearance of the cartilage ECM may be partly attributable to differences in the extractability of various collagens [α1(XIV) and α3(VI)], osteomodulin, biglycan, tenascin-C and epiphycan (9).

3. Transgenic approaches for generating mouse models

Several transgenic approaches have also been used to generate mouse models of the common PSACH mutation, which do not rely on the targeted integration of a single copy of the mutant allele (Table II).

Standard transgenic approaches

In the first example, a transgenic mouse model was generated by Schmitz et al, in which rat Asp469del COMP cDNA expression was achieved through the Col2a1 promoter (20). Mutant COMP was over-expressed by ~40% and transgenic mutant male mice were up to 8% shorter than transgenic wild-type mice at 6 months of age. In an attempt to exacerbate this relatively mild phenotype, the transgenic mutant mice were crossed onto a Comp-null line to ensure that only rat COMP Asp469del was expressed by chondrocytes. This cross resulted in a male-specific increase in disease severity that was characterised by a further decrease in body and femur lengths. Chondrocytes within the proliferative zone showed the retention of the transgenic mutant COMP, the levels of which were further increased on the Comp-null background (20). Moreover, there were abnormal changes to the morphology of the cartilage ECM, including the loss of proteoglycans and changes to the localisation of other ECM molecules, such as type VI collagen, aggrecan and matrilin-1. Finally, increased apoptosis was observed in combination with distinct areas of hypocellularity and these key pathological features are now recognised as hallmark descriptors of the PSACH growth plate in vivo (20).

Subsequently, Posey et al hypothesised that the overexpression of Asp469del COMP would best recapitulate the PSACH disease phenotype in a mouse model and therefore used the inducible overexpression of mutant Comp that was driven from the Col2a1 promoter (21). One reason for taking this approach was as a consequence of limited phenotypic and pathological effects observed in earlier PSACH transgenic mice models (3), which highlights the unpredictability of standard transgenic approaches for developing mouse models of human genetic skeletal diseases (GSDs) (Table II).

In the first model, a BAC clone containing human COMP and its native promoter was used to generate two founders (1 male and 1 female) of which only the female demonstrated a clinical phenotype and both founders died prematurely (3). In a second approach, Asp469del COMP expression from human cDNA was driven by a mouse Col2a1 promoter and enhancer. Genomic analysis demonstrated that 12–20 copies of the transgene had integrated into mouse chromosome 10. Tibia measurements confirmed a 6% reduction in final length and there was some disorganization of the growth plate, with fewer chondrocytes organised into columns of chondrons; however, in contrast to the study by Schmitz et al (20), no intracellular retention of mutant Asp469del COMP was observed in growth plate chondrocytes (3).

Bigenic inducible overexpression of mutant Comp Asp469del

The most recent transgenic approach involved the generation of bigenic mice in which the expression of Comp Asp469del was controlled by a tetracycline responsive element promoter, which was itself under the control of the tetracycline trans-activator coding sequence with a Col2a1 promoter to ensure cartilage-specific expression (21). Whilst Col2a1-driven overexpression of Comp Asp469del was assumed to be robust, the levels of mutant Comp mRNA were only determined at E15 and shown to be 4- to 6-fold higher than endogenous Comp mRNA (21). Unfortunately, the relative levels of Comp Asp469del mRNA and protein were not determined at later time-points, thus limiting the interpretation of phenotypic and pathological readouts, particularly when these analyses were performed postnatally. Nevertheless, key pathological features such as mutant COMP retention, growth plate dysplasia and marginally increased chondrocyte apoptosis were identified in this mouse model (21). Subsequent developmental analysis of this mouse model (22) confirmed growth plate dysplasia by 3 weeks of age that was characterised by disorganization, reduced thickness and distinct areas of hypocellularity. Mutant Asp469del COMP retention was shown to be progressive until 2 weeks of age. Analysis of chondrocyte death by terminal deoxynucleotidyltransferase-mediated dUTP nick-end labelling (TUNEL) confirmed that abnormally increased apoptosis was occurring in the hypertrophic zone by 2 weeks of age, and increased further with age (~3–4-fold); however, the precise localisation of increased apoptosis within the different growth plate zones was not determined. Long bone growth was significantly reduced by 12% in the tibia; however, skull and snout lengths were also shown to be smaller than wild-type controls, indicating that intramembraneous ossification was also disrupted by the transgenic overexpression of mutant COMP, which is not consistent with other mouse models or individuals with PSACH. Moreover, the pathophysiological relevance of Comp Asp469del overexpression is not known and whilst strong phenotypic effects were observed, the genetic pathways that are induced by this transgenic approach may not necessarily be representative of the human disease.

4. Activation of canonical and/or novel ER stress pathways is genotype-specific

The expression of Comp^D469del and Matn3^V194D results in ER retention of the relevant mutant proteins and the co-retention of interacting partners that ultimately results in ER stress (15,19); however, the downstream stress pathways that are activated are genotype-specific.

For example, the expression of Matn3^V194D induces the activation of the canonical unfolded protein response (UPR), which is characterised by the upregulation of binding immunoglobulin protein (BiP) (a sentinel marker of UPR) and a broad range of chaperones, foldases and protein disulphide isomerases (23). Moreover, the downstream splicing of X-box binding protein 1 (Xbp1) in Matn3^V194D chondrocytes (and also in cell models) is symbolic of classical UPR; however, this prolonged ER stress does not result in a C/EBP-homologous protein (CHOP)-mediated increase in apoptosis (23) (and our unpublished observations).

In contrast to mutant matrilin-3, the ER retention of Comp^D469del does not induce a canonical UPR, but a novel form of ER stress that is characterised by changes in the expression of groups of genes implicated in oxidative stress, cell cycle regulation and apoptosis (15). Similar UPR-independent pathways, such as the ER overload response (EOR), appear to be associated with the aggregation of mutant proteins in the ER that eventually induce toxic gain-of-function (24). This has been noted with serpinopathies in which the aggregation of insoluble misfolded α1-antitrypsin triggers an alternative ER stress response that is independent of the UPR and involves the activation of nuclear factor-κB (NF-κB) signalling (25). Moreover, it has been proposed that an aggregating protein response (APR) is activated by glycine substitutions in the triple helical regions of type I collagen that also do not induce canonical UPR (26,27).

Our own studies have identified differences in the molecular organization of the mutant COMP and matrilin-3 proteins that are retained in the ER of mouse chondrocytes and cell culture models (9,28). Mutant matrilin-3 forms non-native disulphide bonded aggregates, due to a delay in the folding of the single vWFA domain, which may render it inaccessible to degradation. By contrast, mutant D469del COMP does not appear to aggregate and is retained in the ER in its apparent native state of either tetramers or pentamers (9). This difference in the molecular organization of mutant protein aggregates may play a role in determining which ER stress pathways are activated.

These unexpected findings demonstrate that ER stress, as a result of mutant protein misfolding, and the genetic pathways that are activated in an attempt to restore ER homeostasis, are likely to be more diverse in mouse models and human genetic diseases than in the more commonly studied chemically-induced ER stress experimental systems (29). However, despite the downstream activation of several potential pathways, such as UPR, APR and/or EOR, a common consequence appears to be the reduction in chondrocyte proliferation (Table III).

5. Common genetic pathways identified in the different mouse models of Asp469del COMP pseudoachondroplasia

Despite differences in the relative severity of growth plate dysplasia, chondrocyte cell death and long bone growth between the different Comp Asp469del mouse models (Table II), transcriptomic profiling has nevertheless implicated several genetic pathways in common (15,22).

The microarray analysis of mRNAs isolated from chondrocytes of the Comp^D469del knock-in mouse model showed a complex disease profile with expression changes in groups of genes implicated in oxidative stress, cell cycle regulation and apoptosis, which is consistent with the chondrocyte and growth plate pathology (15). Moreover, this study demonstrated that reduced cell proliferation and increased dysregulated chondrocyte apoptosis was associated with the downregulation of peroxiredoxin 2, which is a gene important for protecting cells against oxidative damage and also in regulating apoptosis (15). Similarly, transcriptomic analysis of mRNAs isolated from the chondrocytes of the bigenic transgenic mouse identified cell cycle regulation, inflammation, oxidative stress and DNA damage as the major classes of genes implicated in disease pathogenesis (22).

6. Missense mutations in matrilin-3 and COMP cause changes in the extractability of other cartilage proteins and influence ECM organization

Analysis of the cartilage proteome of Matn3^V194D, Comp^D469del and Comp^T585M mice has identified differences in the extractability of numerous structural ECM components relative to the controls (9). The extraction of type IX collagen [a fibril-associated collagen with interrupted triple helices (FACIT)] was increased in Comp^D469del and Comp^T585M mice, which may alter the integrity of the II/IX/XI heterofibrillar collagen network. Other changes in the extractability of FACIT collagens were observed in Matn3^V194D (i.e., the decreased extraction of collagen types XII and XIV), Comp^D469del (decrease in types IX and XIV) and Comp^T585M (decrease in types IX and XII, but increase in type XIV) cartilage, which further implied disruption to ECM organization as a consequence of Comp and Matn3 mutations that correlated with the observations of altered ECM morphology detected by electron microscopy (7,15,19) (Fig. 2).

In addition to these commonalities between mutant mouse models, discrete patterns of ECM protein extraction were also observed (9). Most notably, the extraction of tenascin X was greatly reduced from Comp^D469del cartilage; however, the functional significance of this, and also the increases in tenascin C extractability observed in Comp^D469del and Matn3^V194D mice, remains to be determined.

7. Novel phenocopies of chondrocyte-specific ER stress provide information regarding intracellular disease mechanisms and the influence of chondrocyte proliferation

Defining the relative contributions of intracellular disease mechanisms (ER stress) and extracellular defects (ECM disruption) to the initiation and progression of growth plate dysplasia is experimentally challenging. Therefore, to directly test the role of ER stress in growth plate dysplasia and reduced long bone growth, independent of disruptions to the cartilage ECM, a novel transgenic approach was taken. This approach was previously established and validated as an innovative tool to dissect disease mechanisms in metaphyseal chondrodysplasia type Schmid, which can be caused by missense mutations in the gene encoding type X collagen (30).

To delineate the relative influence of ER stress to the development of chondrodysplasia, the expression of a G2320R mutant form of thyroglobulin (Rdw) was targeted primarily to resting and proliferating chondrocytes using the Col2a1 promoter (31). The expression and retention of this mutant exogenous protein in the rER of growth plate chondrocytes resulted in chronic cell stress and reduced bone growth, but without inducing any disruptions to the architecture and overall organization of the ECM. More significantly, however, decreased bone growth appeared to be the direct result of reduced chondrocyte proliferation in the growth plates in transgenic mice.

8. Reduced chondrocyte proliferation is a shared cellular response to all forms of ER stress and defines a common denominator of PSACH-MED pathology

The pivotal role of ER stress in the initiation of growth plate dysplasia and abnormal bone growth was revealed through targeted knock-in mouse models and novel transgenic phenocopies (Table II). Whilst it has been previously suggested that increased and dysregulated chondrocyte apoptosis is the major cause of reduced bone growth in PSACH (22), our recent analysis of the Tg^Rdw transgenic phenocopy has demonstrated that reduced chondrocyte proliferation alone is sufficient to cause a significant reduction in bone length in the absence of increased apoptosis or extensive disruption to cartilage ECM composition and assembly (31). We therefore hypothesise that modulating chondrocyte proliferation is likely to exert the greatest influence on long bone growth in PSACH-MED and this may represent an attractive target for therapy. Indeed, dysregulated cyclin D1 signaling during the G1 phase of the cell-cycle causes reduced chondrocyte proliferation in a mouse model of diastrophic dysplasia due to a p.A386V substitution in the eighth transmembrane domain of solute carrier family 26 member 2 (Slc26a2) (32). Moreover, recent mouse model studies have demonstrated that long bone length can be restored in achondroplasia by targeting the mitogen-activated protein kinase (MAPK) pathway, which is activated by the tyrosine kinase receptor FGFR3 mutations in achondroplasia, and causes a disruption to normal chondrocyte differentiation (33). Finally, transgenic expression of mutant forms of type II collagen causes ER-stress induced chondrodysplasia (34,35), which can also defined by reduced chondrocyte proliferation and may be associated with disrupted cell polarity and the abnormal organization and morphology of the primary cilia (35).

9. Genetic background influences phenotypic severity in the <italic>Comp</italic>T585M mouse model of PSACH-MED by impacting on chondrocyte proliferation and apoptosis

Several clinical genetic studies have demonstrated that there is considerable intra- and interfamilial variability in disease presentation in both PSACH and MED, which strongly points to the existence of genetic modifiers of phenotypic severity. This is best highlighted by several MATN3 mutations, such as Arg121Trp, which are associated with marked interfamilial variability in the radiographic phenotype of patients (36). Patients carrying the T585M COMP mutation also show variability in final adult height (8).

In-bred mouse strains are a useful tool which can be used to study complex disease traits when the influence of a genetic modifier is suspected (37). Interestingly, crossing the Comp^T585M knock-in mice (originally on a mixed genetic background) onto a C57BL6/J inbred background has been shown to increase the severity of the phenotype by further disrupting chondrocyte proliferation, apoptosis and matrix deposition (38). Moreover, mutant COMP was retained inside the rER of chondrocytes, which was a feature not observed in the original mouse model (7). Dixon and Dixon (37) demonstrated a similar phenotypic variability in their model of craniofacial abnormalities in Treacher Collins Syndrome that is genetic background-dependent. This feature renders inbred mouse strains a valuable genetic model for quantitative trait loci (QTL) studies and the analysis of genetic modifiers co-segregating with various disease traits.

10. Insight into additional musculoskeletal complications of PSACH-MED revealed for the first time through the in-depth analysis of mouse models

Several skeletal dysplasias, including PSACH and MED, often result from mutations in the extracellular proteins that are synthesised by cells of the mesenchymal lineage (39). It is therefore not surprising that patients may present with additional related musculoskeletal complications (40). Mild PSACH/MED patients are sometimes diagnosed with mild myopathy or a ‘neuromuscular problem of unknown etiology’ prior to the confirmation of a chondrodysplasia. Indeed, we have previously reported several patients who initially presented with excessive fatigue during walking; difficulty rising from a squatting position and mildly elevated serum creatine kinase levels (39). These individuals were initially referred to neurological clinics for assessment, prior to the diagnosis of a skeletal dysplasia following radiographic evaluation. The analysis of muscle biopsies often proved inconclusive (40). An in-depth analysis of the Comp^T585M model of mild PSACH/MED (39,41) revealed that the mild myopathy observed in patients, and recapitulated in this mouse model, was actually the result of an underlying tendinopathy that was manifesting primarily at the myotendinous and perimyseal junctions; this finding further correlated with joint laxity, which is another prominent clinical feature of PSACH and MED patients. Subsequent phenotypic analysis of the other two PSACH/MED mouse models (D469del COMP and V194D matrilin-3) revealed that both the myopathy and underlying tendinopathy were associated with mutant COMP, and not mutant matrilin-3, indicating that the neuromuscular complications in PSACH and MED are not just a side effect of the short limbed dwarfism alone (42). This in-depth phenotypic analysis of relevant genetic models of the PSACH-MED disease spectrum has yielded important information related to the specific site of the musculoskeletal complications and their underlying cause; both of which will be value aids for the diagnosis and management of these conditions.

11. Strengths and weaknesses of different genetic approaches to model skeletal diseases

The various transgenic approaches described in this review have both strengths and weaknesses as with all model systems. Homologous recombination allows the correct spatial and temporal expression of the mutant allele at levels comparable to the endogenous allele; however, mice are often required to be homozygous for the mutant allele to achieve a recognisable and quantifiable phenotype. This is in contrast to individuals with autosomal dominant PSACH and MED who only need to be heterozygous for the mutation. Posey et al (43) proposed this as weakness of the homologous recombination approach and suggested that inducible transgenic overexpression is required to produce a phenotype in mice that are heterozygous for the mutant allele; however, the random integration of multiple copies of the mutant transgene into the mouse genome is also not representative of the human condition. Furthermore, the inducible expression of mutant COMP also has its limitations since it is impossible to regulate the amount of dox ingested by individual transgenic mice and determining the levels of mutant COMP expression in the cartilage of each mouse is not feasible. Nevertheless, despite the differences of the two transgenic approaches, both mutant mouse lines demonstrated hallmark features of PSACH, which included mutant COMP retention, increased and dysregulated apoptosis with corresponding areas of hypocellularity (15,22,44). Moreover, cell proliferation was markedly reduced in both mouse models, which has recently been identified as a quintessential feature of growth plate dysplasia and reduced bone growth (11).

The use of endogenous Matn3 and Comp promoters by the homologus recombination approach (7,15,19) has also allowed the in-depth analysis of a range of other musculoskeletal tissues that is not possible with Col2a1-driven transgenic overexpression. These mouse phenotyping studies have confirmed the importance of tendinopathy and mild myopathy to the overall pathophysiology of PSACH and MED that will ultimately provide greater understanding of the clinical presentation of these GSDs.

The development and deep phenotyping of ‘ER-stress phenocopies’ (30,31) is a novel genotype-independent approach for determining the role of ER stress in GSDs. The use of the Col2a1 promoter generated a model that exhibited ER stress in a broad range of cartilaginous tissues including the growth plate and articular cartilages. The resulting phenotype, whilst not phenocopying any specific disease, provided a ‘generalised chondrodysplasia’ in which to identify fundamental disease mechanisms. In contrast, the use of the Col10a1 promoter, which specifically targeted expression to hypertrophic chondrocytes, accurately phenocopied metaphyseal chondrodysplasias type Schmid. In conclusion, this genetic approach demonstrated that ER stress can be accurately modelled in either a single cell type (or differentiation state) or in an entire tissue and will provide a powerful technique for determining the role of ER stress in a broad group of inherited connective tissues diseases.

In conclusion, these different genetic mouse models (transgenic overexpression expression, knock-in by homologous recombination and novel phenocopies) of the PSACH-MED phenotypic spectrum have recapitulated key aspects of disease pathology and identified new fundamental mechanisms that have both temporal and spatially context within the cartilage growth plate. The acquisition of this new knowledge would not have been possible through the use of cell culture models, which do not recapitulate the dynamic properties of the cartilage growth plate.

Acknowledgments

Some of the work presented in this review was funded by the Wellcome Trust (no. 084353/Z/07/Z) and the European Community’s Seventh Framework Programme under grant agreement no. 602300 (SYBIL).

Abbreviations

COMP

cartilage oligomeric matrix protein

GSD

genetic skeletal disease

PSACH

pseudoachondroplasia

MED

multiple epiphyseal dysplasia

endoplasmic reticulum

UPR

unfolded protein response

EOR

ER overload response

APR

aggregated protein response

ECM

extracellular matrix

CTD

carboxyl-terminal domain

vWFA

von Willebrand Factor A

Xbp1

X-box binding protein 1

BiP

binding immunoglobulin protein

CHOP

C/EBP-homologous protein

FACIT

fibril-associated collagens with interrupted triple helices

References 1

Briggs

Hoffman

King

Olsen

Mohrenweiser

Leroy

Mortier

Rimoin

Lachman

Gaines

Pseudoachondroplasia and multiple epiphyseal dysplasia due to mutations in the cartilage oligomeric matrix protein gene

Nat Genet103303361995

10.1038/ng0795-330

7670472

Jackson

Mittaz-Crettol

Taylor

Mortier

Spranger

Zabel

Le Merrer

Cormier-Daire

Hall

Offiah

Pseudoachondroplasia and multiple epiphyseal dysplasia: A 7-year comprehensive analysis of the known disease genes identify novel and recurrent mutations and provides an accurate assessment of their relative contribution

Hum Mutat331441572012

10.1002/humu.21611

3272220

Posey

Yang

Veerisetty

Sharan

Hecht

Model systems for studying skeletal dysplasias caused by TSP-5/COMP mutations

Cell Mol Life Sci656876992008

10.1007/s00018-007-7485-0

18193163

Briggs

Brock

Ramsden

Bell

Genotype to phenotype correlations in cartilage oligomeric matrix protein associated chondrodysplasias

Eur J Hum Genet22127812822014

10.1038/ejhg.2014.30

24595329

4051597

Spitznagel

Nitsche

Paulsson

Maurer

Zaucke

Characterization of a pseudoachondroplasia-associated mutation (His587–>Arg) in the C-terminal, collagen-binding domain of cartilage oligomeric matrix protein (COMP)

Biochem J3774794872004

10.1042/BJ20031179

Schmitz

Becker

Schmitz

Weirich

Paulsson

Zaucke

Dinser

Disruption of extracellular matrix structure may cause pseudoachondroplasia phenotypes in the absence of impaired cartilage oligomeric matrix protein secretion

J Biol Chem28132587325952006

10.1074/jbc.M601976200

16928687

Piróg-Garcia

Meadows

Knowles

Heinegård

Thornton

Kadler

Boot-Handford

Briggs

Reduced cell proliferation and increased apoptosis are significant pathological mechanisms in a murine model of mild pseudoachondroplasia resulting from a mutation in the C-terminal domain of COMP

Hum Mol Genet16207220882007

10.1093/hmg/ddm155

17588960

2674228

Briggs

Mortier

Cole

King

Golik

Bonaventure

Nuytinck

De Paepe

Leroy

Biesecker

Diverse mutations in the gene for cartilage oligomeric matrix protein in the pseudoachondroplasia-multiple epiphyseal dysplasia disease spectrum

Am J Hum Genet623113191998

10.1086/301713

9463320

1376889

Bell

Wagener

Zaucke

Koch

Selley

Warwood

Knight

Boot-Handford

Thornton

Briggs

Analysis of the cartilage proteome from three different mouse models of genetic skeletal diseases reveals common and discrete disease signatures

Biol Open28028112013

10.1242/bio.20135280

23951406

3744072

Hecht

Hayes

Snuggs

Decker

Montufar-Solis

Doege

Mwalle

Poole

Stevens

Duke

Calreticulin, PDI, Grp94 and BiP chaperone proteins are associated with retained COMP in pseudoachondroplasia chondrocytes

Matrix Biol202512622001

10.1016/S0945-053X(01)00136-6

11470401

Hecht

Hayes

Haynes

Cole

COMP mutations, chondrocyte function and cartilage matrix

Matrix Biol235255332005

10.1016/j.matbio.2004.09.006

15694129

Hecht

Makitie

Hayes

Haynes

Susic

Montufar-Solis

Duke

Cole

Chondrocyte cell death and intracellular distribution of COMP and type IX collagen in the pseudoachondroplasia growth plate

J Orthop Res227597672004

10.1016/j.orthres.2003.11.010

15183431

Duke

Montufar-Solis

Underwood

Lalani

Hecht

Apoptosis staining in cultured pseudoachondroplasia chondrocytes

Apoptosis81911972003

10.1023/A:1022926811397

12766479

Hashimoto

Tomiyama

Yamano

Mori

Mutation (D472Y) in the type 3 repeat domain of cartilage oligomeric matrix protein affects its early vesicle trafficking in endoplasmic reticulum and induces apoptosis

Am J Pathol1631011102003

10.1016/S0002-9440(10)63634-6

12819015

1868176

Suleman

Gualeni

Gregson

Leighton

Piróg

Edwards

Holden

Boot-Handford

Briggs

A novel form of chondrocyte stress is triggered by a COMP mutation causing pseudoachondroplasia

Hum Mutat332182312012

10.1002/humu.21631

3320758

Cotterill

Jackson

Leighton

Wagener

Mäkitie

Cole

Briggs

Multiple epiphyseal dysplasia mutations in MATN3 cause misfolding of the A-domain and prevent secretion of mutant matrilin-3

Hum Mutat265575652005

10.1002/humu.20263

16287128

2726956

Fresquet

Jowitt

Ylöstalo

Coffey

Meadows

Ala-Kokko

Thornton

Briggs

Structural and functional characterization of recombinant matrilin-3 A-domain and implications for human genetic bone diseases

J Biol Chem28234634346432007

10.1074/jbc.M705301200

17881354

2673055

Chapman

Mortier

Chapman

Loughlin

Grant

Briggs

Mutations in the region encoding the von Willebrand factor A domain of matrilin-3 are associated with multiple epiphyseal dysplasia

Nat Genet283933962001

10.1038/ng573

11479597

Leighton

Nundlall

Starborg

Meadows

Suleman

Knowles

Wagener

Thornton

Kadler

Boot-Handford

Decreased chondrocyte proliferation and dysregulated apoptosis in the cartilage growth plate are key features of a murine model of epiphyseal dysplasia caused by a matn3 mutation

Hum Mol Genet16172817412007

10.1093/hmg/ddm121

17517694

2674230

Schmitz

Niehoff

Miosge

Smyth

Paulsson

Zaucke

Transgenic mice expressing D469Delta mutated cartilage oligomeric matrix protein (COMP) show growth plate abnormalities and sternal malformations

Matrix Biol2767852008

10.1016/j.matbio.2007.08.001

Posey

Veerisetty

Liu

Wang

Poindexter

Bick

Alcorn

Hecht

An inducible cartilage oligomeric matrix protein mouse model recapitulates human pseudoachondroplasia phenotype

Am J Pathol175155515632009

10.2353/ajpath.2009.090184

19762713

2751552

Posey

Coustry

Veerisetty

Liu

Alcorn

Hecht

Chop (Ddit3) is essential for D469del-COMP retention and cell death in chondrocytes in an inducible transgenic mouse model of pseudoachondroplasia

Am J Pathol1807277372012

10.1016/j.ajpath.2011.10.035

3349877

Nundlall

Rajpar

Bell

Clowes

Zeeff

Gardner

Thornton

Boot-Handford

Briggs

An unfolded protein response is the initial cellular response to the expression of mutant matrilin-3 in a mouse model of multiple epiphyseal dysplasia

Cell Stress Chaperones158358492010

10.1007/s12192-010-0193-y

20428984

3024081

Pahl

Baeuerle

The ER-overload response: Activation of NF-kappa B

Trends Biochem Sci2263671997

10.1016/S0968-0004(96)10073-6

9048485

Ekeowa

Freeke

Miranda

Gooptu

Bush

Pérez

Teckman

Robinson

Lomas

Defining the mechanism of polymerization in the serpinopathies

Proc Natl Acad Sci USA10717146171512010

10.1073/pnas.1004785107

20855577

2951428

Chessler

Byers

BiP binds type I procollagen pro alpha chains with mutations in the carboxyl-terminal propeptide synthesized by cells from patients with osteogenesis imperfecta

J Biol Chem26818226182331993

8349698

Ishida

Yamamoto

Kitamura

Lamandé

Yoshimori

Bateman

Kubota

Nagata

Autophagic elimination of misfolded procollagen aggregates in the endoplasmic reticulum as a means of cell protection

Mol Biol Cell20274427542009

10.1091/mbc.E08-11-1092

19357194

2688553

Hartley

Edwards

Mullan

Bell

Fresquet

Boot-Handford

Briggs

Armet/Manf and Creld2 are components of a specialized ER stress response provoked by inappropriate formation of disulphide bonds: Implications for genetic skeletal diseases

Hum Mol Genet22526252752013

10.1093/hmg/ddt383

23956175

3842181

Kaufman

Orchestrating the unfolded protein response in health and disease

J Clin Invest110138913982002

10.1172/JCI0216886

12438434

151822

Rajpar

McDermott

Kung

Eardley

Knowles

Heeran

Thornton

Wilson

Bateman

Poulsom

Targeted induction of endoplasmic reticulum stress induces cartilage pathology

PLoS Genet5e10006912009

10.1371/journal.pgen.1000691

19834559

2757901

Gualeni

Rajpar

Kellogg

Bell

Arvan

Boot-Handford

Briggs

A novel transgenic mouse model of growth plate dysplasia reveals that decreased chondrocyte proliferation due to chronic ER stress is a key factor in reduced bone growth

Dis Model Mech6141414252013

10.1242/dmm.013342

24046357

3820264

De Leonardis

Monti

Gualeni

Tenni

Forlino

Rossi

Altered signaling in the G1 phase deregulates chondrocyte growth in a mouse model with proteoglycan undersulfation

J Cell Biochem115177917862014

10.1002/jcb.24844

24820054

4262066

Yamashita

Morioka

Kishi

Kimura

Yahara

Okada

Fujita

Sawai

Ikegawa

Tsumaki

Statin treatment rescues FGFR3 skeletal dysplasia phenotypes

Nature5135075112014

10.1038/nature13775

25231866

Liang

Lian

Huang

Gao

Liang

Peng

Huang

Endoplasmic reticulum stress-unfolding protein response-apoptosis cascade causes chondrodysplasia in a col2a1 p.Gly1170Ser mutated mouse model

PLoS One9e868942014

10.1371/journal.pone.0086894

24475193

3903611

Arita

Fertala

Hou

Steplewski

Fertala

Mechanisms of aberrant organization of growth plates in conditional transgenic mouse model of spondyloepiphyseal dysplasia associated with the R992C substitution in collagen II

Am J Pathol1852142292015

10.1016/j.ajpath.2014.09.003

Jackson

Barker

Jakkula

Czarny-Ratajczak

Mäkitie

Cole

Wright

Smithson

Suri

Rogala

Missense mutations in the beta strands of the single A-domain of matrilin-3 result in multiple epiphyseal dysplasia

J Med Genet4152592004

10.1136/jmg.2003.011429

14729835

1757268

Dixon

Genetic background has a major effect on the penetrance and severity of craniofacial defects in mice heterozygous for the gene encoding the nucleolar protein Treacle

Dev Dyn2299079142004

10.1002/dvdy.20004

15042714

Piróg

Irman

Young

Halai

Bell

Boot-Handford

Briggs

Abnormal chondrocyte apoptosis in the cartilage growth plate is influenced by genetic background and deletion of CHOP in a targeted mouse model of pseudoachondroplasia

PLoS One9e851452014

10.1371/journal.pone.0085145

24558358

3928032

Piróg

Briggs

Skeletal dysplasias associated with mild myopathy-a clinical and molecular review

J Biomed Biotechnol20106864572010

10.1155/2010/686457

20508815

2875749

Jackson

Marcus-Soekarman

Stolte-Dijkstra

Verrips

Taylor

Briggs

Type IX collagen gene mutations can result in multiple epiphyseal dysplasia that is associated with osteochondritis dissecans and a mild myopathy

Am J Med Genet A152A8638692010

10.1002/ajmg.a.33240

20358595

3557369

Piróg

Jaka

Katakura

Meadows

Kadler

Boot-Handford

Briggs

A mouse model offers novel insights into the myopathy and tendinopathy often associated with pseudoachondroplasia and multiple epiphyseal dysplasia

Hum Mol Genet1952642010

10.1093/hmg/ddp466

Piróg

Katakura

Mironov

Briggs

Mild myopathy is associated with COMP but not MATN3 mutations in mouse models of genetic skeletal diseases

PLoS One8e824122013

10.1371/journal.pone.0082412

24312420

3842254

Posey

Alcorn

Hecht

Pseudoachondroplasia/COMP - translating from the bench to the bedside

Matrix Biol371671732014

10.1016/j.matbio.2014.05.006

24892720

4209947

Posey

Coustry

Veerisetty

Liu

Alcorn

Hecht

Chondrocyte-specific pathology during skeletal growth and therapeutics in a murine model of pseudoachondroplasia

J Bone Miner Res29125812682014

10.1002/jbmr.2139

4075045

Hecht

Nelson

Crowder

Wang

Elder

Harrison

Francomano

Prange

Lennon

Deere

Mutations in exon 17B of cartilage oligomeric matrix protein (COMP) cause pseudoachondroplasia

Nat Genet103253291995

10.1038/ng0795-325

7670471

Paassilta

Lohiniva

Annunen

Bonaventure

Le Merrer

Pai

Ala-Kokko

COL9A3: A third locus for multiple epiphyseal dysplasia

Am J Hum Genet64103610441999

10.1086/302328

10090888

1377827

Muragaki

Mariman

van Beersum

Perälä

van Mourik

Warman

Olsen

Hamel

A mutation in the gene encoding the alpha 2 chain of the fibril-associated collagen IX, COL9A2, causes multiple epiphyseal dysplasia (EDM2)

Nat Genet121031051996

10.1038/ng0196-103

8528240

Czarny-Ratajczak

Lohiniva

Rogala

Kozlowski

Perälä

Carter

Spector

Kolodziej

Seppänen

Glazar

A mutation in COL9A1 causes multiple epiphyseal dysplasia: Further evidence for locus heterogeneity

Am J Hum Genet699699802001

10.1086/324023

11565064

1274373

Terhal

Nievelstein

Verver

Topsakal

van Dommelen

Hoornaert

Le Merrer

Zankl

Simon

Smithson

A study of the clinical and radiological features in a cohort of 93 patients with a COL2A1 mutation causing spondyloepiphyseal dysplasia congenita or a related phenotype

Am J Med Genet A1674614752015

10.1002/ajmg.a.36922

Majava

Hoornaert

Bartholdi

Bouma

Bouman

Carrera

Devriendt

Hurst

Kitsos

Niedrist

A report on 10 new patients with heterozygous mutations in the COL11A1 gene and a review of genotype-phenotype correlations in type XI collagenopathies

Am J Med Genet A143A2582642007

10.1002/ajmg.a.31586

17236192

Tsang

Susic

Mäkitie

Chan

Sillence

Boot-Handford

Gibson

COL10A1 nonsense and frame-shift mutations have a gain-of-function effect on the growth plate in human and mouse metaphyseal chondrodysplasia type Schmid

Hum Mol Genet16120112152007

10.1093/hmg/ddm067

17403716

Tompson

Merriman

Funari

Fresquet

Lachman

Rimoin

Nelson

Briggs

Cohn

Krakow

A recessive skeletal dysplasia, SEMD aggrecan type, results from a missense mutation affecting the C-type lectin domain of aggrecan

Am J Hum Genet8472792009

10.1016/j.ajhg.2008.12.001

2668039

Stattin

Wiklund

Lindblom

Onnerfjord

Jonsson

Tegner

Sasaki

Struglics

Lohmander

Dahl

A missense mutation in the aggrecan C-type lectin domain disrupts extracellular matrix interactions and causes dominant familial osteochondritis dissecans

Am J Hum Genet861261372010

10.1016/j.ajhg.2009.12.018

20137779

2820178

Nilsson

Guo

Dunbar

Popovic

Flynn

Jacobsen

Lui

Hirschhorn

Baron

Dauber

Short stature, accelerated bone maturation, and early growth cessation due to heterozygous aggrecan mutations

J Clin Endocrinol Metab99E1510E15182014

10.1210/jc.2014-1332

24762113

4121031

Kung

Rajpar

Preziosi

Briggs

Boot-Handford

Increased classical endoplasmic reticulum stress is sufficient to reduce chondrocyte proliferation rate in the growth plate and decrease bone growth

PLoS One10e01170162015

10.1371/journal.pone.0117016

25693198

4334961

Figure 1

Organization of the growth plate in mutant mice is disrupted by 3 weeks of age and shows marked hypocellularity along with the retention and/or mislocalisation of cartilage structural proteins. Representative immunohistochemistry (IHC) of the growth plates from 3 week-old wild-type and mutant mice showing disruption to chondrocyte columns in mice homozygous for the Comp p.Thr585Met (Comp^T585M), Comp p.D469del (Comp^D469del) and Matn3 Val194Asp (Matn3^V194D) mutations. IHC using COMP (wild-type, Comp^T585M and Comp^D469del) and matrilin-3 (Matn3^V194D) antibodies revealed less staining in the extracellular matrix (ECM) between the proliferating columns in the growth plates of mice carrying all three mutations. Furthermore, there was intracellular staining for mutant COMP and matrilin-3 in chondrocytes from the Comp^D469del and Matn3^V194D mice, respectively.

Figure 2

Chondrocytes have dilated cisternae of endoplasmic reticulum (ER) and the extracellular matrix (ECM) ultrastructure is altered in mutant growth plates. These representative images were taken from a complete TEM montage of a day 7 tibia growth plate (from resting to mineralisation zones) and show chondrons from the proliferative zone of mice homozygous for the Comp p.Thr585Met (Comp^T585M), Comp p.D469del (Comp^D469del) and Matn3 Val194Asp (Matn3^V194D) mutations. Top panel, the ultrastructure of the interterritorial matrix at 1 week of age is altered in all three mutant growth plates and is characterised by more prominent appearing collagen fibrillar material. Scale bars, 1.2 μm (wild-type, Comp^D469del and Matn3^V194D) or 1.4 μm (Comp^T585M). Middle and bottom panels, chondrocytes from Comp^D469del and Matn3^V194D mice which show enlarged individual cisternae of ER compared to the wild-type mice in which the ER displays has the typical ribbon appearance. The Comp^T585M growth plate shows misaligned and abnormally shaped chondrocytes despite mutant T585M COMP being secreted.

Table I

Human genetic skeletal diseases result from qualitative (anti-morphic) defects in cartilage structural proteins.

Gene	Protein	Disease(s)	Genetic loci	Domain	Refs.
COMP	COMP	Pseudoachondroplasia (AD)Multiple epiphyseal dysplasia (AD)	PSACHEDM1	T3-7 repeatsC-terminal domain	(4,45)
MATN3	Matrilin-3	Multiple epiphyseal dysplasia (AD)	EDM5	vWFA	(18)
COL9A1COL9A2COL9A3	Type IX collagen	Multiple epiphyseal dysplasia (AD)	EDM6EDM2EDM3	COL3 domain	(46–48)
COL2A1	Type II collagen	Diverse range of AD and AR phenotypes collectively known as type II collagenopathies	Various	Triple helical region and C-propeptide	(49)
COL11A1COL11A2	Type XI collagen	Diverse range of AD and AR phenotypes collectively known as type XI collagenopathies	Various		(50)
COL10A1	Type X collagen	Metaphyseal chondrodysplasia, type Schmid (AD)	MCDS	Carboxyl-terminal non-collagenous domain (NC1)	(51)
ACAN	Aggrecan	Spondyloepimetaphyseal dyslasia (AR)Osteochondritis dissecans (AD)Short stature, accelerated bonematuration (AD)	SEMDOCD	G3 C-type lectin domain	(52–54)

COMP, cartilage oligomeric matrix protein; PSACH, pseudoachondroplasia; AD, autosomal dominant; AR, autosomal recessive.

Table II

Mouse models of the PSACH-MED disease spectrum and novel phenocopies to model ER stress in the cartilage growth plate.

Disease	Gene	Mutation	Approach taken	Promoter	Refs.
PSACH	COMP	D469del	Transgenic (rat COMP cDNA)	Col2a1	(20)
PSACH	COMP	D469del	Transgenic (human COMP gene)	Native	(3)
PSACH	COMP	D469del	Transgenic (human COMP cDNA)	Col2a1	(3)
PSACH	COMP	D469del	Transgenic inducible overexpression (human COMP cDNA)	Col2a1 and tetracycline responsive element	(21,22,44)
PSACH	COMP	D469del	Knock-in	Native	(9,15,42)
PSACH-MED	COMP	T585M	Knock-in	Native	(7,9,38,41)
MED	MATN3	V194D	Knock-in	Native	(9,19,23,42)
Chondrodysplasia	TG	Rdw (G2320R)	Transgenic phenocopy	Col2a1	(31)
Chondrodysplasia	TG	Cog (L2293P)	Transgenic phenocopy	Col2a1	(55)

ER, endoplasmic reticulum; COMP, cartilage oligomeric matrix protein; PSACH, pseudoachondroplasia; MED, multiple epiphyseal dysplasia.

Table III

Key pathological and quantitative measures of disease severity in various knock-in mouse models of PSACH-MED and novel ER stress phenocopies.

Model	Age at onset	Final reduction in bone length			Cell proliferation	Apoptosis	Protein retention	ER stress	Stress pathway
Model	Age at onset	3 weeks	6 weeks	9 weeks	3 weeks	3 weeks	Protein retention	ER stress	Stress pathway
Comp^D469del	~6 weeks	No differences	↓ 6%	↓ 5%	↓ 17%	↑ 90-fold (Pz)↑ 5-fold (Hz)	Yes	Yes	Novel (APR/EOR)
Comp^T585M	~9 weeks	No differences	No differences	↓ 5%	↓ 24%	↑ 3-fold (Rz)↑ 12-fold (Pz)↑ 3-fold (Hz)	Slight	Mild	Mild UPR
Matn3^V194D	~2 weeks	↓ 12%	↓ 13%	↓ 12%	↑ 16%	Spatially dysregulated	Yes	Yes	UPR
Col2-Tg^Rdw	At birth	↓ 8%	↓ 5%	↓ 5%	↑ 21%	No differences	Yes	Yes	UPR
Col2-Tg^cog	~3 weeks	↓ 7%	↓ 4%	↓ 4%	↑ 12%	No differences	Yes	Yes	Novel

EOR, ER overload response; ER, endoplasmic reticulum; APR, aggregated protein response; UPR, unfolded protein response; Pz, proliferative zone; Hz, hypertrophic zone; Rz, resting zone; PSACH, pseudoachondroplasia; MED, multiple epiphyseal dysplasia.