Original Article

Lethal Skeletal Dysplasia in Mice and Humans Lacking the Golgin GMAP-210

Patrick Smits, Ph.D., Andrew D. Bolton, B.S., Vincent Funari, Ph.D., Minh Hong, Ph.D., Eric D. Boyden, Ph.D., Lei Lu, Ph.D., Danielle K. Manning, Ph.D., Noelle D. Dwyer, Ph.D., Jennifer L. Moran, Ph.D., Mary Prysak, B.S., Barry Merriman, Ph.D., Stanley F. Nelson, M.D., Luisa Bonafé, M.D., Ph.D., Andrea Superti-Furga, M.D., Shiro Ikegawa, M.D., Ph.D., Deborah Krakow, M.D., Daniel H. Cohn, Ph.D., Tom Kirchhausen, Ph.D., Matthew L. Warman, M.D., and David R. Beier, M.D., Ph.D.

N Engl J Med 2010; 362:206-216January 21, 2010

Abstract

Background

Establishing the genetic basis of phenotypes such as skeletal dysplasia in model organisms can provide insights into biologic processes and their role in human disease.

Full Text of Background...

Methods

We screened mutagenized mice and observed a neonatal lethal skeletal dysplasia with an autosomal recessive pattern of inheritance. Through genetic mapping and positional cloning, we identified the causative mutation.

Full Text of Methods...

Results

Affected mice had a nonsense mutation in the thyroid hormone receptor interactor 11 gene (Trip11), which encodes the Golgi microtubule-associated protein 210 (GMAP-210); the affected mice lacked this protein. Golgi architecture was disturbed in multiple tissues, including cartilage. Skeletal development was severely impaired, with chondrocytes showing swelling and stress in the endoplasmic reticulum, abnormal cellular differentiation, and increased cell death. Golgi-mediated glycosylation events were altered in fibroblasts and chondrocytes lacking GMAP-210, and these chondrocytes had intracellular accumulation of perlecan, an extracellular matrix protein, but not of type II collagen or aggrecan, two other extracellular matrix proteins. The similarities between the skeletal and cellular phenotypes in these mice and those in patients with achondrogenesis type 1A, a neonatal lethal form of skeletal dysplasia in humans, suggested that achondrogenesis type 1A may be caused by GMAP-210 deficiency. Sequence analysis revealed loss-of-function mutations in the 10 unrelated patients with achondrogenesis type 1A whom we studied.

Full Text of Results...

Conclusions

GMAP-210 is required for the efficient glycosylation and cellular transport of multiple proteins. The identification of a mutation affecting GMAP-210 in mice, and then in humans, as the cause of a lethal skeletal dysplasia underscores the value of screening for abnormal phenotypes in model organisms and identifying the causative mutations.

Full Text of Discussion...

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Media in This Article

Figure 1Effects of Trip11 Mutation in Mice.

Figure 2Effects of GMAP-210 Deficiency on Hypertrophic Differentiation, Proliferation, and Apoptosis of Chondrocytes in Mice.

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Article

The presence of the Golgi apparatus in all cell types suggests that it is indispensable. Although cultured cells are able to survive when their well-structured Golgi architecture is transiently disrupted chemically or through RNA interference (RNAi),1 the requirement for an intact Golgi apparatus during development has not been studied. In this article, we describe mice in which the Golgi architecture is disrupted in multiple tissues by a loss-of-function mutation in the thyroid hormone receptor interactor 11 gene (Trip11), which encodes the Golgi microtubule-associated protein 210 (GMAP-210 — also known as TRIP230 and TRIP11). Golgins constitute a family of Golgi-associated proteins that serve either as tethering factors that facilitate vesicle fusion to Golgi compartments or as structural proteins that maintain Golgi architecture.1,2 We observed that mice lacking GMAP-210 die from a skeletal dysplasia that shares phenotypic features with achondrogenesis type 1A, a lethal, autosomal recessive, skeletal dysplasia in humans.3 We tested for mutations affecting GMAP-210 in patients with achondrogenesis type 1A.

Methods

Identification and Characterization of GMAP-210–Deficient Mice

We carried out a screen for recessive mutations affecting late embryonic development in mice treated with the N-ethyl-N-nitrosourea (ENU) mutagen, as previously described.4 We used whole-genome, single-nucleotide-polymorphism (SNP) analysis5 to map the locus harboring the etiologic mutation and used a polymerase-chain-reaction assay to amplify and sequence candidate genes in accordance with standard methods.

DNA Sequence Analysis of TRIP11

We sequenced TRIP11 in patients with achondrogenesis type 1A. We confirmed mutations with the use of DNA obtained from patients' parents; in the event that parental DNA was unavailable, we used subcloning followed by sequence analysis to show that the mutant alleles making up a compound heterozygous mutation were derived from different parental chromosomes.

DNA samples from patients with a diagnosis of achondrogenesis type 1A (Online Mendelian Inheritance in Man number, 200600) were provided by three referral centers that specialize in the clinical, radiologic, and histologic characterization of skeletal dysplasia. Each referral center obtained written informed consent to collect and analyze DNA. The institutional review board at Children's Hospital Boston approved the analysis of DNA samples that would be stripped of identifying information before being transferred from the referral centers.

Transport Assay

We prepared adenovirus expressing a temperature-sensitive vesicular stomatitis viral G protein fused to green fluorescence protein (VSVG^ts–GFP), as previously described.6 We studied VSVG^ts–GFP processing in heterozygous and mutant skin fibroblasts grown in six-well culture plates. The assay was repeated three times on separate days and performed in triplicate each time. (See the Supplementary Appendix, available with the full text of this article at NEJM.org, for details on fibroblast cultures; skeletal preparations; histologic analysis; RNA in situ hybridization; electron microscopy; monitoring of chondrocyte differentiation, proliferation, and apoptosis; immunofluorescence staining of cultured cells and frozen sections; immunodetection of GMAP-210; and an assay for hedgehog signaling.)

Results

TRIP11 and the Mutant Mouse Phenotype

After initiating mutagenesis with ENU,4 we identified mice with a neonatal lethal phenotype that was autosomal recessive. Affected mice had short limbs, small thoracic cages, short snouts, domed skulls, and in some cases, omphalocele (Figure 1AFigure 1Effects of Trip11 Mutation in Mice.). Skeletal preparations revealed delayed mineralization of intramembranous and endochondral bone (Figure 1B). As compared with wild-type mice, newborn mutant mice lacked vertebral-body ossification (Figure 1B). Alveolar formation in the lungs was also decreased in newborn mutant mice as compared with newborn wild-type mice (Figure 1 in the Supplementary Appendix).

For the screen, we outcrossed mutagenized C57BL/6J mice with wild-type FVB/N mice4 and used a panel of 394 single-nucleotide polymorphisms (SNPs) spanning the mouse genome to facilitate genetic mapping.5 After analysis of 10 mutant mice, we located the causative mutation within a 17-Mb region on chromosome 12, and analysis of additional mice narrowed the candidate interval to 3.7 Mb. We sequenced four genes in this interval before identifying a nonsense mutation (c.5003T→A, p.L1668X) in Trip11 in the mutant mice. Immunoblotting with an antibody that recognizes an epitope encoded by a region of the complementary DNA that precedes the truncating mutation showed that GMAP-210 was absent in protein extracts from mutant cells (Figure 1C).

To confirm that the phenotype resulted from a mutation in Trip11, mice carrying the nonsense mutation were crossed with mice that were heterozygous for another inactivating Trip11 allele.7 Offspring that were compound heterozygotes (i.e., carrying the ENU-induced Trip11 ^L1668X nonsense mutation on one allele and a different Trip11 inactivating mutation on the other allele) had the same phenotype as offspring that were homozygous for the nonsense mutation (data not shown), proving that the phenotype was the result of a GMAP-210 deficiency. We also performed RNA in situ hybridization to determine which tissues normally express Trip11 messenger RNA (mRNA) and observed widespread expression (Figure 1D). Therefore, enhanced or restricted expression of GMAP-210 in the developing skeleton does not explain the prominent skeletal phenotype in the mutant animals.

Cellular Effects of GMAP-210 Deficiency

On embryonic day 13.5, wild-type chondrocytes at the centers of humeri start to undergo hypertrophic differentiation, which is associated with an increase in cell size. The humeri of the mutant mice had hypertrophic chondrocytes that were smaller than those in wild-type mice and had proliferating chondrocytes that were larger than those in wild-type mice (data not shown). These differences became more pronounced by embryonic day 15.5, when mutant chondrocytes in the epiphysis and metaphysis were markedly larger than normal (Figure 1E). Furthermore, mutant chondrocytes failed to form an organized columnar growth zone and produced less extracellular matrix, as indicated by staining with Alcian blue (Figure 1E).

RNA in situ hybridization with mRNA probes that are specific for proliferating chrondrocytes (Col2a1), chondrocytes that are about to undergo hypertrophic differentiation (Ppr), and those that are in the early stage of hypertrophic differentiation (Col10a1) revealed a delay in differentiation (Figure 2Figure 2Effects of GMAP-210 Deficiency on Hypertrophic Differentiation, Proliferation, and Apoptosis of Chondrocytes in Mice., and Figure 2 in the Supplementary Appendix). Expression of Col2a1 by embryonic day 13.5 was identical in wild-type and mutant mice, whereas expression of the prehypertrophic marker, Ppr, and the hypertrophic marker, Col10a1, was reduced in the mutant mice (Figure 2A in the Supplementary Appendix). By embryonic day 14.5, the expression levels of Col10a1 in the humeri of mutant mice was similar to that in wild-type mice, but in the mutant mice, the expression domain had not divided into two growth zones, a finding that is consistent with delayed hypertrophic differentiation (Figure 2A). Furthermore, on embryonic day 14.5, expression of vascular endothelial growth factor (Vegf), a marker of late hypertrophic differentiation, and matrix metalloproteinase 13 (Mmp13), a marker of terminal differentiation, was absent from the mutant humeri, indicating impaired terminal differentiation (Figure 2A). Finally, on embryonic day 18.5, expression of hypertrophic-differentiation markers became undetectable in the mutant mice (Figure 2B in the Supplementary Appendix). Thus, chondrocyte hypertrophic differentiation was delayed in the mutant mice, with worsening at later developmental stages and a complete absence of differentiation by embryonic day 18.5.

Since the mutant humeri failed to increase in size, we performed bromodeoxyuridine incorporation assays to assess chondrocyte proliferation. By embryonic day 15.5, there were no proliferating cells in the center of the epiphysis or in the presumptive columnar zone in the humeri of the mutant mice, in contrast to the findings in the wild-type mice (Figure 2B). The decreased expression of chondrocyte marker genes in the mutant mice on embryonic day 18.5 (Figure 2B in the Supplementary Appendix) suggested that the chondrocytes were dying. This was confirmed with the use of the terminal deoxynucleotidyl transferase dUTP biotin nick end labeling (TUNEL) assay on embryonic day 17.5, which showed apoptotic chondrocytes throughout mutant humeri but not in wild-type humeri (Figure 2C).

Endoplasmic Reticulum and Golgi Organization and Processing in Mutant Cells

Transmission electron microscopy of mutant chondrocytes and osteoblasts revealed swelling of the endoplasmic reticulum (Figure 3A and 3BFigure 3Swollen Endoplasmic Reticulum Cisternae and Abnormal Golgi Architecture in Murine Chondrocytes Lacking GMAP-210.). Although GMAP-210 was expressed in other cell types (e.g., fibroblasts, endothelial cells, pericytes, myocytes, hepatocytes, and keratinocytes), these cells had endoplasmic reticulum of normal appearance (Figure 3A in the Supplementary Appendix). Because mutant chondrocytes contained swollen endoplasmic reticulum, we assayed the expression of the endoplasmic reticulum stress-response gene, heat-shock protein 5 (Hspa5-Bip),8 and found that there was greater Hspa5-Bip expression in mutant chondrocytes than in wild-type chondrocytes (Figure 3A in the Supplementary Appendix). Chondrocytes from mutant mice also lacked a typical Golgi apparatus (Figure 3C). Instead of displaying a Golgi apparatus with stacked cisternal organization, mutant chondrocytes contained an aggregation of vesicle-like structures. Electron microscopical examination of other tissues on embryonic day 15.5 revealed an abnormal Golgi apparatus in the kidney but not in the intestine or lung (Figure 3C, and Figure 3C in the Supplementary Appendix). Primary dermal fibroblast cultures from the mutant mice showed an abnormally condensed Golgi apparatus as compared with that in wild-type fibroblasts (Figure 4AFigure 4Impaired Post-Translational Protein Processing and Secretion in Murine Cells Lacking GMAP-210.). However, the cis- and trans-Golgi compartments in the mutant fibroblasts were preserved, as indicated by the adjacent, nonoverlapping localization of Golgi matrix protein 130 (GM130) (a cis-Golgi protein) and ADP-ribosylation factor–like 1 (Arl1) (a trans-Golgi protein) (Figure 4A).

Primary chondrocyte cultures from mice lacking GMAP-210 grew poorly and failed to differentiate. Therefore, we used primary skin fibroblasts from mice that were heterozygous or homozygous for the nonsense mutation to evaluate endoplasmic reticulum and Golgi function. We infected these fibroblasts with adenovirus expressing a thermoreversible folding mutant of VSVG^ts–GFP; this particular mutant is unfolded and retained within the endoplasmic reticulum at 40°C, but it can fold properly and transit through the Golgi apparatus at 32°C (Figure 4, and Figure 4A in the Supplementary Appendix). VSVG^ts–GFP processing differed between homozygous and heterozygous cells (Figure 4C), probably because of altered glycosylation of VSVG^ts–GFP within the Golgi of homozygous mutant cells rather than impaired transit through the Golgi. We could make this distinction because the transport of VSVG^ts–GFP to the cell surface was similar in homozygous and heterozygous cells (Figure 4 in the Supplementary Appendix).

To confirm that post-translational modifications were altered in cells deficient in GMAP-210, we stained cultured fibroblasts and skeletal sections from wild-type and mutant mice with lectin GS-II. This form of lectin, isolated from the seeds of the tropical African legume Griffonia simplicifolia, preferentially binds to the terminal glycan structure N-acetylglucosamine.9 Increased lectin GS-II binding indicates impaired glycosylation because N-acetylglucosamine is uncommon in correctly glycosylated proteins. As compared with wild-type fibroblasts, mutant primary dermal fibroblasts showed increased lectin GS-II binding along cell surfaces (Figure 5 in the Supplementary Appendix), which is consistent with incomplete modification of cell-surface proteins. Furthermore, we observed a marked increase in lectin GS-II binding in the cartilage of mutant mice (as compared with that of wild-type mice), with most of the binding occurring intracellularly (Figure 5 in the Supplementary Appendix). Lectin GS-II has previously been shown to bind glycans that are being synthesized in the medial- and trans-Golgi compartments.10 Therefore, our result is consistent with impaired Golgi function in chondrocytes that lack GMAP-210.

Transmission electron microscopy of the extracellular matrix of cartilage from the humeri revealed that the collagen fibrils were similar in content in wild-type and mutant mice (Figure 4D). Immunofluorescence light microscopy performed with the use of anti–type II collagen antibodies showed that the amount and distribution of this collagen in the cartilage did not differ between wild-type and mutant mice (Figure 6 in the Supplementary Appendix), a finding that is consistent with electron-microscopical findings. Similarly, there were no differences between wild-type and mutant mice with respect to antibodies directed against the polypeptide cores of cartilage oligomeric matrix protein and aggrecan (Figure 6 in the Supplementary Appendix). In contrast, proteoglycan aggregates in cartilage, seen on electron microscopy as granulelike structures, were clearly smaller in the mutant mice than in the wild-type mice (Figure 4D). Immunofluorescence studies with the use of an antibody directed against the polypeptide core of perlecan showed that mutant chondrocytes had an abnormal accumulation of this protein intracellularly (Figure 4E), where it partially colocalized with the endoplasmic reticulum marker calreticulin. Perlecan, which is a prominent component of basement membranes, is also secreted by dermal fibroblasts, and fibroblasts from mutant mice retained perlecan intracellularly (Figure 4F). Therefore, in addition to a general impairment in glycosylation, chondrocytes deficient in GMAP-210 also differ from wild-type chondrocytes in the synthesis and secretion of specific proteins.

Mutations in TRIP11 and Achondrogenesis Type 1A

Achondrogenesis type 1A, the neonatal lethal skeletal dysplasia with an autosomal recessive pattern of inheritance seen in our patients (Figure 5AFigure 5Mutations in TRIP11 and Human Achondrogenesis Type 1A.), has features that are similar to those of the mice with the Trip11 mutation. The absence of vertebral-body and skull ossification on radiography, the lack of organized columnar zones of proliferating chondrocytes on histologic analysis, the reduced expression of Col10a1 on immunohistochemical analysis, and the expanded endoplasmic reticulum cisternae in chondrocytes on electron microscopy have all been reported in affected patients.3,11 We performed sequence analysis of TRIP11 in our 10 unrelated patients with achondrogenesis type 1A and found loss-of-function mutations in each patient (Figure 5B). Five mutations create termination codons, four alter the open-reading-frame, and two affect splice sites. Homozygous mutations were present in patients from consanguineous unions, and some mutations were found in more than one family.

Discussion

In 1898, Camillo Golgi described the diffuse reticular network that bears his name.12 A half-century later, the ribbonlike cisternal architecture of this intracellular structure was observed with an electron microscope.13 How the Golgi apparatus forms, how it maintains its architecture, and what the relationship is between its structure and its functions — which include glycosylation of proteins — remain incompletely understood.14 Golgin proteins participate in these processes; ex vivo knockdown of the golgins GMAP-210, golgin-84, and GM130 result in fragmentation of the Golgi apparatus.15-17 Golgi fragmentation does not completely block the transport and processing of nascent proteins in cultured cells, but it does reduce the efficiency of these processes.15,16 The identification of mice with a loss-of-function mutation in the gene encoding GMAP-210 facilitates assessment of the function of the Golgi structure in vivo. Although additional roles of GMAP-210 have been suggested,7,18-20 our in vivo data are most consistent with its role in Golgi organization and protein processing.

Despite expression of GMAP-210 in many cell types, GMAP-210 deficiency altered Golgi architecture and caused swelling of the endoplasmic reticulum in a subgroup of tissues. Cells within the developing skeletal system — chondrocytes and osteoblasts — have very high rates of matrix secretion21 and may be particularly susceptible to stress when Golgi processing is inefficient. Indeed, chondrocytes with mutant GMAP-210 showed clear evidence of stress in the endoplasmic reticulum, abnormal differentiation, and increased cell death. Impaired protein processing and swelling of the endoplasmic reticulum have been observed in other human skeletal dysplasias. Typically, these dysplasias have been caused by mutations in a secreted matrix protein that impair its folding and secretion. Examples include specific mutations of type I collagen in osteogenesis imperfecta,22 type II collagen in spondyloepiphyseal dysplasia congenita,23 type X collagen in Schmid metaphyseal dysplasia,24 and cartilage oligomeric matrix protein in pseudoachondroplasia and multiple epiphyseal dysplasia.25 Investigators have identified mutations in patients with craniolenticular dysplasia that affect secretory mutant protein 23A (SEC23A), a protein involved in generating vesicles containing coat protein complex II that are used to move proteins from the endoplasmic reticulum to the Golgi apparatus.26 The nonlethality of SEC23A deficiency may be explained by the coexpression of its paralog, SEC23B, in most cell types.27,28 Mutations affecting trafficking protein particle complex 2 (TRAPPC2) and dymeclin, two other proteins thought to have roles in the transport of proteins between the endoplasmic reticulum and the Golgi apparatus, also cause nonlethal skeletal dysplasias — X-linked spondyloepiphyseal dysplasia tarda and the Dyggve–Melchior–Clausen syndrome, respectively.29-31 Therefore, it is reasonable to postulate that the developing skeleton, being sensitive to defects in protein transport, will be affected by mutations in other components of the secretory pathways whose deficiency causes Golgi disorganization.

Important post-translational modifications, such as the synthesis of glycosaminoglycans, occur in the Golgi apparatus. Chondrocytes produce several highly modified proteoglycans, the most abundant of which is aggrecan, a very large proteoglycan (measuring 500 nm and having a mass of 3 megadaltons) that contains hundreds of glycosaminoglycan side chains.32 Immunofluorescence studies showed that aggrecan core protein was present in both wild-type and mutant cartilage, even though staining with Alcian blue, electron microscopy, and lectin staining suggest that this protein is improperly glycosylated in the mutant cartilage. In contrast, perlecan, a less abundant and smaller glycosaminoglycan containing proteoglycan, is abnormally retained within mutant chondrocytes and fibroblasts. These data suggest that GMAP-210 maintains the Golgi structure in chondrocytes, thereby facilitating complex glycosylation reactions while also participating in the transport of specific proteins. Indeed, RNAi knockdown of golgin-97 and golgin-245 has been shown to affect the secretion of E-cadherin and tumor necrosis factor α, respectively. However, depletion of these golgins did not affect the organization of the Golgi apparatus.33,34

Loss-of-function mutations in solute carrier family 26, member 2 (SLC26A2), which encodes a high-affinity sulfate transporter, cause achondrogenesis type 1B, which is phenotypically similar to achondrogenesis type 1A.35 Impaired post-translational modification of proteoglycans in cartilage appears to be common to the two disorders.

Follit and colleagues described neonatal lethality in mice with a gene-trap insertion into Trip11.7 Their studies focused on the role of GMAP-210 in the formation of the primary cilia and in intraflagellar transport; they noted that cells from the mutant mice had shorter cilial than those from wild-type mice and that these cells failed to localize intraflagellar transport protein 20 to the Golgi apparatus. Impaired cilial function has previously been shown to cause skeletal-patterning defects as well as skeletal dysplasia through disruption of hedgehog signaling.36,37 Our data suggest that neither impaired cilial function nor impaired hedgehog signaling is a primary contributor to the skeletal phenotype in mice lacking GMAP-210 (Figure 7 in the Supplementary Appendix). Decreased alveolar formation was observed in the lungs of gene-trap mutant mice,7 which we also observed in our mutant mice. We suggest that the lung phenotype is a consequence of the skeletal phenotype, since alveolar deficiency has been observed in other conditions characterized by insufficient thoracic volume.38

Although we found TRIP11 mutations in all 10 patients with achondrogenesis type 1A that were tested, we cannot conclude that every case is attributable to mutations in TRIP11. However, the identification of TRIP11 as the major disease-causing gene makes it possible to conduct genetic testing in families with a history of achondrogenesis type 1A. It is notable that we did not observe missense mutations in patients with achondrogenesis type 1A, suggesting that milder mutations may result in a different clinical phenotype. For example, SNPs near TRIP11 have been associated with normal variation in human height.39,40

Forward genetic analysis has the potential to provide insight into the molecular mechanisms of a biologic process that is novel and unexpected, since a phenotype-driven screen is not biased by preconceptions regarding gene function. In vitro knockdown of GMAP-210 had suggested that the absence of this protein would lead to Golgi fragmentation and dysfunction in all cells. Instead, a forward genetic screen in mutagenized mice indicated that the absence of GMAP-210 predominantly affects the development of the skeletal system. Our finding that patients with achondrogenesis type 1A, a phenotypically similar syndrome, also have mutations in TRIP11 that lead to GMAP-210 deficiency underscores the power and usefulness of this strategy of genetic inquiry.

Supported by grants from the National Institutes of Health (HD36404 and UO1 HD43430, to Dr. Beier; GM075252 and A1063430, to Dr. Kirchhausen; and AR050180, to Dr. Warman) and the Swiss National Research Foundation (320000-116506, to Dr. Bonafe) and by an Arthritis Foundation Investigator Award to Dr. Smits.

No potential conflict of interest relevant to this article was reported.

We thank the families of patients with achondrogenesis type 1A and their physicians for participating in this study, Drs. W.R. Wilcox and D.L. Rimoin for their clinical expertise, Dr. R. Stottmann for assistance with the hedgehog assay, Dr. G. Pazour for kindly providing the Trip11 gene-trap mice, and Drs. B. Yoder and Z. Verney for kindly providing the IFT88 mutant mice.

Source Information

From the Orthopedic Research Laboratories, Department of Orthopedic Surgery (P.S., M.H., E.D.B., M.L.W.), the Program in Cellular and Molecular Medicine (L.L., T.K.), and the Howard Hughes Medical Institute (M.L.W.), Children's Hospital; the Division of Genetics, Brigham and Women's Hospital (A.D.B., D.K.M., N.D.D., J.L.M., M.P., D.R.B.); the Immune Disease Institute (L.L., T.K.); and the Departments of Cell Biology (L.L., T.K.) and Genetics (M.L.W.), Harvard Medical School — all in Boston; the Medical Genetics Institute, Cedars–Sinai Medical Center (V.F., D.K., D.H.C.); and the David Geffen School of Medicine, University of California, Los Angeles (V.F., B.M., S.F.N., D.K., D.H.C.) — both in Los Angeles; the Division of Molecular Pediatrics, Centre Hospitalier Universitaire Vaudois, University of Lausanne, Lausanne, Switzerland (L.B.); the Department of Pediatrics, University of Freiburg, Freiburg, Germany (A.S.-F.); and the Center for Genomic Medicine, RIKEN, Tokyo (S.I.).

Address reprint requests to Dr. Warman at the Orthopedic Research Laboratories, Enders 907.2, Children's Hospital, 320 Longwood Ave., Boston, MA 02115, or at matthew.warman@childrens.harvard.edu.

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   Pui Yan Jenny Chung, Wim Van Hul,. (2011) Paget's Disease of Bone: Evidence for Complex Pathogenetic Interactions. Seminars in Arthritis and Rheumatism
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   Guillaume Lettre. (2011) Recent progress in the study of the genetics of height. Human Genetics 129:5, 465-472
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    Martin Lowe. (2011) Structural organization of the Golgi apparatus. Current Opinion in Cell Biology 23:1, 85-93
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    Allen W Root. (2010) Editorial comments: endocrinology and metabolism 2010. Current Opinion in Pediatrics 22:4, 467-469
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    Freeze, Hudson H., . (2010) Achondrogenesis Type 1A — From Mouse to Human. New England Journal of Medicine 362:3, 266-267
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