The ocular findings in Kniest dysplasia

The genetics and disease mechanisms of rhegmatogenous retinal detachment

Rhegmatogenous retinal detachment (RRD) is a sight threatening condition that warrants immediate surgical intervention. To date, 29 genes have been associated with monogenic disorders involving RRD. In addition, RRD can occur as a multifactorial disease through a combined effect of multiple genetic variants and non-genetic risk factors. In this review, we provide a comprehensive overview of the spectrum of hereditary disorders involving RRD. We discuss genotype-phenotype correlations of these monogenic disorders, and describe genetic variants associated with RRD through multifactorial inheritance. Furthermore, we evaluate our current understanding of the molecular disease mechanisms of RRD-associated genetic variants on collagen proteins, proteoglycan versican, and the TGF-β pathway. Finally, we review the role of genetics in patient management and prevention of RRD. We provide recommendations for genetic testing and prophylaxis of at-risk patients, and hypothesize on novel therapeutic approaches beyond surgical intervention.

Orthodontic Treatment in a Patient With Kniest Dysplasia: A Case Study and Review of Literature

Kniest dysplasia is a rare autosomal dominant chondrodysplasia that is characterized by distinct musculoskeletal and craniofacial irregularities. These craniofacial abnormalities include cleft palate, midface anomalies, tracheomalacia, and hearing loss. This article illustrates a case of Kniest dysplasia that presented for orthodontic treatment. The purpose of this literature review is to describe clinical manifestations, radiographic features, histopathological features, genetic mutation, and management of Kniest dysplasia.

Clinical, histopathological and genetic characterisation of oculoskeletal dysplasia in the Northern Inuit Dog

Seven Northern Inuit Dogs (NID) were diagnosed by pedigree analysis with an autosomal recessive inherited oculoskeletal dysplasia (OSD). Short-limbed dwarfism, angular limb deformities and a variable combination of macroglobus, cataracts, lens coloboma, microphakia and vitreopathy were present in all seven dogs, while retinal detachment was diagnosed in five dogs. Autosomal recessive OSD caused by COL9A3 and COL9A2 mutations have previously been identified in the Labrador Retriever (dwarfism with retinal dysplasia 1-drd1) and Samoyed dog (dwarfism with retinal dysplasia 2-drd2) respectively; both of those mutations were excluded in all affected NID. Nine candidate genes were screened in whole genome sequence data; only one variant was identified that was homozygous in two affected NID but absent in controls. This variant was a nonsense single nucleotide polymorphism in COL9A3 predicted to result in a premature termination codon and a truncated protein product. This variant was genotyped in a total of 1,232 dogs. All seven affected NID were homozygous for the variant allele (T/T), while 31/116 OSD-unaffected NID were heterozygous for the variant (C/T) and 85/116 were homozygous for the wildtype allele (C/C); indicating a significant association with OSD (p = 1.41x10-11). A subset of 56 NID unrelated at the parent level were analysed to determine an allele frequency of 0.08, estimating carrier and affected rates to be 15% and 0.6% respectively in NID. All 1,109 non-NID were C/C, suggesting the variant is rare or absent in other breeds. Expression of retinal mRNA was similar between an OSD-affected NID and OSD-unaffected non-NID. In conclusion, a nonsense variant in COL9A3 is strongly associated with OSD in NID, and appears to be widespread in this breed.

Stickler syndrome: exploring prophylaxis for retinal detachment

PURPOSE OF REVIEW

The literature regarding prophylactic treatment of rhegmatogenous retinal detachment in Stickler syndrome remains controversial. We review major published clinical studies and offer a critical analysis of this subject.

SUMMARY

Stickler syndrome is a systemic collagenopathy affecting multiple organ systems including the eye, ear, and skeleton. Stickler syndrome is probably the most common cause of genetically determined pediatric rhegmatogenous retinal detachment. Congenital developmental anomalies constitute over half rhegmatogenous detachments (RRD) in patients less than 10 years. The majority are caused by hereditary vitreoretinopathies associated with Stickler syndrome. Sixty percent of patients with Stickler syndrome develop RRD's over their lifetime with possible severe visual loss and subsequent lifelong morbidity. In view of these complications, some have emphasized the importance of prophylactic laser treatment to the retina of patients with Stickler syndrome to reduce the occurrence of and/or prevent future rhegmatogenous retinal detachment, but there appears to be insufficient data to support the absolute benefit of such prophylactic treatment. Guidelines regarding the age at prophylactic treatment as well as type and frequency of intervention are scarce and would benefit from additional clinical investigations.

Ageing of the vitreous: From acute onset floaters and flashes to retinal detachment

Floaters and flashes are most commonly symptoms of age-related degenerative changes in the vitreous body and posterior vitreous detachment. The etiology and pathogenesis of floaters' formation is still not well understood. Patients with acute-onset floaters, flashes and defects in their visual field, represent a medical emergency with the need for same day referral to an ophthalmologist. Indirect ophthalmoscopy with scleral indentation is needed in order to find possible retinal break(s), on-time treatment and prevention of retinal detachment. The molecular and genetic pathogenesis, as well as the epidemiology of the ageing changes of the vitreous is summarized here, with view on the several treatment modalities in relation to their success rate and side-effects.

Ophthalmic and molecular genetic findings in Kniest dysplasia

PURPOSE

To study the variability of the ophthalmic phenotype in Kniest dysplasia. Kniest dysplasia is an inherited disorder associated with defects in type II collagen and characterised by short-trunked dwarfism, kyphoscoliosis, and enlarged joints with restricted mobility. Other features include marked hand arthropathy, cleft palate, hearing loss, and ocular abnormalities (myopia, abnormal vitreous, and high risk of developing retinal detachment).

METHODS

Data from eight unrelated individuals with a clinical and molecular diagnosis of Kniest dysplasia are reported. Clinical assessment included an audiogram and ophthalmological examination in all but one patient who died in the immediate postnatal period. Sanger sequencing of the COL2A1 gene was performed.

RESULTS

Six of the seven patients tested were high myopes with one patient being an emmetrope. Bilateral quandratic cataracts and subluxed lenses were noted in one subject. Variable but abnormal vitreous architecture was observed in all seven individuals tested. Six of the seven patients had significant hearing impairment and five of the seven patients exhibited clefting abnormalities. One patient had bilateral retinal detachments in his twenties. Six dominant disease-causing COL2A1 variants were detected. In three cases, testing of parental samples revealed that the disease-causing variant was not present in either parent.

CONCLUSION

The ophthalmic features in Kniest dysplasia are very similar to those in other disorders of type II collagen such as Stickler syndrome. It is likely that different type II collagenopathies have a similar level of ocular morbidity and regular ophthalmologic examination is recommended. Kniest dysplasia is associated with heterozygous COL2A1 mutations that are frequently de novo.

Evaluation of pediatric cataracts and systemic disorders

PURPOSE OF REVIEW

The purpose of this review is to outline those systemic disorders with associated cataracts to help in the evaluation and diagnosis of the patient with pediatric cataract who has systemic abnormalities.

RECENT FINDINGS

With the profound advancement in genetics, both making and confirming a diagnosis in rare syndromic disorders have become even more possible. By diagnosing a syndromic cataract, the patient and family members are afforded the opportunity to obtain a better understanding of their disorder as well as develop expectations as to the course of their child's disorder.

SUMMARY

The intent of this article is to act as a resource for helping to determine the cause of cataracts based on the lens appearance, age of onset and systemic findings. Children with cataracts, especially when bilateral, require a comprehensive history and ophthalmic examination with physician awareness toward other organ system involvement. A basic assessment of facial, skeletal, genitourinary, gastrointestinal and integumentary abnormalities is beneficial. In this review, there are numerous tables that are to act as a resource in developing a differential diagnosis and guide further systemic and genetic evaluation.

COL9A2 and COL9A3 mutations in canine autosomal recessive oculoskeletal dysplasia

Oculoskeletal dysplasia segregates as an autosomal recessive trait in the Labrador retriever and Samoyed canine breeds, in which the causative loci have been termed drd1 and drd2, respectively. Affected dogs exhibit short-limbed dwarfism and severe ocular defects. The disease phenotype resembles human hereditary arthro-ophthalmopathies such as Stickler and Marshall syndromes, although these disorders are usually dominant. Linkage studies mapped drd1 to canine chromosome 24 and drd2 to canine chromosome 15. Positional candidate gene analysis then led to the identification of a 1-base insertional mutation in exon 1 of COL9A3 that cosegregates with drd1 and a 1,267-bp deletion mutation in the 5' end of COL9A2 that cosegregates with drd2. Both mutations affect the COL3 domain of the respective gene. Northern analysis showed that RNA expression of the respective genes was reduced in affected retinas. These models offer potential for studies such as protein-protein interactions between different members of the collagen gene family, regulation and expression of these genes in retina and cartilage, and even opportunities for gene therapy.

Significant ocular findings are a feature of heritable bone dysplasias resulting from defects in type II collagen

BACKGROUND/AIMS

The type II collagenopathies are a phenotypically diverse group of genetic skeletal disorders caused by a mutation in the gene coding for type II collagen. Reports published before the causative mutations were discovered suggest heritable bone dysplasias with skeletal malformations may be associated with a vitreoretinopathy.

METHODS

A retrospective notes search of patients with a molecularly characterised type II collagenopathy chondrodysplasia who had been examined in the ophthalmology clinic was conducted.

RESULTS

13 of 14 patients had a highly abnormal vitreous appearance. One patient aged 11 presented with a total retinal detachment. Two other children aged 2 and 4 had bilateral flat multiple retinal tears on presentation. 10 of 12 patients refracted were myopic. Two patients had asymptomatic lens opacities: one associated with bilateral inferiorly subluxed lenses and the other with a zonule and lens coloboma.

CONCLUSION

Heritable skeletal disorders resulting from a mutation in the gene coding for type II collagen are associated with abnormal vitreous, myopia and peripheral cataract with lens subluxation. In bone dysplasias resulting from a defect of type II collagen there is likely to be a high risk of retinal detachment with a propensity to retinal tears at a young age.

Collagens and collagen-related matrix components in the human and mouse eye

The three-dimensional structure of the eye plays an important role in providing a correct optical environment for vision. Much of this function is dependent on the unique structural features of ocular connective tissue, especially of the collagen types and their supramolecular structures. For example, the organization of collagen fibrils is largely responsible for transparency and refraction of cornea, lens and vitreous body, and collagens present in the sclera are largely responsible for the structural strength of the eye. Phylogenetically, most of the collagens are highly conserved between different species, which suggests that collagens also share similar functions in mice and men. Despite considerable differences between the mouse and the human eye, particularly in the proportion of the different tissue components, the difficulty of performing systematic histologic and molecular studies on the human eye has made mouse an appealing alternative to studies addressing the role of individual genes and their mutations in ocular diseases. From a genetic standpoint, the mouse has major advantages over other experimental animals as its genome is better known than that of other species and it can be manipulated by the modern techniques of genetic engineering. Furthermore, it is easy, quick and relatively cheap to produce large quantities of mice for systematic studies. Thus, transgenic techniques have made it possible to study consequences of specific mutations in genes coding for structural components of ocular connective tissues in mice. As these changes in mice have been shown to resemble those in human diseases, mouse models are likely to provide efficient tools for pathogenetic studies on human disorders affecting the extracellular matrix. This review is aimed to clarify the role of collagenous components in the mouse and human eye with a closer look at the new findings of the collagens in the cartilage and the eye, the so-called "cartilage collagens".

Autosomal dominant rhegmatogenous retinal detachment--clinical appearance and surgical outcome

PURPOSE

To study the clinical appearance and surgical results of autosomal dominantly inherited rhegmatogenous retinal detachments (RRDs).

METHODS

After prospective examination of all but two family members, the medical records of 16 affected patients (21 eyes) of two families from the Netherlands with autosomal dominantly inherited RRD were retrospectively evaluated. Special attention was paid to the age at onset, the ocular morphology and the clinical appearance of the RRD. The type and number of the various surgical procedures were analyzed with respect to preoperative appearance of the RRD, postoperative results and final visual acuity.

RESULTS

The mean age at onset of RRD of affected individuals in families A and B was 37 +/- 18 years and 19 +/- 10 years, respectively. The mean ocular axial length in the two families was 24.7 mm and 26.7 mm. The mean number of retinal defects preoperatively found was 2.2 in family A and 7.1 in family B. Round, atrophic retinal holes predominated. Two of 21 affected eyes showed significant preoperative proliferative vitreoretinopathy. Pars plana vitrectomy was the primary procedure in 4 cases; extra ocular buckling was the initial procedure in 15 cases. One eye received scleral folding with diathermy as primary surgery. Redetachment following surgery occurred in 5 of 10 cases in family A and 4 of 10 eyes in family B. Anatomical success could be achieved in 9 of 10 and 8 of 10 eyes in families A and B, respectively.

CONCLUSIONS

In these families the prevalence of RRD is high. Most patients were affected at a relatively young age compared with non-genetically linked forms of RRD. Because of the low success rate of surgical intervention and, subsequently, the high number of operations necessary to achieve reattachment of the retina, the use of diagnostic genetic techniques to identify individuals at risk would be advisable. In these subjects measures to prevent RRD are an option, even when anatomical substrates of precursors of RRD are absent.

A case of Kniest dysplasia with retinal detachment and the mutation analysis

PURPOSE

To report a case of Kniest dysplasia with retinal detachment associated with a novel type II collagen gene (COL2A1) mutation.

DESIGN

Interventional case report.

METHODS

DNA was isolated from peripheral lymphocytes, and mutational analysis was carried out using polymerase chain reaction and direct sequencing.

RESULTS

A 14-year-old Japanese boy was diagnosed with Kniest dysplasia, and ophthalmic examination revealed a retinal detachment in the right eye. He was successfully treated by vitrectomy and silicon oil injection, and his visual acuity improved from 0.01 to 0.22. DNA analysis of COL2A1 revealed a single base-pair substitution at position +5 of intron 20.

CONCLUSION

Vitrectomy and silicon oil injection were effective in reattaching the retinal detachment in a Kniest dysplasia patient. The genetic alteration found in this patient suggested that this prevented the normal splicing of COL2A1, resulting in an abnormal type II collagen product.

Expression of Sox9 and type IIA procollagen during ocular development and aging in transgenic Del1 mice with a mutation in the type II collagen gene

PURPOSE

To study the expression and distribution of transcription factor Sox9 and type IIA procollagen in the developing and aging eyes of normal and transgenic Dell mice carrying pro(alpha)1(II) collagen transgenes with a short deletion mutation, which cause ocular abnormalities in this mouse line.

METHODS

The eyes of Del1 mice were studied on embryonic days E14.5, E16.5 and E18.5, and at the ages of 4 and nine months, using their nontransgenic littermates as controls. Sox9 and pro(alpha)1(IIA) collagen were detected by RNase protection assay and immunohistochemistry.

RESULTS

RNase protection assay revealed Sox9 transcripts in the eyes of Del1 and control mice during development and aging. The mRNA for type IIA procollagen had a similar temporal expression pattern. On embryonic days E14.5, E16.5 and E18.5, Sox9 was located by immunohistochemistry in the nuclei and type IIA procollagen in the extracellular space of the developing retina. During growth and aging, the ocular expression of Sox9 mRNA and the immunohistochemical reaction for Sox9 antibody diminished, concomitant with the reduction in type II procollagen mRNA. However, at the age of nine months, levels of Sox9 and type IIA procollagen mRNAs were higher in the degenerating eyes of Del1 and control mice.

CONCLUSIONS

The similarities in the temporo-spatial distribution of Sox9 and type IIA procollagen suggest that this transcription factor is involved in the activation of type II collagen expression in the eye, as has been demonstrated in prechondrogenic mesenchyme and immature cartilage. The increased production of Sox9 and type IIA procollagen in the aging retina and vitreous is analogous to degenerating articular cartilage where attempted tissue repair has also been observed.

Ultrastructural characterization of developmental and degenerative vitreo-retinal changes in the eyes of transgenic mice with a deletion mutation in type II collagen gene

PURPOSE

Molecular genetic analyses have clearly associated vitreoretinal degeneration with mutations in the type II collagen gene, but lack of experimental models has prevented systematic analyses of the occurrence of phenotypic changes and of the pathogenetic mechanisms involved. The present study is a detailed morphological and ultrastructural analysis of the vitreoretinal consequences of a small deletion mutation in the type II collagen gene.

METHODS

The eyes of Del1 mice carrying six copies of pro alpha1(II) collagen transgene with a small deletion mutation were analyzed during embryonic development, postnatal growth and aging using their nontransgenic littermates as controls. Tissue samples were processed for light and electron microscopy for morphological and ultrastructural analyses. Transcription of pro alpha1(II) collagen gene was localized by in situ hybridization, and type II collagen was detected by immunohistochemistry.

RESULTS

In this mouse model most components of the eye are ultrastructurally unaltered. However, the transgenes caused a dose-dependent dominant negative effect seen as a reduced number of type II collagen fibrils in the vitreous. In concert with this, dose-dependent accumulation of amorphous material was observed in the dilated rough endoplasmic reticulum of cells responsible for the production of type II collagen molecules. In mice homozygous for the transgene locus, the vitreoretinal degenerative lesions appeared already during late embryonic development. In mice heterozygous for the locus, such changes were milder and appeared only during postnatal growth and progressed gradually upon aging.

CONCLUSIONS

The observed ultrastructural changes suggest that defective structure and function of collagen fibrils in Del1 mice result from a partial block in the post-translational processing and secretion of the mutated procollagen chains, and partly from secretion of mutated procollagen molecules which interfere with normal fibrillogenesis.

Cloning and characterization of opticin cDNA: evaluation as a candidate for canine oculo-skeletal dysplasia

Opticin, a novel member of the leucine-rich repeat (LRR) family, has been reported to bind to collagen fibrils. Many members of the LRR family of extracellular matrix proteins have been reported to bind to fibrillar collagen and regulate the diameter of collagen fibrils and lateral fusion between fibrils. Collagen fibrils are important for the maintenance of the vitreous body in the eye and growth plate cartilage of joints. Oculo-skeletal dysplasia (OSD) is a heterogeneous group of heritable genetic disorders affecting humans and a few breeds of dogs. Labrador retrievers and Samoyeds affected with non-allelic forms of OSD exhibit vitreous dysplasia and dwarfism, and could serve as an animal model for the disorder. To test the opticin gene as a candidate for OSD, canine opticin cDNA has been cloned and characterized. The predicted 327 amino acid sequence is 77% homologous to human opticin, and maintains characteristic structural domains including seven LRR domains, two cysteine clusters and potential O-linked glycosylation sites. It shows highest protein sequence identity to epiphycan (37%) and osteoglycin (31%) and belongs to the Class III family of LRR extracellular matrix proteins. In addition to ocular tissues and cartilage, opticin mRNA and protein have been identified in ligament, skin, muscle, and testes. No alteration of opticin expression at the protein level was observed in OSD affected dogs relative to normal controls. Based on linkage analysis using a newly identified intragenic single nucleotide polymorphism opticin has been excluded from having any causal association with the OSD loci in both Samoyeds and Labrador retrievers.

Age-dependent changes in the expression of matrix components in the mouse eye

Although the presence of 'cartilage-specific' collagens in the eye has been documented earlier, very little is known about their synthesis rates during ocular development, growth and aging. The purpose of the present study was to follow changes in the mRNA levels and distribution of key components of the extracellular matrix in the eyes of normal and transgenic Del1 mice, harboring a short deletion mutation in the type II collagen gene, during ocular growth and aging. Total RNAs extracted from mouse eyes were studied by Northern analysis for mRNA levels of type I, II, III, VI, IX and XI collagens, biglycan, fibromodulin and decorin. A predominant finding of the present study was the marked reduction in the mRNA levels of type I and II collagens in the eye upon aging. The changes in the mRNA levels of type III and VI collagen and proteoglycans were smaller. Localization of type II and IX collagen in the eye was performed by immunohistochemistry. Despite the reduction in the type II collagen mRNA levels, immunohistochemistry confirmed widespread distribution of the protein also in aging mouse eyes, suggesting its slow turnover. Although the Del1 mutation caused gradual degenerative lesions in the eyes, the distribution of the protein remained essentially unchanged. The widespread distribution and marked downregulation of type II collagen production in the mouse eye upon aging probably explain the gradual development of degenerative lesions, particularly in the eyes of transgenic Del1 mice, where production of mutant type II collagen chains also contributes to the process.

Cloning and expression of type II collagen mRNA: evaluation as a candidate for canine oculo-skeletal dysplasia

The disease phenotype of oculo-skeletal dysplasia (OSD) detected in Labrador retrievers and Samoyeds shows a large degree of similarity with human Stickler and Kniest dysplasia. Type II collagen (COL2A1) mRNA, which is defective in a larger number of Stickler and Kniest patients, has been cloned and characterized from normal dog. The amino acid sequence of the canine type II procollagen is predicted to contain 1487 residues, with high degree of homology with its human homologue, and maintains all the characteristic structural domains. In addition to cartilage, expression of COL2A1 has also been detected in canine retina and testes. In testes, the N-propeptide region of COL2A1 displayed differential splicing and expressed both splice variants, IIA (with exon 2) and IIB (without exon 2), suggesting the importance of both forms in testis maturation and maintenance. Despite a severe decrease of type II collagen protein in the vitreous of OSD affected Labrador retrievers, COL2A1 gene has been excluded from having any causal association with the disease locus by linkage analysis. Using an intragenic RFLP marker, COL2A1 gene has also been tested as a candidate gene for the non-allelic form of the other canine OSD identified in Samoyeds, and excluded by linkage analysis. Oculo-skeletal dysplastic Labrador retriever and Samoyed provide two animal models for chondrodysplasia with genetic heterogeneity.

Clinical and molecular genetics of Stickler syndrome

Stickler syndrome is an autosomal dominant disorder with characteristic ophthalmological and orofacial features, deafness, and arthritis. Abnormalities of vitreous gel architecture are a pathognomonic feature, usually associated with high myopia which is congenital and non-progressive. There is a substantial risk of retinal detachment. Less common ophthalmological features include paravascular pigmented lattice degeneration and cataracts. Non-ocular features show great variation in expression. Children with Stickler syndrome typically have a flat midface with depressed nasal bridge, short nose, anteverted nares, and micrognathia. These features can become less pronounced with age. Midline clefting, if present, ranges in severity from a cleft of the soft palate to Pierre-Robin sequence. There is joint hypermobility which declines with age. Osteoarthritis develops typically in the third or fourth decade. Mild spondyloepiphyseal dysplasia is often apparent radiologically. Sensorineural deafness with high tone loss may be asymptomatic or mild. Occasional findings include slender extremities and long fingers. Stature and intellect are usually normal. Mitral valve prolapse was reported to be a common finding in one series but not in our experience. The majority of families with Stickler syndrome have mutations in the COL2A1 gene and show the characteristic type 1 vitreous phenotype. The remainder with the type 2 vitreous phenotype have mutations in COL11A1 or other loci yet to be identified. Mutations in COL11A2 can give rise to a syndrome with the systemic features of Stickler syndrome but no ophthalmological abnormality.

Incorporation of structurally defective type II collagen into cartilage matrix in kniest chondrodysplasia

Kniest dysplasia, a human chondrodysplasia that severely affects skeletal growth, is caused by mutations in the type II collagen gene, COL2A1. We report here on abnormal type II collagen in the cartilage from a lethal Kniest dysplasia case and identify a novel exon-skipping mutation. Screening of cyanogen bromide (CB) peptides from the cartilage samples by SDS-PAGE indicated an abnormality in peptide alpha1(II)CB11. Further peptide mapping and N-terminal sequence analysis showed a 15-amino-acid deletion encoded by exon 15 in about 25% of the alpha1(II) chains in the cartilage. The mutation responsible for exon skipping was found by sequencing amplified genomic DNA. The baby was heterozygous for a G to A transition at the first position of the splice donor of intron 15. Pepsin-solubilized type II collagen from the cartilage matrix contained both normal alpha1(II) and shortened chains expressed from the mutant allele. Trypsin cleaved the native molecules below 37 degrees C selectively at a site within the exon 15-encoded domain of the normal alpha1(II) chains. This is best explained by the coassembly of normal and truncated alpha1(II) chains into heterotrimers in which the triple helix is normally folded in both directions from the deletion site but the latter presents a region of local disruption. The findings support an emerging pattern of COL2A1 mutations that can cause Kniest dysplasia. Short deletions (single or partial exon) clustered in one region of the alpha1(II) chain are favored, resulting in abnormal heterotrimeric molecules that become a significant component of the cartilage extracellular matrix.

Hereditary vitreopathy

Heterogeneity has long been recognised within the spectrum of inherited vitreo-retinal disease but the extent of the variation has been less easy to quantify. This has been compounded by the small size and numbers of pedigrees available for the study, and the phenotypic variation both within and between pedigrees. Formation abnormalities in the vitreous architecture have, in the past, been eclipsed by classifications based on general skeletal and morphological differences. Stickler syndrome is the commonest disorder within the spectrum of hereditary vitreous abnormalities and many of the recent published advances relate to this. Stickler syndrome has been subclassified on the basis of vitreo-retinal phenotype: type 1 families with a characteristic congenital vitreous anomaly show linkage without recombination to markers at the COL2A1 locus; type 2 families with different congenital vitreo-retinal phenotypes are not linked to COL2A1. A recent report identifies the COL11A2 mutation in a Dutch pedigree with systemic features of Stickler syndrome but without ocular involvement. Others have implicated COL11A1 in a type 2 Stickler syndrome pedigree with ocular abnormalities. Both COL11A1 and COL11A2 are expressed in cartilage, but on the basis of studies of bovine vitreous it is likely that only the alpha 1(XI) chain encoded by COL11A1 is present in vitreous. This would be consistent with the hypothesis that mutations in the genes encoding collagen XI can give rise to manifestations of Stickler syndrome, but of these, only mutations in COL11A1 will give the full syndrome including the vitreo-retinal features.

Congenital glaucoma and skeletal dysplasia

We have observed congenital glaucoma in a patient with a skeletal dysplasia closely resembling Kniest syndrome. The clinical and radiographic features, along with the differential diagnosis of Kniest syndrome, are discussed. Review of the literature suggests a relationship between the pathophysiology of bone dysplasia and congenital glaucoma. Congenital glaucoma may be an additional ocular finding in Kniest syndrome.

Kniest dysplasia is characterized by an apparent abnormal processing of the C-propeptide of type II cartilage collagen resulting in imperfect fibril assembly

Epiphyseal and growth plate cartilages from four cases of Kniest dysplasia have been studied. In each case collagen fibril organization appeared abnormal by electron microscopy compared with age-matched normal cartilages: fibrils were much thinner, of irregular shape and did not exhibit the characteristic banding pattern. This was associated with the absence (compared with normal cartilage) of the C-propeptide of type II collagen (chondrocalcin) from the extracellular matrix of epiphyseal cartilages, although it was detected (as in normal cartilages) in the lower hypertrophic zone of the growth plate in association with calcifying cartilage. The C-propeptide was abnormally concentrated in intracellular vacuolar sites in Kniest cartilages and its total content was reduced in all cases but not in all cartilages. Moreover, it was not a part of the procollagen molecule. In contrast, type II collagen alpha-chain size was normal, indicating the formation of a triple helix. Also type II collagen content was normal and it was present in extracellular sites and only occasionally detected intracellularly. These observations suggest that the defect in Kniest dysplasia may result from the secretion of type II procollagen lacking the C-propeptide and abnormal fibril formation, and that the C-propeptide is normally required for fibril formation.