A naturally occurring canine model of syndromic congenital microphthalmia.

In humans, the prevalence of congenital microphthalmia is estimated to be 0.2-3.0 for every 10,000 individuals, with nonocular involvement reported in ∼80% of cases. Inherited eye diseases have been widely and descriptively characterized in dogs, and canine models of ocular diseases have played an essential role in unraveling the pathophysiology and development of new therapies. A naturally occurring canine model of a syndromic disorder characterized by microphthalmia was discovered in the Portuguese water dog. As nonocular findings included tooth enamel malformations, stunted growth, anemia, and thrombocytopenia, we hence termed this disorder Canine Congenital Microphthalmos with Hematopoietic Defects. Genome-wide association study and homozygosity mapping detected a 2 Mb candidate region on canine chromosome 4. Whole-genome sequencing and mapping against the Canfam4 reference revealed a Short interspersed element insertion in exon 2 of the DNAJC1 gene (g.74,274,883ins[T70]TGCTGCTTGGATT). Subsequent real-time PCR-based mass genotyping of a larger Portuguese water dog population found that the homozygous mutant genotype was perfectly associated with the Canine Congenital Microphthalmos with Hematopoietic Defects phenotype. Biallelic variants in DNAJC21 are mostly found to be associated with bone marrow failure syndrome type 3, with a phenotype that has a certain degree of overlap with Fanconi anemia, dyskeratosis congenita, Shwachman-Diamond syndrome, Diamond-Blackfan anemia, and reports of individuals showing thrombocytopenia, microdontia, and microphthalmia. We, therefore, propose Canine Congenital Microphthalmos with Hematopoietic Defects as a naturally occurring model for DNAJC21-associated syndromes.

[Macrophthalmos mimics microphthalmos in an 8-month-old Great Swiss Mountain Dog]. / Makrophthalmus imitiert Mikrophthalmus bei einem 8 Monate alten Großen Schweizer Sennenhund.

An 8-month-old Great Swiss Mountain dog was presented with a suspected right-sided microphthalmos, malformed and blind globe which was present since birth. On magnetic resonance imaging an ellipsoid macrophthalmos with absence of the normal retrobulbar tissue was detected. Histology revealed a dysplastic uvea with unilateral cyst formation associated with mild lymphohistiocytic inflammation. The ciliary body covered the posterior side of the lens unilaterally and showed focal metaplastic bone formation. Slight cataract formation as well as diffuse panretinal atrophy and intravitreal retinal detachment was evident. Preoperative diagnostic imaging procedure is recommended in eyes that clinically demonstrate as microphthalmos and are planned to be enucleated. As described in this case report the bulbus may be macrophthalmic which potentially complicates the enucleation. The performance of such a procedure at a site with ophthalmologic and soft tissue expertise is advisable. To the authors' knowledge this is the first report of a macrophthalmos with multiple ocular defects in a dog.

Microphthalmia, aphakia and agenesis of the optic chiasm and tract in a wild fox squirrel (Sciurusniger).

We describe gross and histopathological features of multiple ocular and neuro-ophthalmic abnormalities in a fox squirrel (Sciurus niger). Ophthalmic findings included severe bilateral microphthalmos, with the right eye more affected than the left. Histopathology confirmed severe microphthalmia, aphakia, disorganized retinal tissue and small optic nerves, as well as agenesis of the optic chiasm and optic tract. This combination of neuro-ophthalmic abnormalities has not been previously described in wild animals.

Nonketotic hyperglycinemia in captive-bred Vervet monkeys (Chlorocebus aethiops) with cataracts.

BACKGROUND: Nonketotic hyperglycinemia (NKH) is a rare metabolic disorder that is characterized by high levels of glycine in plasma and cerebrospinal fluid in humans. In this study, total congenital cataract captive-bred Vervet monkeys (Chlorocebus aethiops) that are hyperglycinemic were screened to identify mutations in Bola type 3 (BOLA3), glutaredoxin 5 (GLRX5), and lipoate synthase (LIAS) genes. METHODS: Twenty-four Vervet monkeys (12 hyperglycinemic and 12 healthy controls) were selected for mutation analysis using polymerase chain reaction (PCR), Sanger sequencing, and reverse transcriptase-polymerase chain reaction (RT-PCR). RESULTS: Novel sequence variants were identified in BOLA3 (R23H and Q38R) and LIAS (R369I and A371A), and gene expression in the control group was significantly lower compared to the hyperglycinemic group (P < 0.05). CONCLUSION: The data obtained from this study will contribute to generation of new knowledge regarding the involvement of these genes in NKH development.

Microphthalmia With Multiple Anterior Segment Defects in Portuguese Water Dogs.

Portuguese Water Dog breeders and veterinary ophthalmologists recognize microphthalmia with multiple congenital ocular anomalies. Fifteen Portuguese Water Dog puppies (<8 weeks of age; 8 females, 7 males) and 1 adult (5 years old; castrated male) with microphthalmia were examined. The 2 most common abnormalities were microphthalmia (31/32 eyes; 97%) and lens abnormality (congenital cataract or aphakia; 32/32 eyes; 100%). Other common histologic lesions included lack of both a ciliary cleft and trabecular meshwork (15/32 eyes; 47%) and abnormal relationship of anterior segment structures (15/32 eyes; 47%). Many of the observed lesions were similar to those described in various types of anterior segment dysgenesis in humans. Our findings define the histologic lesions in affected Portuguese Water Dogs and suggest a genetic defect that causes anterior segment malformation early in development.

Autosomal recessive congenital cataract in captive-bred vervet monkeys (Chlorocebus aethiops).

BACKGROUND: The aim of the study was to evaluate the genetic predisposition of congenital cataract in a colony of captive-bred vervet monkeys. METHODS: Four congenital cataract genes: glucosaminyl (N-acetyl) transferase 2 (GCNT2), heat shock transcription factor 4 (HSF4), crystallin alpha A (CRYAA) and lens intrinsic membrane protein-2 (LIM2) were screened, sequenced and analysed for possible genetic variants in 36 monkeys. Gene expression was also evaluated in these genes. RESULTS: Fifteen sequence variants were identified in the coding regions of three genes (GCNT2, HSF4 and CRYAA). Of these variations, only three were missense mutations (M258V, V16I and S24N) and identified in the GCNT2 transcripts A, B and C, respectively, which resulted in a downregulated gene expression. CONCLUSION: Although the three missense mutations in GCNT2 have a benign effect, a possibility exists that the candidate genes (GCNT2, HSF4 and CRYAA) might harbour mutations that are responsible for total congenital cataract.

Microphthalmia, corneal dermoids, and congenital anomalies resembling Goldenhar syndrome in a cat.

CASE DESCRIPTION An 18-month-old spayed female domestic shorthair cat was evaluated because of conjunctivitis and skin-fold dermatitis secondary to bilateral microphthalmia, corneal dermoids, and ankyloblepharon. CLINICAL FINDINGS Physical examination revealed bilateral microphthalmia, bilaterally symmetrical corneal dermoids, ankyloblepharon, superior and inferior entropion, prognathism, and facial asymmetry with deviation of the nasal septum. Computed tomography revealed malformed, thickened bony orbits with mineralization of the orbital ligament bilaterally. Moderate rightward deviation of the nasal septum and ventral nasal meatus was also evident, with no identifiable maxillary sinuses. Results of MRI of the brain were unremarkable. Abdominal ultrasonography showed an irregularly marginated left kidney and a right kidney defect suggestive of chronic renal infarction. An abnormal, well-demarcated, focally thickened region of the muscularis externa of the jejunum was also evident. TREATMENT AND OUTCOME Transpalpebral enucleation was performed bilaterally. Histologic examination of ocular tissues confirmed the corneal dermoids and microphthalmia with anterior and posterior segment dysgenesis and cataracts in both eyes. Ocular discomfort resolved after postoperative recovery, and follow-up revealed that the patient's activity level and quality of life were excellent. No clinical signs of upper respiratory, urinary, or gastrointestinal tract disease were observed during the approximately 3.5-year follow-up period. CLINICAL RELEVANCE The congenital abnormalities observed resembled those described for human patients with Goldenhar syndrome, and the outcome of treatment was favorable. This report may prompt clinicians to consider this diagnosis when evaluating young cats with similar clinical signs.

[Ocular dermoids and microphthalmia in a juvenile sheep]. / Okuläre Dermoide und Mikrophthalmie bei einem Jungschaf.

A 6-month-old Leine sheep was presented because of dermal tissue located on the left eye. During the first examination, the animal was clinically silent, apart from the deformed eye. A corneal and conjunctival dermoid and blindness of the left eye were diagnosed. Over a period of a year, the animal displayed conjunctivitis and inflammation of the affected eye. Furthermore, the sheep did not develop according to its age. During histopathological examination of the euthanized animal, microphthalmia and aphakia of the left eye were found in addition to the dermoids. Dermoids are described in humans and in different domestic animals. They can be combined with other congenital malformations. In sheep, dermoids are rarely diagnosed or reported in the literature.

Bilateral oblique facial clefts, rudimentary eyes and hydrocephalus in an aborted equine foetus.

Knowledge of congenital malformations and their causes in horses is generally sparse. Such conditions require more scientific attention to improve their diagnostics and inform prevention strategies. Here, a unique syndrome of bilateral oblique facial clefts (meloschisis), rudimentary eyes and hydrocephalus is reported in an equine foetus spontaneously aborted at gestation day 224. The cause of abortion was considered to be intrauterine death caused by umbilical cord torsions and subsequent compromised blood flow, but the aetiology of the malformation could not be determined. A detailed history, which includes exposure to a range of pharmaceutical compounds during the early stages of pregnancy, is provided and emphasizes the need for accurate recording of treatments in pregnant animals.

Requirement of Smad4 from Ocular Surface Ectoderm for Retinal Development.

Microphthalmia is characterized by abnormally small eyes and usually retinal dysplasia, accounting for up to 11% of the blindness in children. Right now there is no effective treatment for the disease, and the underlying mechanisms, especially how retinal dysplasia develops from microphthalmia and whether it depends on the signals from lens ectoderm are still unclear. Mutations in genes of the TGF-ß superfamily have been noted in patients with microphthalmia. Using conditional knockout mice, here we address the question that whether ocular surface ectoderm-derived Smad4 modulates retinal development. We found that loss of Smad4 specifically on surface lens ectoderm leads to microphthalmia and dysplasia of retina. Retinal dysplasia in the knockout mice is caused by the delayed or failed differentiation and apoptosis of retinal cells. Microarray analyses revealed that members of Hedgehog and Wnt signaling pathways are affected in the knockout retinas, suggesting that ocular surface ectoderm-derived Smad4 can regulate Hedgehog and Wnt signaling in the retina. Our studies suggest that defective of ocular surface ectoderm may affect retinal development.

Campylorrhinus lateralis, Bilateral microphthalmia and odontoma temporalis in an Oldenburg Foal.

An Oldenburg colt with wry nose was autopsied after having lived for only 30 min. It presented cyanotic oral mucosae, underdeveloped eyes and a right-sided temporal osseous mass. The applicable nomenclature for the defects is discussed, and the potential etiopathogenesis is explored by describing the normal embryonic development of the affected body parts.

Unilateral microphthalmia or anophthalmia in eight pythons (Pythonidae).

OBJECTIVE: To provide morphological descriptions of microphthalmia or anophthalmia in eight pythons using microcomputerized tomography (µCT), magnetic resonance imaging (MRI), and histopathology. ANIMALS STUDIED: Seven Burmese pythons (Python bivittatus) and one ball python (P. regius) with clinically normal right eyes and an abnormal or missing left eye. PROCEDURE: At the time of euthanasia, four of the eight snakes underwent necropsy. Hereafter, the heads of two Burmese pythons and one ball python were examined using µCT, and another Burmese python was subjected to MRI. Following these procedures, the heads of these four pythons along with the heads of an additional three Burmese pythons were prepared for histology. RESULTS: All eight snakes had left ocular openings seen as dermal invaginations between 0.2 and 2.0 mm in diameter. They also had varying degrees of malformations of the orbital bones and a limited presence of nervous, glandular, and muscle tissue in the posterior orbit. Two individuals had small but identifiable eyes. Furthermore, remnants of the pigmented embryonic framework of the hyaloid vessels were found in the anophthalmic snakes. Necropsies revealed no other macroscopic anomalies. CONCLUSIONS: Eight pythons with unilateral left-sided microphthalmia or anophthalmia had one normal eye and a left orbit with malformed or incompletely developed ocular structures along with remnants of fetal structures. These cases lend further information to a condition that is often seen in snakes, but infrequently described.

A 19-Mb de novo deletion on BTA 22 including MITF leads to microphthalmia and the absence of pigmentation in a Holstein calf.

Mutations in MITF lead to a large variety of phenotypes in human, mice and other species. They mostly affect pigmentation and hearing, whereas in mice, they may additionally cause microphthalmia and osteopetrosis. In this study, we report a single case of a Holstein calf with lack of pigmentation and microphthalmia born to healthy parents. Mendelian analysis of high-density SNP genotypes reveals a large number of parentage errors showing missing paternal alleles in the offspring, indicating a deletion encompassing 19 Mb on BTA 22. The genomic deletion affects the paternal allele and includes MITF and 131 other annotated genes. As the calf shows only one copy of the BTA 22 segment, the observed phenotype is probably caused by haploinsufficiency of the genes in that genomic region. Both the observed lack of skin pigmentation and reduced eye size can most likely be explained by a lack of MITF function.

Congenital ocular and adnexal disorders in reptiles.

Ocular and adnexal congenital disorders are those that manifest at birth and could involve single or multiple tissues. Several abnormalities have been reported in literature affecting reptilian ocular and/or adnexal tissues. The objectives of this review are: (i) review those disorders previously reported in reptile literature; (ii) present new cases; (iii) provide a basic classification of them according to the moment of occurrence and (iv) indirectly, encourage the clinician dealing with these cases to go further in their diagnosis. The authors consider that categorizing ocular and adnexal congenital disorders could help the clinician to deal with them. The categorization of these disorders required an intense review of cases previously reported in literature and allows the authors suspect that some of them could not have been accurately diagnosed according to the definitions of the anomalies and/or not accurately described. The authors consider that ocular and adnexal congenital disorders could have been underestimated in reptiles and further studies could be helpful to promote the description of new disorders and to expand the knowledge about those previously reported. The review will first describe abnormalities reported during organogenesis (describing possible etiopathogenesis, cases reported, an approach to their diagnosis and recommended therapeutic options).Then a mention of the ocular disorders occurring after organogenesis is made. These disorders are divided when possible in those affecting all or most part of the globe and those affecting only specific tissues (surface ectoderm, neurocrest and mesenchyma and neuroectoderm).

Bilateral microphthalmia and aphakia associated with multiple eye abnormalities in a free-living European red deer calf (Cervus elaphus).

A free-living European red deer calf (Cervus elaphus) was euthanized due to bilateral microphthalmia. Lens was missing, replaced by proliferating squamous epithelial cells; hyperplastic squamous cells, sebaceous and mucinous glands were observed within the cornea with the characteristics of inclusion cyst. Findings were consistent with congenital microphthalmia/aphakia, with multiple eye abnormalities.

Bilateral complex microphthalmia with intraocular dermoid cyst in a neonate red deer (Cervus elaphus).

A 3-day-old, male red deer (Cervus elaphus) with bilateral microphthalmia was found dead in the Western Alps in northern Italy. No other gross alterations were present. Ocular globes were formalin fixed and processed for histology. In both eyes, a large cyst, filled with keratin and lined by squamous epithelium admixed with sebaceous glands and hair follicles, expanded the anterior chamber. A mass composed of spindle cells and small tubules, embedded in myxoid ground substance, filled the vitreal chamber. No lens tissue was found, leading to the speculation that the dermoid cystic structures originated from abnormal differentiation of the primitive ectodermal lens vesicle. Immunohistochemistry with a panel of antibodies against cytoskeletal proteins revealed neural and mesenchymal elements within the vitreal mass. A complex bilateral ocular dysgenesis, with microphthalmia, aphakia, and dermoid metaplasia of primitive lens vesicle was diagnosed. The latter finding was unusual and was previously documented only in Texel sheep (Ovis ammon), in which it was related to specific gene mutation on chromosome 23.