Suppression of developmental retinal cell death but not of photoreceptor degeneration in Bax-deficient mice.

PURPOSE: Bax, a member of the Bcl2 family of cell death regulators, induces cell death by promoting the induction of apoptosis. Bax-deficient mice were examined in this study to determine whether Bax is required for cell death in the developing retina and for pathologic apoptotic photoreceptor degeneration resulting from the rd mutation. METHODS: Retinas from Bax-deficient mice and their wild-type siblings were harvested at postnatal day (P) 7 and processed for TdT-dUTP terminal nick-end labeling (TUNEL) staining, and the number of nuclei containing fragmented DNA were counted. Adult retinas and optic nerves were processed for plastic-embedded 1-microm sections, and the cross-sectional area was determined. The mutant Bax allele was outbred onto the C3H mouse strain, which carries the rd allele. Retinas from these animals were examined histologically at P21 after most of the photoreceptor cell death had occurred. RESULTS: At P7, around the time of peak cell death in the inner nuclear layer (INL), significantly fewer neurons in INL and ganglion cell layer (GCL) were TUNEL positive in Bax-deficient mice than in their wild-type siblings. In adult Bax-deficient mice, the cross-sectional area of the optic nerve was approximately 50% larger than in wild-type siblings, and the total number of retinal ganglion cell axons was increased to 226%. The INL of Bax-deficient mice was thicker than normal. The Bax genotype did not affect the thickness or histologic appearance of the outer nuclear layer in retinas of mice with wild-type or mutant rd alleles. CONCLUSIONS: In the absence of the expression of the Bax gene, there is a profound increase in the survival of retinal ganglion cells that lasts into adulthood. Similarly, death of INL cells is diminished but not completely abolished. The absence of Bax does not, however, protect photoreceptors from naturally occurring cell death or degeneration induced by the rd mutation. This shows that Bax is involved to a variable degree in the control of developmental cell death in the retina and that not all apoptotic retinal cell deaths are controlled by Bax.

The murine tub (rd5) mutation is not associated with a primary axonemal defect.

Some genetic syndromes causing loss of hearing and vision, such as some forms of Usher's syndrome, also cause reduced sperm cell motility, bronchiectasis, and other pathologies involving cilia- and flagella-bearing cells. In some Usher's patients, ultrastructural defects of axonemes within photoreceptor ciliary bridges, nasal cilia, and sperm cell flagella have been found, indicating a primary defect of axonemal conformation. Mice homozygous for the tub (rd5) mutation exhibit progressive retinal degeneration, sensorineural hearing loss, reduced fertility, and obesity, and presently represent the only animal model with neuroepithelial degeneration of both cochlea and retina without other neurological abnormalities. They provide a good phenotypic match to human genetic sensory syndromes, particularly human sensory/obesity syndromes, such as Alstrom's and Bardet/Biedl, although no human candidate genes have been identified. Because of their unique phenotype, tubby mice are an appropriate model in which to look for a primary axonemal defect. We studied the axonemal ultrastructure of photoreceptors and sperm cells and performed functional testing of sperm in tub/tub mice before and after the onset of obesity. Approximately 15% of photoreceptor axonemes appeared abnormal in tub/tub animals, compared to 0% in controls. Both tub homozygotes and controls exhibited approximately 10% abnormal sperm cell axonemes, and no differences in sperm cell motile function were found at any age. The modest occurrence of axonemal defects in photoreceptors of tub/tub animals is likely to be a secondary effect of retinal degeneration. We conclude that the tubby phenotype is not associated with a generalized defect of cilia- and flagella-bearing cells and that the tub mutation does not primarily affect axonemal structure.

Débridement of the pig retinal pigment epithelium in vivo.

OBJECTIVE: To study the morphologic effects of surgical débridement of the retinal pigment epithelium (RPE) in an animal model. METHODS: A pars plana vitrectomy was performed in the domestic pig, and a neurosensory retinal detachment was created by injecting the calcium-chelating agent edetic acid (commonly referred to as ethylenediaminetetraacetic acid or EDTA) into the subretinal space through a retinotomy. Twenty minutes later, the RPE was débrided by gently brushing Bruch's membrane with a soft-tip silicone catheter. Dissociated RPE was aspirated from the subretinal space, and the retina was reattached with a fluid-gas exchange. RESULTS: Light microscopic analysis confirmed that Bruch's membrane was devoid of native RPE and the choriocapillaris was morphologically intact immediately after débridement. Photoreceptor outer segments were disrupted and foreshortened immediately after RPE débridement. One to 4 weeks later, a layer of hypopigmented RPE covered most of the previously débrided areas of Bruch's membrane. The choriocapillaris was intact in areas of Bruch's membrane that were repopulated by hypopigmented RPE, and remained intact 12 weeks after débridement. Some regions of Bruch's membrane near the retinotomy remained devoid of RPE for more than 4 weeks after débridement. The choriocapillaris was atrophic and there was extensive disruption of the outer retinal layers in these areas. CONCLUSIONS: The RPE healed in most areas after surgical débridement of the RPE in the experimental animal. Atrophy of the choriocapillaris was present in areas of poor RPE healing near the retinotomy.

Cochlear and retinal degeneration in the tubby mouse.

A number of autosomal recessive syndromes feature both sensorineural hearing loss and retinal degeneration. The mouse mutant tubby also combines hearing loss with progressive retinal degeneration, and thus may constitute a useful model of one form of human sensorineural deafness/retinal dystrophic syndrome. It has not been directly demonstrated that the hearing loss in this mouse involves the cochlea, however. We have examined the cochleas of adult tubby mice using light microscopy. The tubby cochlea shows pronounced degeneration of the organ of Corti and loss of afferent neurons in the base, with relative sparing of the apex. Our findings support the tubby mouse as a model of human sensorineural deafness/retinal dystrophic syndrome. Possible human counterparts include Usher's, Alstrom's, and Bardet-Biedl syndromes.