Onset and time course of apoptosis in the developing zebrafish retina.

In mammalian development, apoptosis spreads over the retina in consecutive waves and induces a remarkable amount of cell loss. No evidence for such consecutive waves has been revealed in the fish retina so far. As the zebrafish is of growing importance as a model for retinal development and for degenerative retinal diseases, we examined the onset and time course of apoptosis in the developing zebrafish retina and in adult fish. We found that apoptosis peaked in the ganglion cell layer (GCL) and inner nuclear layer (INL) in early developmental stages (3-4 days post-fertilization; dpf) followed by a second, but clearly smaller wave at 6-7dpf. Apoptosis in the outer nuclear layer (ONL) started at 5dpf and peaked at 7dpf. This late-onset high peak of apoptosis of photoreceptors is different from that of all other species examined to date. With 1.09% of cells in the GCL and 1.10% in the ONL being apoptotic, the rate of apoptosis in the developing zebrafish retina was conspicuously lower than that observed in other vertebrates (up to 50% in GCL). During development (2-21dpf), apoptotic waves were most obvious in the central retina, whereas in the periphery near the marginal zone (MZ), apoptosis was much lower; in adult animals, practically no apoptosis was present in the central retina but it still occurred near the MZ. Our data show that the onset and time course of apoptosis in the GCL and INL of the zebrafish is comparable with other vertebrates; however, the amount of apoptosis is clearly reduced. Thus, apoptosis in the zebrafish retina may serve more as a mechanism for the fine tuning of the retinal neuronal network after mitotic waves during development or in remaining mitotic areas than as a mechanism for eliminating large numbers of excess cells.

Genetic disorders of vision revealed by a behavioral screen of 400 essential loci in zebrafish.

We examined optokinetic and optomotor responses of 450 zebrafish mutants, which were isolated previously based on defects in organ formation, tissue patterning, pigmentation, axon guidance, or other visible phenotypes. These strains carry single point mutations in >400 essential loci. We asked which fraction of the mutants develop blindness or other types of impairments specific to the visual system. Twelve mutants failed to respond in either one or both of our assays. Subsequent histological and electroretinographic analysis revealed unique deficits at various stages of the visual pathway, including lens degeneration (bumper), melanin deficiency (sandy), lack of ganglion cells (lakritz), ipsilateral misrouting of axons (belladonna), optic-nerve disorganization (grumpy and sleepy), inner nuclear layer or outer plexiform layer malfunction (noir, dropje, and possibly steifftier), and disruption of retinotectal impulse activity (macho and blumenkohl). Surprisingly, mutants with abnormally large or small eyes or severe wiring defects frequently exhibit no discernible behavioral deficits. In addition, we identified 13 blind mutants that display outer-retina dystrophy, making this syndrome the single-most common cause of inherited blindness in zebrafish. Our screen showed that a significant fraction (approximately 5%) of the essential loci also participate in visual functions but did not reveal any systematic genetic linkage to particular morphological traits. The mutations uncovered by our behavioral assays provide distinct entry points for the study of visual pathways and set the stage for a genetic dissection of vertebrate vision.