An assessment of rat photoreceptor sensitivity to mitochondrial blockade.

PURPOSE: To report results of functional, biochemical and structural studies of photoreceptor mitochondria in isolated rat retinas under conditions of mitochondrial inhibition. METHODS: Dark-adapted rat retinas were incubated in a modified Ringer's bicarbonate medium under aerobic and anaerobic conditions. Several different procedures were used to inhibit mitochondrial function; N2, 0.01 mM antimycin A, and 1 and 10 mM potassium cyanide (KCN). Measurements were made of lactic acid production, retinal adenosine triphosphate (ATP) content, and receptor potentials. Morphology of the inner segment mitochondria was examined by electron microscopy. RESULTS: In the presence of N2, 0.01 mM antimycin, or 1 mM KCN, lactic acid production was linear throughout the 60- minute period; and the rate was similar for each condition. Retinal ATP content and the amplitude of the receptor potential were also maintained at high levels after short-term incubations with either N2, antimycin A, or 1 mM KCN. In contrast, use of 10 mM KCN produced an entirely different set of results. These effects were studied both at the alkaline pH (8.9) found when this concentration of KCN was simply added to bicarbonate-buffered media and at the normal pH (after readjustment) of 7.4. With 10 mM KCN (pH 8.9), retinal lactate production was severely depressed, retinal ATP content was nearly depleted within 5 to 10 minutes, and the amplitude of the receptor potential rapidly declined to a low level. The deleterious effects of 10 mM KCN on these parameters were lessened to varying degrees when pH was readjusted to 7.4. Electron microscopic observations of rat rod inner segments indicated generally excellent survival of these organelles after incubation with either N2, antimycin A, or 1 mM KCN in comparison with their appearance under oxygenated conditions. However, the inner segments were significantly disrupted after incubation of retinas with 10 mM KCN. CONCLUSIONS: Findings suggest that the loss of the receptor potential and depletion of ATP observed with minutes after exposing isolated rat retinas to media containing 10 mM KCN results from the inhibition of both respiration and glycolysis by this high concentration of KCN. In contrast, when conditions are chosen so that only respiration is impaired (as with N2, antimycin A, or 1 mM KCN) photoreceptor cells are resistant to short-term episodes of mitochondrial inhibition, principally because the upregulation of glycolysis generates sufficient ATP to compensate reasonably well for the loss in mitochondrially produced ATP.

Early deletion of neuromeres in Wnt-1-/- mutant mice: evaluation by morphological and molecular markers.

The Wnt-1 gene is required for the development of midbrain and cerebellum; previous work showed that knockout of Wnt-1 causes the loss of most molecular markers of these structures in early embryos and deletion of these structures by birth. However, neither the extent of early neuronal defects nor any possible alterations in structures adjacent to presumptive midbrain and cerebellum were examined. By using a neuron-specific antibody and fluorescent axon tracers, we show that central and peripheral neuronal development are altered in mutants during initial axonogenesis on embryonic day 9.5. The absence of neuronal landmarks, including oculomotor and trochlear nerves and cerebellar plate, suggests that both mesencephalon and rhombomere 1 (r1) are delected, with the remaining neural tube fused to form a new border between the caudalmost portion of the prosencephalon (prosomere 1, or p1) and r2. Central axons accurately traverse this novel border by forming normal longitudinal tracts into the rhombencephalon, implying that the cues that direct these axons are aligned across neuromeres and are not affected by the delection. The presence of intact p1 and r2 is further supported by the retention of markers for these two neuromers, including a marker of p1, the Sim-2 gene, and an r2-specific lacZ transgene in mutant embryos. In addition, alterations in the Sim-2 expression domain in ventral prosencephalon, rostral to p1, provide novel evidence for Wnt-1 function in this region.

Cone photoreceptor regeneration in adult fish retina: phenotypic determination and mosaic pattern formation.

The retina of anamniotes (fish and amphibia), unlike the CNS of most vertebrates, can regenerate neurons following injury. Using the highly ordered mosaic of single and double cones in the retina of the adult green sunfish (Lepomis cyanellus) as our model system, we examined the events that followed the surgical excision of a small patch of central retina. After surgery there was a transient elevation in the number, and a change in the distribution, of proliferative cells within the retina. The wound was filled in two ways: a proliferative regeneration of new retina and a nonproliferative movement of the wound boundaries toward the center of the lesion. The nonproliferative movement stretched the surrounding, intact retina. In stretched retina the basic pattern of the cone mosaic was maintained, but it was augmented by new cones, even though cones are not normally generated in intact central retina. The stretch itself likely triggered the anomalous cone production. The new and preexisting cones in stretched retina had their morphological phenotypes influenced by mutual contact, often resulting in atypical morphologies (triple and quadruple cones). In the center of the lesioned area, the regenerated cone mosaic was disordered, had a higher than normal cone density, and contained atypical morphologies. The presence of outer segments and synaptic pedicles suggested that the new cones in regenerated and stretched retina were functional. We interpret these results to mean (1) a stretch-induced decrease in cell density can trigger a compensatory, adaptive neurogenesis, (2) cone morphological phenotypes in fish retina are plastic throughout life, and are influenced by cone-cone contacts, (3) the mechanisms that spatially regulate cone production during normal growth are disrupted regeneration.

Local regeneration in the retina of the goldfish.

We have studied regeneration of the retina in the goldfish as a model of regenerative neurogenesis in the central nervous system. Using a transscleral surgical approach, we excised small patches of retina that were replaced over several weeks by regeneration. Lesioned retinas from three groups of animals were studied to characterize, respectively, the qualitative changes of the retina and surrounding tissues during regeneration, the concomitant cellular proliferation, and the quantitative relationship between regenerated and intact retina. The qualitative and quantitative analyses were done on retinas prepared using standard methods for light microscopy. The planimetric density of regenerated and intact retinal neurons was computed in a group of animals in which the normal planimetric density ranged from high to low. Cell proliferation was investigated by making intraocular injections of 5-bromo-2'-deoxyuridine (BUdr) at various survival times to label proliferating cells and processing retinal sections for BUdr immunocytochemistry. The qualitative analysis showed that the surgery created a gap in the existing retina that was replaced with new retina over the subsequent weeks. The BUdr-labeling experiments demonstrated that the excised retina was replaced by regeneration of new neurons. Neuroepithial-like cells clustered on the wound margin and migrated centripetally, appositionally adding new retina to the old. The quantitative analysis showed that the planimetric density of the regenerated neurons approximated that of the intact ones.

Axonogenesis and morphogenesis in the embryonic zebrafish brain.

We have examined early neuronal differentiation and axonogenesis in the fore- and midbrain of zebrafish embryos to address general issues of early vertebrate brain development. AChE expression and HNK-1 antibody immunoreactivity were used as markers for differentiated neurons and axons, respectively. The pattern of neuronal differentiation followed a stereotyped sequence. AChE-positive cells first appeared between 14 and 16 hr in three small, isolated, bilaterally symmetrical clusters on the surface of the brain. The three clusters--the dorsorostral, ventrorostral, and ventrocaudal clusters--proved to be the progenitors of the telencephalon, ventral diencephalon, and mesencephalic tegmentum, respectively. With further development, more cells were added to these three clusters, and new clusters appeared in the anlage of the epiphysis (18 hr) and in the pituitary and dorsal mesencephalon (by 24 hr). Subsequently, as more neurons differentiated, the gaps of unlabeled cells were reduced; by 48 hr, the cluster boundaries were indistinguishable. Axonogenesis also followed a stereotyped sequence. The first HNK-1-labeled processes arose from the first three clusters of AChE-positive cells and connected the clusters. The earliest axonal growth cones appeared at 16 hr, directed caudally from two to three neurons of the ventrocaudal cluster and pioneering the ventral longitudinal tract. By 18 hr, the tract of the postoptic commissure was initiated by growth cones directed caudally from the ventrorostral cluster toward the ventrocaudal cluster. By 20 hr, axons from the dorsorostral cluster projected ventrally to form the supraoptic tract. The other dorsoventral tracts (the dorsoventral diencephalic tract and the tract of the posterior commissure) became evident between 20 and 24 hr. These observations provide a continuous record of the topological distortions involved in the conversion of the tubular embryonic brain into the contorted adult form. The telencephalon, ventral diencephalon, and hypothalamus originate from the same rostrocaudal level of the neural tube. The pattern of differentiation demonstrated that the early development of the rostral neural tube occurs simultaneously in several independent centers, similar to the overtly segmental development of the hindbrain.

Degenerative and regenerative changes in the trochlear nerve of goldfish.

The features of unlesioned and lesioned trochlear nerves of goldfish have been examined electron microscopically. Lesioned nerves were studied between 1 and 107 days after cutting or crushing the nerve. Unlesioned nerves contained, on average, 77 myelinated axons and 19 unmyelinated axons. The latter were found in 1-2 fascicles per nerve. A basal lamina surrounded each myelinated axon and fascicle of unmyelinated axons. The numbers of myelinated axons, fascicles of unmyelinated axons and basal laminae varied by less than 5% over the intraorbital extramuscular segment of the nerve. Following interruption of the nerve, by either cutting or crushing, all of the axons and their myelin sheaths began to degenerate by 4 days in the distal nerve-stump. Both abnormally electron-dense and electron-lucent axons were observed. Both Schwann cells and macrophages appeared to phagocytose the myelin sheaths. Following a lesion, the Schwann cells and their basal laminae persisted in the distal nerve-stump. In crushed nerves, the basal laminae surrounding myelinated axons formed 97%, on average, of the Schwann tubes in the distal stump. The perimeters of the basal laminae were of similar size to those in the proximal stump, at least for the first 8 days after crush. In crushed nerves, single myelinated axons in the proximal nerve-stump gave rise to multiple sprouts, some of which reached the site of crush by 2 days, the distal stump by 4 days and the superior oblique muscle by 8 days. The regeneration of the unmyelinated axons was not examined. In both crushed and transected nerves, nearly all of the sprouts in the proximal and distal stumps were found within the basal laminae of Schwann cells, even though the spouts were disorganized in the transected region where there were no basal laminae. The growth cones of the regenerating axons were always found apposed to the inner surface of the basal laminae, which may have provided an adhesive substrate that directed their growth. Terminal sprouts from the ends of myelinated axons in the proximal stump accounted for the majority of the regenerating axons in the distal stump, as only a few collateral sprouts were found in the proximal stump, and only a small amount of axonal branching was found within the distal stump itself. The largest axons in the distal stump were remyelinated first, and the number of remyelinated axons increased progressively between 8 and 31 days after crush, at which time there were about twice as many as in unlesioned nerves.(ABSTRACT TRUNCATED AT 400 WORDS)

Postembryonic growth of the optic tectum in goldfish. II. Modulation of cell proliferation by retinal fiber input.

The proliferation of cells in the germinal zone of the optic tectum of adult goldfish was studied following unilateral optic nerve crush or removal of one eye. Dividing germinal cells were labeled with [3H]thymidine, which was injected at various times (0 to 30 days) following surgery; fish were sacrificed after short (48 hr) survival times. The numbers of labeled nuclei in the tectal germinal zones were compared on the two sides (intact and denervated). We show that permanent removal of optic input (by enucleation) resulted in a sustained depression of [3H]thymidine incorporation in the tectal germinal zone on the denervated compared to the intact side. Temporary denervation (by optic nerve crush) initially had a similar effect; however, upon reinnervation of the tectum by regenerating optic fibers, proliferation was enhanced on the experimental side compared to the intact side. Because cells in the germinal zone are known to produce new tectal cells, neurons as well as glia, in the normal growing adult brain (Raymond, P. A. and S. S. Easter, Jr. (1983) J. Neurosci. 3: 1077-1091), some of the proliferating cells may have been generating neurons. This inference is supported by the observation that in two fish whose right eye had been removed more than 2 years earlier, there were fewer neurons in the denervated tectum than in the intact tectum. Thus, it is likely that the observed decrease in incorporation of [3H]thymidine by cells in the germinal zone of the denervated optic tectum resulted in a slower rate of addition of new tectal cells on the affected side. We conclude that cytogenesis in the germinal zone of the growing optic tectum of adult goldfish is regulated by optic fiber input. This mechanism may be important in matching the rates of growth of retina and tectum in the normal brain of the growing adult fish.

The paths and destinations of the induced ipsilateral retinal projection in goldfish.

Adult goldfish had one tectal lobe removed surgically, and several months later, the eye contralateral to the missing tectum was injected with radioactive proline. Radioautographs of the brains were studied to trace the paths and termination sites of the optic fibers. The optic tract decussated at the chiasm, as normally, but then ran caudally in a large neuroma on the tectum-less side of the brain. Substantial numbers of fibers left this neuroma to enter two or more of five commissures, through which they recrossed the midline. These commissures: transverse, minor, horizontal, posterior and ansate, ordinarily contain few or no optic fibers. All are normally linked with the tectum. Negligible numbers of aberrant optic fibers recrossed the midline elsewhere. On the intact side of the brain, ipsilateral to the injected eye, the optic fibers innervated some or all of the nuclei and areas normally served by contralateral retinal fibers. An earlier behavioral study of these same fish had shown that some of them made reversed optokinetic nystagmus in response to stripe movement seen by the eye projecting ipsilaterally; others failed to respond to stimuli through this eye. In all the reversed responders, a caudal group of retinal projection sites was labeled ipsilaterally. This included the basal optic nucleus and the caudal portions of nucleus dorsolateralis thalami and area pretectalis. In the non-responders, these targets were not labeled ipsilaterally. Together, these results suggest that one or more of these three sites is or are responsible for optokinetic nystagmus in normal goldfish.