Formation of hyposorhodopsin in frog retina.

Hypsorhodopsin was formed in frog retina by irradiation at liquid helium temperature and converted into bathorhodopsin above about 29K.     

Synaptic transmission in the retina.

A recent highlight in the study of the retina has been the publication of evidence that the response of the ON bipolar cells is generated by a cGMP-mediated second messenger system. This GTP-binding protein mechanism is activated by the binding of glutamate, the photoreceptor neurotransmitter, to the 2-amino-4-phosphonobutyrate (APB) class of receptor.     

Glutamate uptake by chick retina.

The uptake of glutamate was found to be via a single high-affinity transport mechanism with Km values of 35 and 95 mum for chick-embryo and mature chick retina respectively. These data contrast with the uptake of gamma-aminobutyratewhich in the same tissue has previously been shown to display two kinetically distinct mechanisms in the embryo, but a single low-affinity process in the mature retina.     

Differentiation of the retina and pigment epithelium in the ontogeny of the common frog. 1. The retina

Changes in the ultrastructure of the differentiating retinal cells were studied by means of electron microscopy in Rana temporaria at successive developmental stages. Common features of the onset of differentiation of the retinal cells have been shown: appearance of the granular endoplasmic reticulum elements, of the polysomes, beginning of utilization of the yolk and lipids, elimination of ovarial melanosomes. Later during the differentiation of retinal neurons the protein synthesizing machinery and Golgi complex of these cells develop markedly, the number of mitochondria increases. The differentiation of retina begins from the Müllerian cells (stage 28) which determine the direction of growth of the neuron processes. They are followed by the ganglion cells and photoreceptors (stage 29). The signs of differentiation of the inner nuclear layer neurons become apparent later, in the amacrine and horizontal cells at the same time and in the bipolars later. The main features of neuronal organization of the retina which determine the structural basis of its function of light perception are formed by stage 40.     

Formation of cone mosaic of zebrafish retina.

In the zebrafish retina, four types of cone photoreceptor cells (or cones) with different sensitive frequencies are arranged in a regular pattern, named "cone mosaic". A pair of small cones, one sensitive to red and the other sensitive to green, is in close contact and forms a "double cone". In addition, there are two kinds of single cones, sensitive to blue and to UV, respectively. We study characteristics of cell-differentiation rules that realize stable formation of cone mosaic. Assumptions are: undifferentiated cells are arranged in a regular square lattice, and they are one of the three types (B, U, and D cells). A D cell has two parts (G and R-parts) and takes one of the four directions. The cells change their cell type and orientation following a continuous-time Markovian chain. The state transtion occurs faster if it increases the stabilities of the focal cell, in which the stability is the sum of affinities with neighboring cells. After the transient period, the system may reach a stable pattern (pre-pattern). The pattern becomes fixed later when the cells are fully differentiated in which B cells, U cells, and D cells become blue-sensitive, UV-sensitive, and double cones, respectively. We search for the combinations of affinities between cell states that can generate the same cone mosaic patterns as in zerbrafish retina. Successful transition rules give (1) zero or small affinity with the pairs of cell states that are absent in the zebrafish cone mosaic (lambda(UR), lambda(BG)and the contact of two cells of the same type); (2) a large affinity between a part of D cells and a non-D cell (lambda(UG)and lambda(BR)); and (3) a positive affinity of an intermediate magnitude between two non-D cells (lambda(BU)) and between two parts of D cells (lambda(GR)). The latter should be of a magnitude of about 60-90% of the former. The time needed to form a regular pattern increases with the lattice size if all the cells start pre-pattern formation simultaneously. However, the convergence time is shortened considerably if the pre-pattern formation occurs only in a narrow band of morphogenetic cell layer that sweeps from one end of the lattice to the other.     

Regeneration of dopaminergic neurons in goldfish retina.

The conditions necessary to trigger regeneration of dopaminergic neurons were investigated in the goldfish retina. Intraocular injection of 6-hydroxydopamine (6-OHDA) was used to destroy dopaminergic neurons, and neuronal regeneration was monitored by injections of the thymidine analog bromodeoxyuridine (BUdR). Regenerated dopaminergic neurons, (identified by double-labeling with anti-tyrosine hydroxylase and anti-BUdR antibodies) were found within 3 weeks after 2 injections of 0.6 mg/ml 6-OHDA (estimated intraocular concentration), but not after injection of lower doses. All retinas with regenerated dopaminergic neurons also contained other types of regenerated neurons, including cones and ganglion cells, consistent with nuclear counts which revealed non-selective cell loss (34-36%) in both the outer and inner nuclear layers after exposure to the high dose, but not lower doses of 6-OHDA. Regenerated neurons were produced by clusters of dividing neuroepithelial cells probably derived from rod precursors in the outer nuclear layer. These results demonstrate that dopaminergic neurons will not regenerate after they are selectively ablated but only as part of a developmental process that involves generation of multiple cell types.     

Sulpholipid metabolism in developing chicken retina.

Glycolipid analysis of chicken retina and brain indicated the presence of cerebroside, cerebroside 3-sulphate and sulphogalactosylglycerolipid In retina, the ratio of cerebroside to cerebroside 3-sulphate was approximately half compared to brain. During chicken retina ontogenesis the ratio of cerebroside 3-sulphate to sulphogalactosylglycerolipid increased rapidly and in the adult animal, the amount of cerebroside 3-sulphate was 14 times higher than that of sulphogalactosylglycerolipid. The activity of PAPS: cerebroside sulphotransferase and arylsulphatase A in developing chicken retina indicated that the general ontogenic profiles of retinal PAPS: cerebroside sulphotransferase and arylsulphatase A were similar to those obtained for the brain. Both the enzymes showed the highest activity just before hatching. The significance of occurrence of sulpholipids in retina is discussed.     

Some properties of acetylcholinesterase from rat retina.

Acetylcholinesterase (AChE, EC 3.1.1.7) of rat retina was studied with respect to its kinetic and other properties, and a comparison was made with the enzyme from brain. The subcellular distribution of the retinal AChE showed that the enzyme was concentrated in the synaptosomal-mitochondrial fraction although in the brain the AChE was distributed more evenly between the fractions studied. The enzyme from both retina and brain was easily solubilised and exhibited a Km of the order of 10(-4) M. The pH optimum was 8.3-8.6 for the AChE from both tissues for both the soluble and particulate enzyme.     

Analysis of the retina via suprafusion electroretinography.

Electroretinographic (ERG) transient responses elicited in monkeys by abrupt changes in the periodicity of a rapidly intermittent (suprafusion) luminance stimulus were studied experimentally, and analyzed and interpreted through a theory of dynamic retinal responses. The suprafusion ERG transients are confirmed to behave in accord with theoretical expectation, as elemental responses (retinal Green's functions). By aid of the theory the ERG wave-forms can be reduced to two significant elements. One element, accounting for approximately two-thirds of the total ERG variance, is strictly linear, and correlates well with simultaneously evoked cortical (VEP) transients which were previously related to suprafusion perception in humans. The other element, comprising approximately one-third the ERG transient, is a rectification, with properties indicating that it may arise from a specific layer of retinal neurons (amacrine cells); on this assumption the theory demonstrates that high-frequency nonlinear ERG flicker can isolate activities proximal and distal to the rectifying (amacrine) layer. Thus, the hypothesis of an amacrine origin for the rectifying element entails the possibility that suprafusion ERG studies could accomplish in vivo "dissection" of the human retina.     

Muscarinic cholinergic receptors in goldfish retina.

Using ³H-Quinuclinidyl Benzilate (³H-QNB) as a high affinity ligand for quantitative studies of specific binding to muscarinic cholinergic receptors we have demonstrated the presence of such receptors in homogenates of goldfish retina. Only one set of binding sites could be detected with an apparent dissociation constant of 1.9 × 10^?10 M and a density of 53.5 fentomoles per mg of protein. The receptor sites become saturated at a QNB concentration of 1.2 nM. The pharmacological profile of the specific binding is similar to those described for homogenates of beef and chick retina, as well as for rodent brain and smooth muscle.