A novel cone visual cycle in the cone-dominated retina.

The visual processing of humans is primarily reliant upon the sensitivity of cone photoreceptors to light during daylight conditions. This underscores the importance of understanding how cone photoreceptors maintain the ability to detect light. The vertebrate retina consists of a combination of both rod and cone photoreceptors. Subsequent to light exposure, both rod and cone photoreceptors are dependent upon the recycling of vitamin A to regenerate photopigments, the proteins responsible for detecting light. Metabolic processing of vitamin A in support of rod photopigment renewal, the so-called "rod visual cycle", is well established. However, the metabolic processing of vitamin A in support of cone photopigment renewal remains a challenge for characterization in the recently discovered "cone visual cycle". In this review we summarize the research that has defined the rod visual cycle and our current concept of the novel cone visual cycle. Here, we highlight the research that supports the existence of a functional cone-specific visual cycle: the identification of novel enzymatic activities that contribute to retinoid recycling, the observation of vitamin A recycling in cone-dominated retinas, and the localization of some of these activities to the Müller cell. In the opinions of the authors, additional research on the possible interactions between these two visual cycles in the duplex retina is needed to understand visual detection in the human retina.

ARPE-19 cell growth and cell functions in euglycemic culture media.

Human retinal pigmented epithelial cells (ARPE-19) grown in euglycemic media (5.5 mM) had lower cell number, significantly different cell morphology, and lower levels of vascular endothelial growth factor (VEGF) in the culture media than those grown in hyperglycemic media (18 mM) customarily used for culturing ARPE-19 cells. Although it has been shown that within a 24-hour period, all-trans retinoic acid significantly reduces VEGF secretion by retinal pigmented epithelial cells (grown in 18 mM glucose), such an inhibitory effect was not observed in cells grown in 5.5 mM glucose. Our results suggest that ARPE-19 cells grown in euglycemic media exhibit distinctly different cell growth, cell differentiation, and cell functions in comparison to cells grown in hyperglycemic media. Because euglycemic conditions provide a physiological glucose environment, this glucose concentration must be included in all future investigations of the mechanism of diabetic retinopathy when studying VEGF secretion by ARPE-19 cells.

11-cis-Acyl-CoA:retinol O-acyltransferase activity in the primary culture of chicken Muller cells.

A novel retinoid cycle has recently been identified in the cone-dominated chicken retina, and this cone cycle accumulates 11-cis-retinyl esters upon light adaptation. The purpose of this study is to investigate how 11-cis-retinyl esters are formed in the retina. Primary cultures of chicken Muller cells and cell membrane were incubated with all-trans- or 11-cis-retinol to study retinyl ester synthesis. In Muller cells, esterification of 11-cis-retinol was four times greater than esterification of all-trans-retinol. In the presence of palmitoyl-CoA and CRALBP, Muller cell membranes synthesized 11-cis-retinyl ester from 11-cis-retinol at a rate which was 20-fold higher than that of all-trans-retinyl ester. In the absence of CRALBP, 11-cis-retinyl ester synthesis was greatly reduced (by 7-fold). In the absence of palmitoyl-CoA, retinyl ester synthesis was not observed. Muller cell membranes incubated with radiolabeled palmitoyl-CoA resulted in the transfer of the labeled acyl group to retinol. This acyl transfer was greatly reduced in the presence of progesterone, a known ARAT inhibitor. 11-cis-ARAT activity remained unchanged when assayed in the presence of all-trans-retinol, suggesting a distinct catalytic activity from that of all-trans-ARAT. Apparent kinetic rates for 11-cis-ARAT were 0.135 nmol min(-)(1) mg(-)(1) (V(max)) and 11.25 microM (K(M)) and for all-trans-ARAT were 0.0065 nmol min(-)(1) mg(-)(1) (V(max)) and 28.88 microM (K(M)). Our data indicate that Muller cells in the chicken retina possess 11-cis-ARAT activity, thus providing an explanation for the accumulation of 11-cis-retinyl esters in the cone cycle.

Effect of light exposure on the accumulation and depletion of retinyl ester in the chicken retina.

A previous study has shown that in the cone-rich chicken retina, 11-cis retinyl ester increases with light exposure and decreases in subsequent dark adaptation. The purpose of this research is to study how light exposure (intensity and duration) determine the rate of accumulation and utilization as well as the size of this 11-cis retinyl ester pool in the chicken retina. Chickens were dark-adapted overnight before exposure to different light intensities and durations. Animals were sampled at regular time intervals. 11-cis retinal and 11-cis retinyl ester were extracted from the retina and analyzed by HPLC. An increase in light intensity from 1,000 and 2,000 Lux (for a 20 min exposure) increased the amount of 11-cis retinyl ester from 0.38 to 0.75 nmol/mg. An increase in the duration of light exposure from 10 to 20 min (at 2,000 Lux) also increased the amount of 11-cis retinyl ester in the chicken retina (from 0.37 to 0.75 nmol/mg). This 11-cis retinyl ester pool in the chicken retina was rapidly reduced to baseline level ( approximately 0.20 nmol/mg) upon dark adaptation. The rate of accumulation of 11-cis retinyl ester was dependent on light intensity and duration of exposure and the maximum rate was approximately 0.03 nmol/mg/min. In comparison, dark adaptation was associated with a significantly higher rate of 11-cis retinyl ester depletion (approximately 0.05), indicating that light exposure and dark adaptation were associated with different biochemical steps of retinoid storage and utilization. Results from this study are the first to show that the size of the 11-cis retinyl ester pool, as well as the rate of its accumulation and depletion in the cone-rich chicken retina, are determined by the intensity and duration of light exposure. These data support the suggestion that a light-driven cone cycle exists in the chicken retina.

Retinoid cycles in the cone-dominated chicken retina.

In past decades, the role of retinoids in support of rod photopigment regeneration has been extensively characterized. In the rhodopsin cycle, retinal chromophore from bleached rod pigments is reduced to retinol and transferred to the retinal pigment epithelium (RPE) to store as all-trans retinyl ester. This ester pool is subsequently utilized for visual pigment regeneration. However, there is a lack of information on the putative cone visual cycle. In the present study, we provide experimental evidence in support of a novel retinoid cycle for cone photopigment regeneration. In the cone-rich chicken, light exposure resulted in the accumulation of 11-cis retinyl esters to the retina and all-trans retinyl esters to the RPE. Both the rate of increase and the amount of 11-cis retinyl esters in the retina far exceeded those of the all-trans retinyl esters in the RPE. In response to dark adaptation, this 11-cis retinyl ester pool in the retina depletes at a rate several times faster than the all-trans retinyl ester pool in the RPE. In vitro, isolated, dark-adapted retinas devoid of RPE show both an accumulation of 11-cis retinyl ester and a concomitant reduction of 11-cis retinal chromophore in response to light exposure. Finally, we provide experimental results to elucidate a cone visual cycle in chicken by relating the change in retinoids (retinal and retinyl ester) with time during light and dark adaptation. Our results support a new paradigm for cone photopigment regeneration in which the 11-cis retinyl ester pool in the retina serves as the primary source of visual chromophore for cone pigment regeneration.