Chunhe Chen

Reduction of All-trans-retinal in Vertebrate Rod Photoreceptors Requires the Combined Action of RDH8 and RDH12

Background: Retinoid dehydrogenases/reductases (RDHs) reduce retinal in rod photoreceptors. Results: In single rod cells, RDH8 reduces retinal generated in outer segments; RDH12 reduces retinal that escapes to inner segments. Conclusion: By detoxifying stray retinal, RDH12 acts as a barrier against intracellular aldehyde diffusion. Significance: This protective role is consistent with the severe pathology resulting from RDH12 mutations in human disease. In vertebrate rod cells, retinoid dehydrogenases/reductases (RDHs) are critical for reducing the reactive aldehyde all-trans-retinal that is released by photoactivated rhodopsin, to all-trans-retinol (vitamin A). Previous studies have shown that RDH8 localizes to photoreceptor outer segments and is a strong candidate for performing this role. However, RDH12 function in the photoreceptor inner segments is also key, because loss of function mutations cause retinal degeneration in some forms of Leber congenital amaurosis. To investigate the in vivo roles of RDH8 and RDH12, we used fluorescence imaging to examine all-trans-retinol production in single isolated rod cells from wild-type mice and knock-out mice lacking either one or both RDHs. Outer segments of rods deficient in Rdh8 failed to reduce all-trans-retinal, but those deficient in Rdh12 were unaffected. Following exposure to light, a leak of retinoids from outer to inner segments was detected in rods from both wild-type and knock-out mice. In cells lacking Rdh8 or Rdh12, this leak was mainly all-trans-retinal. Wild-type rods incubated with all-trans-retinal reduced moderate loads of retinal within the cell interior, but this ability was lost by cells deficient in Rdh8 or Rdh12. Our findings are consistent with localization of RDH8 to the outer segment where it provides most of the activity needed to reduce all-trans-retinal generated by the light response. In contrast, RDH12 in inner segments can protect vital cell organelles against aldehyde toxicity caused by an intracellular leak of all-trans-retinal, as well as other aldehydes originating both inside and outside the cell.

Calcium and Phototransduction

Visual phototransduction, the conversion of incoming light to an electrical signal, takes place in the outer segments of the rod and cone photoreceptor cells. Light reduces the concentration of cGMP, which, in darkness, keeps open cationic channels present in the plasma membrane of the outer segment. Ca2+ plays an important role in phototransduction by modulating the cGMP-gated channels as well as cGMP synthesis and breakdown. Ca2+ is involved in a negative feedback that is essential for photoreceptor adaptation to background illumination. The effects of Ca2+ on the different components of rod phototransduction have been characterized and can quantitatively account for the steady state responses of the rod cell to background illumination. The propagation of the Ca2+ feedback signal from the periphery toward the center of the outer segment depends on the Ca2+ diffusion coefficient, which has a value of 15 +/- 1 microm2 s(-1). This value shows that diffusion of Ca2+ in the radial direction is quite slow providing a significant barrier in the propagation of the feedback signal. Also, because the diffusion coefficient of Ca2+ is much smaller than that of cGMP, the decline of Ca2+ in the longitudinal direction lags behind the propagation of excitation by the decline of cGMP.

Rod Outer Segment Retinol Formation Is Independent of Abca4, Arrestin, Rhodopsin Kinase, and Rhodopsin Palmitylation

PURPOSE The reactive aldehyde all-trans retinal is released in rod photoreceptor outer segments by photoactivated rhodopsin and is eliminated through reduction to all-trans retinol. This study was undertaken to determine whether all-trans retinol formation depends on Abca4, arrestin, rhodopsin kinase, and the palmitylation of rhodopsin, all of which are factors that affect the release and sequestration of all-trans retinal. METHODS Experiments were performed in isolated retinas and single living rods derived from 129/sv wild-type mice and Abca4-, arrestin-, and rhodopsin kinase-deficient mice and in genetically modified mice containing unpalmitylated rhodopsin. Formation of all-trans retinol was measured by imaging its fluorescence and by HPLC of retina extracts. The release of all-trans retinal from photoactivated rhodopsin was measured in purified rod outer segment membranes according to the increase in tryptophan fluorescence. All experiments were performed at 37°C. RESULTS The kinetics of all-trans retinol formation in the different types of genetically modified mice are in reasonable agreement with those in wild-type animals. The kinetics of all-trans retinol formation in 129/sv mice are similar to those in C57BL/6, although the latter are known to regenerate rhodopsin much more slowly. The release of all-trans retinal from rhodopsin in purified membranes is significantly faster than the formation of all-trans retinol in intact cells and is independent of the presence of the palmitate groups. CONCLUSIONS The regeneration of rhodopsin and the recycling of its chromophore are not strongly coupled. Neither the activities of Abca4, rhodopsin kinase, and arrestin, nor the palmitylation of rhodopsin affects the formation of all-trans retinol.

All‐Trans Retinal Mediates Light‐Induced Oxidation in Single Living Rod Photoreceptors†

All‐trans retinal is a potent photosensitizer that is released in photoreceptor outer segments by the photoactivated visual pigment following the detection of light. Photoreceptor outer segments also contain high concentrations of polyunsaturated fatty acids, and are thus particularly susceptible to oxidative damage such as that initiated by light via a photosensitizer. Upon its release, all‐trans retinal is reduced within the outer segment to all‐trans retinol, through a reaction requiring metabolic input in the form of NADPH. The phototoxic potential of physiologically generated all‐trans retinal was examined in single living rod photoreceptors obtained from frog (Rana pipiens) retinas. Light‐induced oxidation was measured with fluorescence imaging using an oxidation‐sensitive indicator dye from the shift in fluorescence between the intact and oxidized forms. Light‐induced oxidation was highest in metabolically compromised rod outer segments following photoactivation of the visual pigment rhodopsin, and after a time interval, sufficiently long to ensure the release of all‐trans retinal. Furthermore, light‐induced oxidation increased with the concentration of exogenously added all‐trans retinal. The results show that the all‐trans retinal generated during the detection of light can mediate light‐induced oxidation. Its removal through reduction to all‐trans retinol protects photoreceptor outer segments against light‐induced oxidative damage.

Rapid formation of all-trans retinol after bleaching in frog and mouse rod photoreceptor outer segments

All-trans retinol is formed in the outer segments of vertebrate rod photoreceptors from the reduction of the all-trans retinal released by photoactivated rhodopsin. The reduction requires NADPH and is therefore dependent on metabolic input. In metabolically intact photoreceptors, a large increase in rod outer segment fluorescence, attributed to the fluorescence of all-trans retinol, follows rhodopsin photoactivation. The fluorescence increase is biphasic, including a rapid and a slow component. In metabolically compromised cells, there is a much smaller fluorescence increase following rhodopsin photoactivation, but it too contains a rapid component. We have measured the fluorescence signal in single living frog and mouse rod photoreceptors, and have characterized its dependence on the wavelengths of light selected for excitation and for collecting emission. We find that in metabolically intact cells, the excitation and emission properties of both the rapid and slow components of the fluorescence signal are in close agreement with those of all-trans retinol fluorescence. In metabolically compromised cells, however, the signal can only partially be due to all-trans retinol, and most of it is consistent with all-trans retinal. The results suggest that in the outer segments of living rod photoreceptors there is rapid release of all-trans retinal, which in metabolically intact cells is accompanied by rapid conversion to all-trans retinol.

Longitudinal diffusion of a polar tracer in the outer segments of rod photoreceptors from different species.

Abstract Vertebrate rod photoreceptors are the ultimate light sensors, as they can detect a single photon. In darkness, rods maintain a high concentration of the intracellular messenger cyclic guanosine monophosphate (cGMP), which binds to and keeps open cationic channels on the plasma membrane of the outer segment. Absorption of a photon by the visual pigment of the rod, rhodopsin, initiates a biochemical amplification cascade that leads to a reduction in the concentration of cGMP and closure of the channels, thereby converting the incoming light to an electrical signal. Because the absorption of a photon and the ensuing reactions are localized events, the magnitude of the response of the rod to a single photon depends on the spread of the decrease in the cGMP concentration along the length of the outer segment. The longitudinal diffusion of cGMP depends on the structural parameters of the rod outer segment, specifically the area and the volume available for diffusion. To characterize the effect of rod outer segment cytoarchitecture on diffusion, we have used fluorescence recovery after photobleaching (FRAP) and examined the mobility of a fluorescent polar tracer, calcein, in the rod outer segments from three species with different outer segment structures: frog (Rana pipiens), mouse (Mus musculus domesticus) and gecko (Gekko gekko). We found that the diffusion coefficient is similar for all three species, in the order of 8–17 μm2 s−1, in broad agreement with the predictions by Holcman and Korenbrot (Biophys. J. 2004:86;2566–2582) based on the known cytoarchitecture of rod outer segments. Consequently, the results also support their prediction that the longitudinal spread of light excitation in rods is similar across species.

Regulation of the visual cycle: retinol dehydrogenase and retinol fluorescence measurements in vertebrate retina.

The initial and only light-activated step in vision is the photoisomerization of the ligand of the visual pigment,11-cis retinal to all-trans retinal, which occurs while being covalently bound to a lysine deep in the membrane region of the visual pigment. This event leads to the activation of the g-protein, transducin, which in turn activates c-gmp phosphodiesterase causing the destruction of c-gmp, the closure of cation channels in the plasma membrane of the photoreceptor, and eventually to the reduction in release of synaptic transmitter to other retinal neurons in the visual pathway. However, the visual pigment containing retinal in its all-trans form is now incapable of absorbing photons in the visual region of the spectrum and can no longer activate the transduction cascade. In order to do so, it must be regenerated into a form that contains 1 1-cis retinal. The biochemical reactions by which this occurs are collectively called the visual cycle. This complex series of reactions is initiated in the photoreceptors themselves, by the reduction of all-trans retinal to all-trans retinol by all-trans retinol dehydrogenase (rdh) and the cofactor nadph. All the subsequent steps in the regeneration of 11-cis retinal take place in the retinal pigment epithelium. Regenerated 11-cis retinal is then transported from the retinal pigment epithelium through the extracellular matrix back to the photoreceptor cells where it condenses with opsin to reform visual pigment.

Hepatic stellate cells retain retinoid-laden lipid droplets after cellular transdifferentiation into activated myofibroblasts.

Loss of retinyl ester (RE)-rich lipid droplets (LDs) from hepatic stellate cells (HSCs) is cited as a key event in their cellular transdifferentiation to activated, pro-fibrotic myofibroblasts; however, it remains unclear if changes in LD morphology or RE content are causal for transdifferentiation. To better understand LD dynamics in vitro within a common model of HSC activation, we used novel approaches preserving LD morphology and allowing for quantitation of RE. The size and quantity of LDs within in vitro and in vivo bile duct ligation (BDL)-activated HSCs were quantitated using adipocyte differentiation-related protein (ADRP) labeling and oil red o (ORO) staining (gold standard), and RE content was determined using fluorescence microscopy. We found during HSC activation in vitro that LD number differed significantly when measured by ADRP and ORO, respectively ( day 1: 56 vs. 5, P = 0.03; day 4: 101 vs. 39, P = 0.03; day 14: 241 vs. 12, P = 0.02). Ex vivo HSCs activated in vivo contained the same number of LDs as day 4 in vitro activated HSCs (118 vs. 101, P = 0.54). Decline in LD RE occurred beyond day 4 in vitro and day 1 ex vivo , after HSC transdifferentiation was underway. Lastly, in situ HSCs examined using electron microscopy show LDs tend to be smaller but are ultimately retained in BDL injured livers. Therefore, we conclude that during HSC transdifferentiation, LDs are not lost but are retained, decreasing in size. Additionally, RE content declines after transdifferentiation is underway. These data suggest that these LD changes are not causal for HSC transdifferentiation. NEW & NOTEWORTHY Loss of retinoid-laden lipid droplets from hepatic stellate cells has long been held as a hallmark of their transdifferentiation into activated myofibroblasts, the dominant cells that drive hepatic fibrosis. This study demonstrates that stellate cells activated in culture and after liver injury in vivo retain their lipid droplets and that these droplets become smaller and more numerous, with decreases in droplet retinoid concentration occurring only after cellular transdifferentiation is underway.

Interphotoreceptor retinoid binding protein removes all-trans retinol and retinal from rod outer segments preventing lipofuscin precursor formation

Interphotoreceptor retinoid–binding protein (IRBP) is a specialized lipophilic carrier that binds the all-trans and 11-cis isomers of retinal and retinol, and this facilitates their transport between photoreceptors and cells in the retina. One of these retinoids, all-trans-retinal, is released in the rod outer segment by photoactivated rhodopsin after light excitation. Following its release, all-trans-retinal is reduced by the retinol dehydrogenase RDH8 to all-trans-retinol in an NADPH-dependent reaction. However, all-trans-retinal can also react with outer segment components, sometimes forming lipofuscin precursors, which after conversion to lipofuscin accumulate in the lysosomes of the retinal pigment epithelium and display cytotoxic effects. Here, we have imaged the fluorescence of all-trans-retinol, all-trans-retinal, and lipofuscin precursors in real time in single isolated mouse rod photoreceptors. We found that IRBP removes all-trans-retinol from individual rod photoreceptors in a concentration-dependent manner. The rate constant for retinol removal increased linearly with IRBP concentration with a slope of 0.012 min−1 μm−1. IRBP also removed all-trans-retinal, but with much less efficacy, indicating that the reduction of retinal to retinol promotes faster clearance of the photoisomerized rhodopsin chromophore. The presence of physiological IRBP concentrations in the extracellular medium resulted in lower levels of all-trans-retinal and retinol in rod outer segments following light exposure. It also prevented light-induced lipofuscin precursor formation, but it did not remove precursors that were already present. These findings reveal an important and previously unappreciated role of IRBP in protecting the photoreceptor cells against the cytotoxic effects of accumulated all-trans-retinal.

All-trans retinal levels and formation of lipofuscin precursors after bleaching in rod photoreceptors from wild type and Abca4-/- mice

Abstract The accumulation of lipofuscin in the cells of the retinal pigment epithelium (RPE) is thought to play an important role in the development and progression of degenerative diseases of the retina. The bulk of RPE lipofuscin originates in reactions of the rhodopsin chromophore, retinal, with components of the photoreceptor outer segment. The 11‐cis retinal isomer is generated in the RPE and supplied to rod photoreceptor outer segments where it is incorporated as the chromophore of rhodopsin. It is photoisomerized during light detection to all‐trans and subsequently released by photoactivated rhodopsin as all‐trans retinal, which is removed through reduction to all‐trans retinol in a reaction requiring metabolic input in the form of NADPH. Both 11‐cis and all‐trans retinal can form lipofuscin precursor fluorophores in rod photoreceptor outer segments. Increased accumulation of lipofuscin has been suggested to result from excess formation of lipofuscin precursors due to buildup of all‐trans retinal released by light exposure. In connection with this suggestion, the Abca4 transporter protein, an outer segment protein defects in which result in recessive Stargardt disease, has been proposed to promote the removal of all‐trans retinal by facilitating its availability for reduction. To examine this possibility, we have measured the outer segment levels of all‐trans retinal, all‐trans retinol, and of lipofuscin precursors after bleaching by imaging the fluorescence of single rod photoreceptors isolated from wild type and Abca4‐/‐ mice. We found that all‐trans retinol and all‐trans retinal levels increased after bleaching in both wild type and Abca4‐/‐ rods. At all times after bleaching, there was no significant difference in all‐trans retinal levels between the two strains. All‐trans retinol levels were not significantly different between the two strains at early times, but were lower in Abca4‐/‐ rods at times longer than 20 min after bleaching. Bleaching in the presence of lower metabolic substrate concentrations resulted in higher all‐trans retinal levels and increased formation of lipofuscin precursors in both wild type and Abca4‐/‐ rods. The results show that conditions that result in buildup of all‐trans retinal levels result in increased generation of lipofuscin precursors in both wild type and Abca4‐/‐ rods. The results are consistent with the proposal that Abca4 facilitates the reduction of all‐trans retinal to retinol; absence of Abca4 however does not appear to be associated with higher all‐trans retinal levels compared to wild type. HighlightsFluorescence imaging of retinal, retinol, and lipofuscin precursors in single rods.Accumulation of light‐generated free all‐trans retinal is unaffected by lack of Abca4.Metabolic limitations result in all‐trans retinal accumulation.Metabolic limitations lead to increased formation of lipofuscin precursors.