Glucose metabolism in mammalian photoreceptor inner and outer segments

Narayan, Daniel S.; Chidlow, Glyn; Wood, J. K.; Casson, Robert J.

doi:10.1111/ceo.12952

Cited by 74 publications

(74 citation statements)

References 112 publications

(155 reference statements)

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“…While our experiments did not identify the mechanisms by which light-evoked photoreceptor responses are increased in the presence of additional glucose, likely targets include energy dependent processes in photoreceptors such as Na + /K + ATPases, Na + /Ca 2+ /K + exchangers and Ca 2+ ATPases (42), ATP-sensitive K + channels expressed in photoreceptors (43) or other ATP-dependent processes. The main glucose transporters expressed in photoreceptors are the insulin-independent GLUT-1 and insulin-dependent GLUT-4 (42), which have previously been reported to be reduced in diabetes (31; 44; 45), thus potentially explaining the inability of the photoreceptors in db/db mice to utilize increased glucose concentrations to promote their light responses. However, these findings are not universal and increased expression of GLUT-1 in diabetes has also been reported (39).…”

Section: Discussionmentioning

confidence: 86%

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Rod phototransduction and light signal transmission during type 2 diabetes

Becker

Vinberg

2020

Preprint

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Diabetic retinopathy is a major complication of diabetes recently associated with attenuated photoreceptor function. Multiple stressors in diabetes, such as hyperglycemia, oxidative stress and inflammatory factors, have been identified, but systemic effects of diabetes on outer retina function are incompletely understood. Ex vivo ERG presents the unique opportunity to test rod photoreceptor light signal transduction and transmission and determine whether they are permanently compromised and/or adapt to hyperglycemia in chronic type 2 diabetes. Lightevoked rod photoreceptor signals in control and diabetic mice in vivo were compared to those recorded ex vivo under normal or elevated extracellular glucose. Transduction and transmission of light signals were compromised in 6 mo. diabetic mice in vivo. In contrast, ex vivo rod signaling was similar in isolated retinas from 6 mo. control and diabetic mice under normoglycemic conditions. Acutely elevated glucose ex vivo increased light-evoked photoreceptor responses in control mice, but did not affect light responses in diabetic mice. In summary, our data suggest that long-term diabetes does not irreversibly change the ability of rod photoreceptors to transduce and mediate light signals. However, type 2 diabetes appears to induce adaptational changes in the rods that render them less sensitive to increased availability of glucose.Diabetic retinopathy, one of the leading causes of irreversible vision loss worldwide (1), has traditionally been characterized by retinal vascular abnormalities. Recent studies in human patients with diabetes suggest, however, that retinal diabetic neuropathy with neuroglial dysfunction and degeneration frequently precedes visible microvasculopathy (2-4). Even in the absence of or with minimal signs of retinal vascular abnormalities, patients with diabetes show dysfunction and loss of retinal neuronal cells. In fact, impairment of the neurovascular unit has been suggested to lead to or accelerate retinal vascular disease progression, since implicit time delay of the multifocal electroretinogram (ERG) predicts onset of visible vascular changes (5). Damage to nerve fiber, ganglion cell and inner plexiform layers in the human eye has been demonstrated in diabetes by impaired pattern ERG and oscillatory potentials (6) and thinning of inner retinal layers (4). Reduced amplitudes and longer implicit times of the scotopic and photopic b-waves (6) also implicate dysfunction of rod and cone bipolar cells in retinal diabetic neuropathy of human patients. These findings are not universal, however, and reduced scotopic a-and b-wave amplitudes have not been shown in all studies (7). Murine models of diabetes share many features of retinal dysfunction and cell loss with those in patients with diabetes. The positive component of the scotopic threshold response, as a measure of retinal ganglion cell function, is attenuated (8) and nerve fiber and ganglion cell layer thickness and retinal ganglion cell density are reduced (4) in streptozotocin (STZ)-induced di...

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Section: Discussionmentioning

confidence: 86%

“…While photoreceptors are highly metabolically active and mostly depend on glucose as their source of energy (42), effects of acute hyperglycemia on retinal function remain unclear. Studies in patients with diabetes and diabetic animal models suggest a correlation between bipolar cell function and blood glucose levels.…”

Section: Discussionmentioning

confidence: 99%

Rod phototransduction and light signal transmission during type 2 diabetes

Becker

Vinberg

2020

Preprint

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“…A similarly interesting finding was that the CFPD was ~30% lesser than TPFD in all species. Cone photoreceptors require more energy than rods . As the pecten appears to be associated with providing nourishment and oxygen supply to the retina and as the vitreous allows relatively molecular mobility, it is possible that the closer proximity of the central fovea to the pecten is beneficial due to the higher energy needs of the central fovea .…”

Section: Discussionmentioning

confidence: 99%

“…Cone photoreceptors require more energy than rods. 55 As the pecten appears to be associated with providing nourishment and oxygen supply to the retina and as the vitreous allows relatively molecular mobility, it is possible that the closer proximity of the central fovea to the pecten is beneficial due to the higher energy needs of the central fovea. 56 Photoreceptors and retinal pigment epithelium (RPE) are responsible for phototransduction, which require a large amount of energy; therefore, it would not be surprising if the central fovea had higher energetic requirements given its functionality and metabolic requirements.…”

Section: Discussionmentioning

confidence: 99%

Spectral‐domain optical coherence tomography imaging of normal foveae: A pilot study in 17 diurnal birds of prey

Gomes

Abou‐Madi

Ledbetter

et al. 2020

Veterinary Ophthalmology

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Objective To describe and to establish normative data for the foveae of diurnal birds of prey using spectral‐domain optical coherence tomography (SD‐OCT). Methods All animals (9 red‐tailed hawks, 3 Cooper's hawks, 3 American kestrels, 1 sharp‐shinned hawk, and 1 broad‐winged hawk) had an ophthalmic examination performed with slit lamp biomicroscopy and indirect ophthalmoscopy. Following ophthalmic examination, SD‐OCT was performed in each eye that had a visible fundus and normal fovea on SD‐OCT. Temporal foveae depth, central foveae depth, pecten‐temporal foveae distance, and pecten‐central foveae distance (PCFD) were measured using SD‐OCT. Differences in measured outcomes between species were determined using generalized linear mixed effects models. Results The central foveae (mean ± SD) displayed a small but significant depth variation between species (P = .002) and was deepest in red‐tailed hawks (293 ± 16 µm), followed by American kestrels (260 ± 12 µm), broad‐winged hawks (256 ± 16 µm), Cooper's hawks (250 ± 9 µm), and sharp‐shinned hawks (239 ± 16 µm). The temporal foveae were shallower than the central foveae in all species tested, and there was a significant variation between species (P < .001). The temporal foveae (mean ± SD) were deepest in American kestrels (137 ± 8 µm), followed by red‐tailed hawks (129 ± 3 µm), broad‐winged hawks (59.5 ± 3.5 µm), Cooper's hawks (20.3 ± 6.4 µm), and sharp‐shinned hawks (17.5 ± 0.7 µm). Pecten‐temporal foveae distance was approximately 30% shorter than PCFD in all species. There were no differences in the parameters tested between the eyes within each species (P ≥ .47). Conclusion Normative foveae SD‐OCT data were obtained in four species of diurnal birds of prey. Further studies are warranted to provide structural and functional information regarding normal and pathologic changes that can affect the foveae.

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“…Indeed, photoreceptor function is highly susceptible to glycolytic inhibition (via sodium iodoacetate injection) and mature 'RP' rats lacking a majority of their photoreceptors display an ~50% reduction in glycolytic activity compared to normal rat retinas [16,17]. In addition to meeting the high energy demands of photoreceptors, glucose metabolism plays other non-energetic roles in the retina [18,19]. For example, glucose metabolism by the pentose phosphate pathway leads to the production of intracellular glutathione, which prevents neuronal cell death through redox inactivation of cytochrome c-mediated apoptosis pathways [20].…”

Section: Introductionmentioning

confidence: 99%

Metabolite therapy guided by liquid biopsy proteomics delays retinal neurodegeneration

Wert

Vélez

Vijayalakshmi

et al. 2019

Preprint

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One Sentence Summary: The study shows protein and metabolite pathways affected during neurodegeneration and that replenishing metabolites provides a neuroprotective effect on the retina. Abstract: 244Main Text: 9,039References: 83 AbstractNeurodegenerative diseases are debilitating, incurable disorders caused by progressive neuronal cell death.Retinitis pigmentosa (RP) is a blinding neurodegenerative disease that results in retinal photoreceptor cell death and progresses to the loss of the entire neural retinal network. We previously found that proteomic analysis of the adjacent vitreous serves as way to indirectly biopsy the neural retina and identify changes in the retinal proteome. We therefore analyzed protein expression in liquid vitreous biopsies from autosomal recessive retinitis pigmentosa (arRP) patients with PDE6A mutations and arRP mice with Pde6ɑ mutations. Proteomic analysis of retina and vitreous samples identified molecular pathways affected at the onset of photoreceptor cell death. Based on affected molecular pathways, arRP mice were treated with a ketogenic diet or metabolites involved in fatty-acid synthesis, oxidative phosphorylation, and the tricarboxylic acid (TCA) cycle. Dietary supplementation of a single metabolite, ɑ-ketoglutarate, increased docosahexaeonic acid (DHA) levels, provided neuroprotection, and enhanced visual function in arRP mice. A ketogenic diet delayed photoreceptor cell loss, while vitamin B supplementation had a limited effect. Finally, desorption electrospray ionization mass spectrometry imaging (DESI-MSI) revealed restoration of key metabolites that correlated with our proteomic findings: pyrimidine and purine metabolism (uridine, dihydrouridine, and thymidine), glutamine and glutamate (glutamine/glutamate conversion), and succinic and aconitic acid (TCA cycle). This study demonstrates that replenishing TCA cycle metabolites via oral supplementation prolongs vision and provides a neuroprotective effect on the photoreceptor cells and inner retinal network.

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Glucose metabolism in mammalian photoreceptor inner and outer segments

Cited by 74 publications

References 112 publications

Rod phototransduction and light signal transmission during type 2 diabetes

Rod phototransduction and light signal transmission during type 2 diabetes

Spectral‐domain optical coherence tomography imaging of normal foveae: A pilot study in 17 diurnal birds of prey

Metabolite therapy guided by liquid biopsy proteomics delays retinal neurodegeneration

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