BACKGROUND: The glial proliferation after macular hole (MH) surgery was divided into two types previously: those replacing the entire intraretinal layer and those involving only the inner foveal layers. The evolution and prognosis of the former type were elaborated on in previous studies, but the latter one has received limited attention. Therefore, this study aims to investigate the evolution of glial proliferation with varying grades after MH surgery and its effects on foveal microstructure and best-corrected visual acuity (BCVA).
METHODS: In this retrospective research, we reviewed 202 eyes from 196 consecutive patients who underwent a successful idiopathic MHs repair. Based on optical coherence tomography images, glial proliferation was classified into three types: A-type, which replaced the entire intraretinal layer; B-type, located at the level of and above the external limiting membrane (ELM); and C-type, situated above the ELM.
RESULTS: Of the 67 eyes that attended the 1-, 4-, and 10-month follow-up, A-type, B-type, C-type, and no glial proliferation were identified in 27 (40.3%), 17 (25.4%), 20 (29.8%), and 3 eyes (4.5%), respectively, at 1 month. Within 10 months, the prevalence of A-type glial proliferation significantly decreased (p < 0.001), but the changes in B-type (p = 0.261), C-type (p = 0.151), and no glial proliferation (p = 0.492) were not significant. In 32 of the 67 eyes, the grade of glial proliferation gradually improved, with A-type transforming into B- or C-type in 19 of 27 eyes (70.4%), B-type into C-type or no glial proliferation in 11 out of 17 eyes (64.7%), and C-type gradually disappearing in 2 out of 20 eyes (10.0%). Among the eyes that attended at least one follow-up (1 M, 202 eyes; 4 M, 161 eyes; 10 M, 97 eyes), those with A-type glial proliferation showed the most defective outer retinal layers, worst BCVA, and thinnest central fovea compared with the other two types at all follow-up time points (p < 0.001). Eyes with C-type glial proliferation exhibited significantly better photoreceptor layer status and BCVA compared with those with B-type glial proliferation. A-type glial proliferation at 1 month, which showed significant association with BCVA at 10 months, could be accurately predicted by the minimum linear diameter with a cut-off >547.5 μm (p < 0.001).
CONCLUSIONS: Within 10 months, A-type glial proliferation substantially resolves but the prevalence of B- and C-type remains unchanged. B-type glial proliferation hinders the restoration of photoreceptors and impairs visual recovery despite being located within the inner retina.

Photoactivated adenylate cyclases (PACs) are multidomain BLUF proteins that regulate the cellular levels of cAMP in a light-dependent manner. The signaling route and dynamics of PAC from Oscillatoria acuminata (OaPAC), which consists of a light sensor BLUF domain, an adenylate cyclase domain, and a connector helix (α3-helix), were studied by detecting conformational changes in the protein moiety. Although circular dichroism and small-angle X-ray scattering measurements did not show significant changes upon light illumination, the transient grating method successfully detected light-induced changes in the diffusion coefficient (diffusion-sensitive conformational change (DSCC)) of full-length OaPAC and the BLUF domain with the α3-helix. DSCC of full-length OaPAC was observed only when both protomers in a dimer were photoconverted. This light intensity dependence suggests that OaPAC is a cyclase with a nonlinear light intensity response. The enzymatic activity indeed nonlinearly depends on light intensity, that is, OaPAC is activated under strong light conditions. It was also found that both DSCC and enzymatic activity were suppressed by a mutation in the W90 residue, indicating the importance of the highly conserved Trp in many BLUF domains for the function. Based on these findings, a reaction scheme was proposed together with the reaction dynamics.

Abnormal dislocation of cone opsin protein affects the sensitivity function of photoreceptors and results in depressed central vision. Nutraceutical therapy is needed to restore the residual function of photoreceptors. Crocin is a natural substance for retinal health. However, its effect on the restoration of functional vision and its underlying mechanisms have not been fully studied. This study analyzed the restorative effect of crocin on residual functional vision in vivo in a mouse model. High-energy light-evoked photoreceptor dysfunction was confirmed by M opsin dislocation in the retina accompanied by a loss of functional vision. Crocin treatment significantly increased brain-derived neurotrophic factor (BDNF) protein in retinas, thus contributing to the re-localization of the M opsin protein, restoration of the visual acuity (VA), and high spatial frequency-characterized visual contrast sensitivity function (VCSF). In contrast, such effects were significantly reversed after the washout period. Additionally, the restorative effect of crocin on functional vision and M opsin re-localization can be reversed and blocked by synchronous injection of a tropomyosin receptor kinase B (TrkB) receptor antagonist (ANA-12). This study demonstrated the major functional vision-rescuing or restoring effect of crocin in vivo by modulating M opsin location plasticity and increasing the capacity of the residual photoreceptor function through the BDNF-TrkB receptor pathway.

The light environments of natural water sources have specific characteristics. For the majority of aquatic organisms, vision is crucial for predation, hiding from predators, communicating information, and reproduction. Electroretinography (ERG) is a diagnostic method used for assessing visual function. An electroretinogram records the comprehensive potential response of retinal cells under light stimuli and divides it into several components. Unique wave components are derived from different retinal cells, thus retinal function can be determined by analyzing these components. This review provides an overview of the milestones of ERG technology, describing how ERG is used to study visual sensitivity (e.g., spectral sensitivity, luminous sensitivity, and temporal resolution) of fish, crustaceans, mollusks, and other aquatic organisms (seals, sea lions, sea turtles, horseshoe crabs, and jellyfish). In addition, it describes the correlations between visual sensitivity and habitat, the variation of visual sensitivity as a function of individual growth, and the diel cycle changes of visual sensitivity. Efforts to identify the visual sensitivity of different aquatic organisms are vital to understanding the environmental plasticity of biological evolution and for directing aquaculture, marine fishery, and ecosystem management.

Animal models are the silent scouts that help to understand the complex biological processes and gather data that aid our understanding of how organisms function. Various animal models are being sacrificed to assess the impact of toxic chemicals. Mortality calculations should be minimized and much data should be collected on the basis of clinical signs that can contribute to identifying robust humane endpoints linked to mortality. This study was designed to calculate the lowest possible dose of PbAc (lead acetate), a neurotoxicant, that can have a toxicological impact on the zebrafish retina and to minimize animal usage. Dose and time-dependent changes were observed in the zebrafish retina following PbAc exposure with zero mortality. Vision and visual behavior response are the foremost indicators that can be recorded to mark the risk assessment of any chemical. Therefore, the present study aims at dose and time response to find the lowest dose of PbAc affecting the zebrafish retina and its visual behavior. Zebrafish were treated for 3 weeks with four concentrations of 0.04, 0.06, 0.08, and 0.1 mg/L of PbAc for a dose-response study. Then for the time response study, two doses 0.08 and 0.1 mg/L were selected and zebrafish were exposed to those concentrations for 2 and 4 weeks. The results of qualitative and quantitative analyses of retinal histology showed that 15 days of treatment with 0.08mg/L concentration can cause appropriate damage to the photoreceptor layer. At the ultrastructural level, it was further observed that PbAc induces damage to the photoreceptors, especially the rod cells. Escape response behavior showed a significant decrease in visual response to changing contrasts in an increasing dose-dependent manner.

OBJECTIVE: To explore whether the retinal neovascularization (NV) in a genetic mutant mice model could be ameliorated in an inherited retinitis pigmentosa (RP) mouse, which would help to elucidate the possible mechanism and prevention of retinal NV diseases in clinic.
METHODS: The Vldlr -/- mice, the genetic mutant mouse model of retinal NV caused by the homozygous mutation of Vldlr gene, with the rd1 mice, the inherited RP mouse caused by homozygous mutation of Pde6b gene were bred. Intercrossing of the above two mice led to the birth of the F1 hybrids, further inbreeding of which gave birth to the F2 offspring. The ocular genotypes and phenotypes of the mice from all generations were examined, with the F2 offspring grouped according to the genotypes.
RESULTS: The rd1 mice exhibited the RP phenotype of outer retinal degeneration and loss of retinal function. The Vldlr -/- mice exhibited the phenotype of retinal NV obviously shown by the fundus fluorescein angiography. The F1 hydrides, with the heterozygote genotype, exhibited no phenotypes of RP or retinal NV. The F2 offspring with homozygous genotypes were grouped into four subgroups. They were the F2-I mice with the wild-type Pde6b and Vldlr genes (Pde6b+/+ -Vldlr+/+ ), which had normal ocular phenotypes; the F2-II mice with homozygous mutant Vldlr gene (Pde6b+/+ -Vldlr-/- ), which exhibited the retinal NV phenotype; the F2-III mice with homozygous mutant Pde6b gene (Pde6b-/- -Vldlr+/+ ), which exhibited the RP phenotype. Specifically, the F2-IV mice with homozygous mutant Vldlr and Pde6b gene (Pde6b-/- -Vldlr-/- ) showed only the RP phenotype, without the signs of retinal NV.
CONCLUSIONS: The retinal NV can be inhibited by the RP phenotype, which implies the role of a hyperoxic state in treating retinal NV diseases.

The neuroretina is protected by its own defense system, that is microglia and the complement system. Under normal physiological conditions, microglial activation is tightly regulated by the neurons although the underlying mechanism remains elusive. Using published single-cell RNA sequencing data sets, we found that immune regulatory molecules including CD200, CD47, CX3CL1, TGFβ, and complement inhibitor CD59a are expressed by various retinal neurons. Importantly, we found that photoreceptors express higher levels of CD47 and CD59a, which was further confirmed in cultured 661W cells, WERI-Rb1 cells, and microdissected photoreceptors from human eyes. The expression of CD59a mRNA in 661W cells was upregulated by TNFα and hypoxia, whereas LPS, hypoxia, and IL-4 upregulated CD47 mRNA expression in 661W cells. Immunofluorescence staining detected strong CD59a immunoreactivity in the outer nuclear layer, inner/outer segments, and discrete staining in ganglion cell layer (GCL), inner plexiform layer (IPL), and outer plexiform layer. The expression of CD59a in photoreceptors was increased in the detached retina, but decreased in retinas from experimental autoimmune uveoretinitis (EAU) mice. In EAU retina, CD59a was highly expressed by active immune cells. CD47 was detected in GCL, IPL, and inner nuclear layer and some photoreceptors. The expression of CD47 in photoreceptors was also increased in the detached retina but decreased in EAU retina. In a coculture system, 661W enhanced arginase-1 and reduced IL-6 mRNA expression in BV2 microglial cells. Our results suggest that photoreceptors express immune regulatory molecules and may have the potential to regulate immune activation in the outer retina/subretinal space under pathophysiological conditions.

Gap junction-mediated electrical coupling between retinal photoreceptors is an important determinant of photoreceptor function. Yet, quantitative measurements of the junctional conductance between coupled photoreceptors are required to fully assess the effects of coupling on visual performance. Such measurements have been obtained in salamander and other lower vertebrate retinas but are difficult to acquire in mammalian retinas, in part because of the much smaller size of photoreceptors in mammals. Here, we describe in detail a dual whole-cell patch-clamp technique we recently developed to measure the junctional conductance between photoreceptor pairs in the mouse retina. With this method, electrical coupling strength between mouse photoreceptors can be estimated with high accuracy and its impact on retinal processing of visual information further evaluated.

UNASSIGNED: To study photoreceptor changes after a successful macular hole surgery using adaptive optics.
UNASSIGNED: Three patients who underwent a successful macular hole surgery were studied. Cone density, spacing, and number of nearest neighbors were analyzed at 2° and 4° of eccentricity in all four quadrants using adaptive optics.
UNASSIGNED: All three patients gained a visual acuity better than logMAR 0.477 (Snellen equivalent 6/18) at 6 months following successful macular hole surgery. Following successful closure of the macular hole, photoreceptors were appreciated at 2° and 4° of eccentricity from the center. However, as compared with the fellow normal eye, cell density was reduced significantly in the inferior (12,929.33 ± 2047.50 versus 23,839.67 ± 3711.16 cells/mm2 at 2°) and temporal quadrant (13,890 ± 3424.26 versus 22,578.67 ± 5651.34 cells/mm2 at 2°), and intercell spacing was increased significantly in inferior (9.6 ± 0.92 versus 7.14 ± 0.545 µm) and nasal quadrant (8.83 ± 0.39 versus 7.49 ± 0.42 µm). Number of nearest neighbors was unaffected after the hole closure.
UNASSIGNED: Postoperative recovery of vision after successful closure of the hole occurs because of the migration or shifting of cells from parafoveal retina toward the center. Cells nearest to the hole margin (at 2° eccentricity) appear to shift more as compared with cells which are further away.

The choanoflagellate Salpingoeca rosetta contains a chimeric rhodopsin protein composed of an N-terminal rhodopsin (Rh) domain and a C-terminal cyclic nucleotide phosphodiesterase (PDE) domain. The Rh-PDE enzyme light-dependently decreases the concentrations of cyclic nucleotides such as cGMP and cAMP. Photoexcitation of purified full-length Rh-PDE yields an \"M\" intermediate with a deprotonated Schiff base, and its recovery is much faster than that of the enzyme domain. To gain structural and mechanistic insights into the Rh domain, here we expressed and purified the transmembrane domain of Rh-PDE, Rh-PDE(TMD), and analyzed it with transient absorption, light-induced difference UV-visible, and FTIR spectroscopy methods. These analyses revealed that the \"K\" intermediate forms within 0.005 ms and converts into the M intermediate with a time constant of 4 ms, with the latter returning to the original state within 4 s. FTIR spectroscopy revealed that all-trans to 13-cis photoisomerization occurs as the primary event during which chromophore distortion is located at the middle of the polyene chain, allowing the Schiff base to form a stronger hydrogen bond. We also noted that the peptide backbone of the α-helix becomes deformed upon M intermediate formation. Results from site-directed mutagenesis suggested that Glu-164 is protonated and that Asp-292 acts as the only Schiff base counterion in Rh-PDE. A strong reduction of enzymatic activity in a D292N variant, but not in an E164Q variant, indicated an important catalytic role of the negative charge at Asp-292. Our findings provide further mechanistic insights into rhodopsin-mediated, light-dependent regulation of second-messenger levels in eukaryotic microbes.