Nuclear and plasma membrane localization of SH3BP4 in retinal pigment epithelial cells.

PURPOSE: The SH3BP4 protein contains domains belonging to the Eps15-Homology (EH) network family of endocytosis proteins and a C-terminal death domain. The purpose of this study was to determine the expression of SH3BP4 in ARPE-19, Y79 and COS-7 cell lines and to determine SH3BP4 subcellular localization within ARPE-19 cells. METHODS: A chicken anti-human SH3BP4 antibody was generated that specifically immunostains SH3BP4 fusion proteins and a corresponding endogenous protein band at 120 kDa. Protein expression of SH3BP4 was determined using western analysis of multiple cell lines and dissected retinal tissue. Intracellular localization of both endogenous SH3BP4 and SH3BP4 fusion proteins were determined using subcellular fractionation and microscopy studies using ARPE-19 and COS-7 cells. RESULTS: The retinal pigment epithelial (RPE) cell line ARPE-19 was found to express SH3BP4 protein at more than 7 fold the levels in Y79 retinoblastoma cells and more than 2.5 fold the levels in COS-7 cells. Both the RPE and neural retinal layers of the eye were also found to express the SH3BP4 protein. SH3BP4 endogenous and fusion proteins were found to localize to both membrane and nuclear fractions but not the cytosol in subcellular fractionation experiments. Subsequent microscopy analyses show that SH3BP4 fusion proteins localize to the plasma membrane and the nuclear periphery. CONCLUSIONS: These studies show that SH3BP4 is expressed in the RPE and neural retina in vivo, and in ARPE-19, Y79, and COS-7 cell lines. Compared to other EH network and death domain proteins, SH3BP4 fusion proteins have an unusual intracellular localization to the plasma membrane and the nuclear periphery. The present demonstration of the suborganelle localization in conjunction with the unique domain combinations belonging to both endocytosis and cell death pathways suggests that SH3BP4 has physiological significance for RPE cells.

Evidence for apoptosis correlated with mortality in the giant black tiger shrimp Penaeus monodon infected with yellow head virus.

Histological, cytochemical and ultrastructural changes in giant black tiger shrimp Penaeus monodon were investigated at various time intervals after injection with yellow head virus (YHV). Hemocytes, lymphoid organs (LO) and gills were the main focus of the study. After injection with YHV, onset of mortality varied from 36 h onward. By normal hematoxylin and eosin staining, the 3 tissues showed clear and increasing prevalence of nuclear condensation, pyknosis and karyorrhexis from approximately 36 h post-injection (p.i.) until death, although pathology was evident in the LO as early as 12 h p.i. in some shrimp. By nuclear DNA staining with 4',6-diamidino-2-phenylindole (DAPI) and by specific labeling of 3'-OH ends of nuclear DNA using a technique called terminal deoxynucleotidyl transferase-mediated deoxy-UTP nick-end labeling (TUNEL), cells of the 3 tissues showed evidence of chromatin condensation and DNA fragmentation, respectively. Both are generally considered to be characteristic of apoptosis. In addition to TUNEL labeling, evidence for DNA fragmentation was supported by the appearance of approximately 200 base pair DNA ladders at approximately 48 h p.i. in hemocytes of YHV-infected but not uninfected shrimp. Transmission electron microscopy (TEM) of LO tissue revealed features of apoptosis in tissues of YHV-infected shrimp only. These included marginated, condensed and fragmented chromatin without concurrent cytoplasmic damage. Histological, cytochemical, ultrastructural and biochemical data were consistent with the hypothesis that widespread and progressive apoptosis occurred in susceptible shrimp infected with YHV. Although no specific tests were carried out to determine whether this purported apoptosis was the cause of mortality, moribund shrimp had extensive deterioration of vital tissues such as the hemolymph, gills, heart and LO, suggesting that many essential bodily functions had been severely compromised. This probably resulted in the gross signs of lethargy and weakness seen, and it is reasonable to suggest that further, progressive deterioration could have led to the collapse of vital functions followed by death.

Time-course and levels of apoptosis in various tissues of black tiger shrimp Penaeus monodon infected with white-spot syndrome virus.

This study focused on apoptosis in various tissues of the black tiger shrimp Penaeus monodon following white spot syndrome virus (WSSV) injection. The study included: (1) light microscopy (LM) and transmission electron microscopy (TEM) of various tissues; (2) fluorescent LM of nuclear DNA by staining with 4, 6-diamidine-2-phenyl indole dihydrochloride (DAPI) and TdT-mediated dUTP nick-end labelling (TUNEL) techniques; and (3) determination of caspase-3 activity. Juvenile P. monodon were injected with WSSV, and several tissues of ectodermal and mesodermal origin were studied at different intervals after injection. The total haemocyte count had decreased to one-tenth of its original level 60 h after WSSV injection. By LM, extensive destruction by WSSV was observed in the stomach epithelium, gills, hematopoietic tissue, hemocytes and the heart, but the most severely affected tissue was the subcuticular epithelium. TEM revealed that at 6 h post-injection (p.i.) the chromatin of infected nuclei was marginated, and by 24 h p.i. the nuclei were filled with enveloped and non-enveloped WSSV virions. At later stages of the infection, the nucleus extruded WSSV particles. Chromatin margination and nuclear condensation and fragmentation (i.e. signs of apoptosis) were observed as early as 6 h p.i. in all affected tissues, but occurred in cells without WSSV virions rather than in cells with virions. The occurrence of apoptosis was supported by data obtained using TUNEL and by DAPI-staining and progressed from 6 to 60 h p.i. In addition, caspase-3 activity in WSSV-infected shrimp was about 6-fold higher than that in uninfected shrimp. The data strongly suggests that apoptosis occurs following WSSV infection in P. monodon, but the extent to which it contributes to shrimp mortality requires further investigation.

Diarylheptanoid 7-(3,4 dihydroxyphenyl)-5-hydroxy-1-phenyl-(1E)-1-heptene from Curcuma comosa Roxb. protects retinal pigment epithelial cells against oxidative stress-induced cell death.

Chronic exposure to oxidative stress causes damage to retinal pigment epithelial cells which may lead to the development of age-related macular degeneration, the major cause of vision loss in humans. Anti-oxidants provide a natural defense against retinal cell damage. The present study was designed to evaluate the potential anti-oxidant activity and protective effect of two diarylheptanoids isolated from a medicinal herb Curcuma comosa; 7-(3,4 dihydroxyphenyl)-5-hydroxy-1-phenyl-(1E)-1-heptene (compound A), and 1,7-diphenyl-4(E),6(E)-heptadien-3-ol (compound B) against oxidative stress (H(2)O(2))-induced human retinal pigment epithelial (APRE-19) cell death. The 2,2-diphenyl-1-picrylhydrazyl (DPPH) assay indicated that the anti-oxidant activity (IC(50)) of compound A was similar to that of vitamin C. Pre-treatment of ARPE-19 cells with 20 µM compound A for 4h afforded greater protection against the insult from 500 µM H(2)O(2), compared to a similar protection period for compound B. Compound A lowered H(2)O(2)-induced lipid peroxidation, malondialdehyde formation and intracellular reactive oxygen species. Furthermore, compound A ameliorated the H(2)O(2)-induced decrease in anti-oxidant enzyme activities and subsequent apoptotic cell death in ARPE-19 cells in a dose and time-dependent manner. These results suggest that compound A protects ARPE-19 cells against oxidative stress, in part, by enhancing several anti-oxidant defense mechanisms. Therefore, compound A may have therapeutic potential for diseases associated with oxidative stress, particularly degenerative retinal diseases.

Harmonin (Ush1c) is required in zebrafish Müller glial cells for photoreceptor synaptic development and function.

Usher syndrome is the most prevalent cause of hereditary deaf-blindness, characterized by congenital sensorineural hearing impairment and progressive photoreceptor degeneration beginning in childhood or adolescence. Diagnosis and management of this disease are complex, and the molecular changes underlying sensory cell impairment remain poorly understood. Here we characterize two zebrafish models for a severe form of Usher syndrome, Usher syndrome type 1C (USH1C): one model is a mutant with a newly identified ush1c nonsense mutation, and the other is a morpholino knockdown of ush1c. Both have defects in hearing, balance and visual function from the first week of life. Histological analyses reveal specific defects in sensory cell structure that are consistent with these behavioral phenotypes and could implicate Müller glia in the retinal pathology of Usher syndrome. This study shows that visual defects associated with loss of ush1c function in zebrafish can be detected from the onset of vision, and thus could be applicable to early diagnosis for USH1C patients.

Function of MYO7A in the human RPE and the validity of shaker1 mice as a model for Usher syndrome 1B.

PURPOSE: To investigate the function of MYO7A in human RPE cells and to test the validity of using shaker1 RPE in preclinical studies on therapies for Usher syndrome 1B by comparing human and mouse cells. METHODS: MYO7A was localized by immunofluorescence. Primary cultures of human and mouse RPE cells were used to measure melanosome motility and rod outer segment (ROS) phagocytosis and digestion. MYO7A was knocked down in the human RPE cells by RNAi to test for a mutant phenotype in melanosome motility. RESULTS: The distribution of MYO7A in the RPE of human and mouse was found to be comparable, both in vivo and in primary cultures. Primary cultures of human RPE cells phagocytosed and digested ROSs with kinetics comparable to that of primary cultures of mouse RPE cells. Melanosome motility was also comparable, and, after RNAi knockdown, consisted of longer-range fast movements characteristic of melanosomes in shaker1 RPE. CONCLUSIONS: The localization and function of MYO7A in human RPE cells is comparable to that in mouse RPE cells. Although shaker1 retinas do not undergo degeneration, correction of mutant phenotypes in the shaker1 RPE represents a valid preclinical test for potential therapeutic treatments.

Dysfunction of heterotrimeric kinesin-2 in rod photoreceptor cells and the role of opsin mislocalization in rapid cell death.

Due to extensive elaboration of the photoreceptor cilium to form the outer segment, axonemal transport (IFT) in photoreceptors is extraordinarily busy, and retinal degeneration is a component of many ciliopathies. Functional loss of heterotrimeric kinesin-2, a major anterograde IFT motor, causes mislocalized opsin, followed by rapid cell death. Here, we have analyzed the nature of protein mislocalization and the requirements for the death of kinesin-2-mutant rod photoreceptors. Quantitative immuno EM showed that opsin accumulates initially within the inner segment, and then in the plasma membrane. The light-activated movement of arrestin to the outer segment is also impaired, but this defect likely results secondarily from binding to mislocalized opsin. Unlike some other retinal degenerations, neither opsin-arrestin complexes nor photoactivation were necessary for cell loss. In contrast, reduced rod opsin expression provided enhanced rod and cone photoreceptor survival and function, as measured by photoreceptor cell counts, apoptosis assays, and ERG analysis. The cell death incurred by loss of kinesin-2 function was almost completely negated by Rho⁻/⁻. Our results indicate that mislocalization of opsin is a major cause of photoreceptor cell death from kinesin-2 dysfunction and demonstrate the importance of accumulating mislocalized protein per se, rather than specific signaling properties of opsin, stemming from photoactivation or arrestin binding.