Epigenetic modifications such as DNA methylation, histone post-translational modifications, non-coding RNA are reversible, heritable alterations which are induced by environmental stimuli. Major risk factors of diabetes and diabetic complications including hyperglycemia, oxidative stress and advanced glycation end products, can lead to abnormal epigenetic modifications in retinal vascular endothelial cells and retinal pigment epithelium cells. Epigenetic mechanisms are involved in the pathogenesis of macular edema and neovascularization of diabetic retinopathy (DR), as well as diabetic metabolic memory. The heritable nature of epigenetic marks also playsakey role in familial diabetes mellitus. Further elucidation of epigenetic mechanisms in DR can open the way for the discovery of novel therapeutic targets to prevent DR progression.
Objective To investigate the disease-causing gene of Stargardt disease. Method Fifteen patients with Stargardt disease were analyzed with 11 primers of the 11 exons of ABCR gene by using PCR-SSCP and DNA direct sequencing techniques. Results Three newly detected disease-causing mutations were found. Among those mutations, one is a frameshift mutation and others are single base transition. Conclusion This research confirmed that ABCR gene is associated with Stargardt disease, and 3 new mutations of ABCR gene were found. (Chin J Ocul Fundus Dis,2000,16:240-243)
X-linked retinoschisis (XLRS) is a rare X-linked inherited retinal disorder, caused by mutations in retinoschisin 1 (RS1) gene. Three XLRS mice were established, providing ideal systems to study the mechanism and treatment methods for XLRS. RS1 gene mutations can induce abnormal secretion or adhesion function of RS1 protein. In the past year, phase I clinical trials for XLRS has begun in USA, using adeno associated virus (AAV, AAV8 or AAV2)-mediated gene delivery. With the rapid development of new generation of AAV vector that can transduce more retinal cells through intravitreous delivery, gene therapy for XLRS will have a brighter future.
RNA can be labeled by more than 170 chemical modifications after transcription, and these chemical modifications are collectively referred to as RNA modifications. It opened a new chapter of epigenetic research and became a major research hotspot in recent years. RNA modification regulates the expression of genes from the transcriptome level by regulating the fate of RNA, thus participating in many biological processes and disease occurrence and development. With the deepening of research, the diversity and complexity of RNA modification, as well as its physiological significance and potential as a therapeutic target, can not be ignored.
ObjectiveTo reveal the pathogenic mutation in a three-generation Chinese family with autosomal dominant familial exudative vitreoretinopathy (FEVR). MethodsThree patients and a healthy spouse from the index family with FEVR were recruited. The proband was a 5 years old boy. His mother and grandpa were presented with typical FEVR presentations, while his father with normal ocular fundus. DNA was extracted from peripheral blood samples taken from all four participants. All coding and exon-intron boundary regions of five targeted genes, including NDP, FZD4, LRP5, TSPAN12 and ZNF408 were amplified with polymerase chain reaction and sequenced using direct sequencing. In silico analyses were applied to determine the conservation of the mutation site, pathogenic effect and the potential protein crystal structural changes caused by the mutation. ResultsFZD4 c.478G > A, a susceptible mutation was found after four high frequency mutation sites which MAF values were higher than 0.001 was filtered among 5 single nucleotide variations detected in four participants, leading to the residue 160 changing from glutamate to lysine (p.E160K). Co-segregation analysis between genotypes and phenotypes revealed FZD4 p.E160K as the disease-causing mutation for this family. Conservational analysis suggested that this mutation site was highly conserved among all tested species. Functional analysis predicated that this mutation may be a damaging mutation. Crystal structural analysis also indicated that this mutation could lead to the elimination of the hydrogen bond between residue 160 and asparagine at residue 152, thus altering the tertiary structure of the protein and further impairing the protein function. ConclusionOur study demonstrates FZD4 p.E160K as a novel pathogenic mutation for FEVR.
Epigenetic mechanisms influence gene expression and function without modification of the base sequence of DNA and may generateagenetic phenotype. Epigenetic modifications include DNA methylation, histone modifications, and deployment of noncoding RNA. There is growing evidence that epigenetic mechanisms could playacrucial role in the development of diabetic retinopathy (DR). Molecular biological methods which could maintain mitochondrial homeostasis through the regulation of epigenetic mechanisms may prevent the development of DR. Epigenetic-related treatment modalities will become the new direction of targeted therapy for DR.
Objective To observe the genetic predisposition of complement C5 gene polymorphisms in proliferative diabetic retinopathy (PDR) in Chongqing Han population. Methods 400 type 2 diabetes (T2D) patients (case group) and 600 age- and sex-matched healthy controls (control group) were enrolled in this study. There were 8 PDR patients in case group. All the subjects were Han ethnic people. The immune-related representative SNP locus of C5 gene including rs2269067, rs7040033, rs7027797 were screened by linkage disequilibrium analysis. Locus rs1017119 was selected by TagSNP and was around the above three loci. Subjects′ peripheral venous blood was collected and DNA was extracted. Genotyping was examined by PCR-restriction fragment length polymorphism method. The level of C5 plasma protein was measured by enzyme-linked immunoabsorbent assay. Results The frequency of GG genotype of rs2269067 was significantly increased in PDR patients in cases group compared with controls (Pc=3.4×10-5, OR=1.87, 95%CI=1.43 - 2.44;P=3.1×10-6). There was no differences in frequency of G, CC and CG genotype of rs2269067 between two groups (P=1.4×10-4, 1.000, 1.0×10-6). There were no differences in frequency of G, CC, CG, GG genotype of rs7040033, rs1017119, and rs7027797 between two groups (P > 0.05). The production of C5 plasma protein was significantly increased in case group as compare with control group (P=0.0004). An increased production of C5 plasma protein was observed in rs2269067 GG genotype cases compared to CG or CC cases (P=0.003, 0.001). Conclusion C5 rs2269067 GG genotype may be associated with the PDR of T2D in Chongqing Han population.
ObjectiveTo investigate the association of high density lipoprotein cholesterol (HDL-C) and cholesterol ester transfer protein (CETP) TaqIB mutation with non-arteritic anterior ischemic optic neuropathy (NA-AION) in the Shaanxi Han ethnic population. MethodsThe study cohort consisted of 45 individuals that had been diagnosed with NA-AION and 45 healthy controls (matched for age, gender). None of the cases or controls had a history of diabetes, serious cardio-cerebral vascular diseases, liver and kidney dysfunction that might influence plasma lipid levels. Plasma HDL-C was detected by enzyme-linked immunosorbent one-step, through the Toshiba TBA-40FR automatic biochemical analyzer. CETP TaqIB gene polymorphism was determined by the polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) techniques for analysis. B2B2 genotype was only a fluorescence band with 535 bp; B1B1 genotype was 2 fluorescence bands with 361, 174 bp; B1B2 genotype was 3 fluorescence bands with 535, 361, 174 bp. The relative risk of genotype, HDL-C and disease occurrence was analyzed by logistics regression analysis. ResultsThere have no significant difference between NA-AION patients and controls about plasma total cholesterol level and triglyceride level (t=1.907, 1.877; P > 0.05). The plasma HDL-C levels were significantly lower in NA-AION patients than in controls (t=2.367, P=0.022). Compared with controls, the prevalence of B1B1 genotype and B1 allele was higher (χ2=17.289, P=0.001), the prevalence of B2 allele (χ2=15.648, P=0.000) was lower in NA-AION patients. The lower concentration of HDL-C was risk factor of NA-AION (odds ratio=6.143, 95% confidence interval 1.262-29.895, χ2=27.676;P=0.013). The proportion of B1B1 genotype was significantly higher in NA-AION patients than in controls (odds ratio=2.24, 95% confidence interval 2.427-36.323, χ2=10.526; P=0.001). ConclusionsThe low plasma HDL-C is independent risk factor for NA-AION and is associated with the development of NA-AION in the Shaanxi Han ethnic population. CETP TaqIB mutation is associated with low plasma HDL-C in NA-AION in the Shaanxi Han ethnic population.
OBJECTIVE:The hereditary form of retinoblastoma(RB)is a monogenic disorder which is due to germinal mutation of RB susceptibility gene located on 13q14.The majority of hereditary RB cases transmit as a Mendelian autosomal dominant inheritance that 50% of the offspring of a carrier will inherit the disorder susceptibility gene and all carriers will develop the disorder.The authors report 3 hereditary RB families with incompleted penetrance and irregular transmission of RB phenotype. METHOD:RFLPsamp;VNTRs for analysis of haplotype and SSCPamp;direct DNA sequencing for determination of RB point mutation. RESULTS:The mosaicism of Rb gene point mutation resulted in the incompleted penetrance and irregular transmission of RB phentype. CONCLUSION:DAN-based diagnosis can be used to differentiate the hereditary and nonhereditary forms of retinblastoma but only is the direct detection of disease-causing mutation reliable for determnation of carrier and estimation of th e risk for retinoblastoma. (Chin J Ocul Fundus Dis,1996,12: 37- 40)
Olfactory bulb is a critical component in encoding and processing olfactory signals, characterized by its intricate neural projections and networks dedicated to this function. It has been found that descending neural projections from the olfactory cortex and other advanced brain regions can modulate the excitability of olfactory bulb output neurons in the olfactory bulb, either directly or indirectly, which can further influence olfactory discrimination, learning, and other abilities. In recent years, advancements in optogenetic technology have facilitated extensive application of neuron manipulation for studying neural circuits, thereby greatly accelerating research into olfactory mechanisms. This review summarizes the latest research progress on the regulatory effects of neural projections from the olfactory cortex, basal forebrain, raphe nucleus, and locus coeruleus on olfactory bulb function. Furthermore, the important role that photogenetic technology plays in olfactory mechanism research is evaluated. Finally, the existing problems and future development trends in current research are preliminarily proposed and explained. This review aims to provide new insights into the mechanisms underlying olfactory neural regulation as well as applications of optogenetic technology, which are crucial for advancing the research on olfactory mechanism and the application of optogenetic technology.