Objective To establish a method for primary culture of iris pigment epithelial cells(IPE). MethodsEnzyme-Assisted microdissection was used to isolate and cultivate the IPE cells.An identification was made with microscopic and immunohistochemical observations.Results IPE were successfully sultured and showed on differences with RPE in primary culture and subculture.ConclusionEnzyme-Assisted microdissection is a reliable and quick method for the isolation of IPE.
Objective To verify whetheriris pigment epithelial cells(IPECs)possess the similar potential of specific phagocytosis to retinal outer segments(ROS) with retinal pigment epithelialcells(RPECs). Methods IPESc were isolated from neonatal bovines with Hu's method,and were cultured.The cultured cells were identified by immunohistochemical methods with antibodies to cytokeratin and s-100.Total RNA of IPECs was extracted by Trizol.The specific primers for mannose-receptor andbeta;-actin were designed according to their sequence from Genbank.The mRNA expression of these proteins in the IPECs was analyzed by reverse transcription polymerase chain-reaction (RT-PCT).Results The Cultured IPECs have no contamination of other cells .The extracted RNA was ideal and had no degradation.RT-PCR analysis showed that mannose-receptor's mRNA was expressed in cultured IPECs in vitro.ConclusionCultured IPECs may express the mannose-receptor,and may have similar potential of phagocytosis to ROS with REPCs.
ObjectiveTo deeply explore the clinical features and gene mutations of Waardenburg syndrome (WS) by tested of the eyes and genes of three patients. MethodsA Case series study. From 2019 to 2021, 3 children with WS who were diagnosed at Department of Ophthalmology, West China Hospital of Sichuan University were included in the study. Among them, there were 2 males and 1 female; the ages were 3, 4, and 12 months, respectively. All children underwent external eye, anterior segment, fundus and fluorescein fundus angiography, the clinical features of the eyes were observed. The peripheral venous blood of 3 children was collected, and the whole genome DNA was extracted for whole exome sequencing to analyze the gene mutation sites. ResultsAll children had different degrees of iris heterochromia and fundus pigment abnormalities, and were accompanied by sensorineural hearing impairment. Case 1 had dystopia canthorum; case 2 had macular fovea hypoplasia. The sequencing results of case 1 showed that there were large fragments of heterozygous deletion in exons 2-8 of the Paired box 3 (PAX3) gene, who was diagnosed as WS Ⅰ type. The sequencing results of of case 2 showed heterozygous mutation in exon 9 of Microphthalmia-associated transcription factor (MITF) gene (c.1066 C>T), combined with heterozygous mutation in exon 1 of HPS6 gene (c.1417 G>T), who was diagnosed as WS Ⅱ type. The sequencing result of case 3 showed that the exon 3 of SOX10 gene had loss of heterozygosity (c.497_500 delAAGA), who was diagnosed as WS Ⅳ type. Both PAX3 and SOX10 gene mutations were newly discovered mutations. ConclusionsThe ocular clinical features of Waardenburg syndrome include hypopigmentation of the iris and choroid, and dystopia canthorum, etc. Early screening of the eye and hearing will help to better diagnose the disease. The large fragments of heterozygous deletion in exons 2-8 of the PAX3 gene, the heterozygous mutation in exon 9 of MITF gene (c.1066 C>T), and the loss of heterozygosity in exon 3 of SOX10 gene are pathogenic genetic variations of 3 children.
Waardenburg syndrome is a rare genetic disease of auditory pigmentation. The main symptom is sensorineural hearing loss. Pigment disorders and other developmental defects in skin, hair, iris, fundus and other parts are specifically divided into four different subtypes, each of which corresponds to different pathogenic genes, which encode transcription factors and signaling molecules that play a key role in the development process of neural crest cells into melanocytes. Because there are multiple subtypes of Waardenburg syndrome, different subtypes exhibit different symptoms, signs and ocular manifestations. Patients with Waardenburg syndrome are often first treated in ENT head and neck surgery due to hearing loss. Lack of theoretical knowledge related to Waardenburg syndrome by ophthalmologists may lead to misdiagnosis or missed diagnosis. Although there are currently limited treatments for the disease, with the continuous development of gene therapy and hearing management methods, the future treatment prospects will be broader.
Objective lt;brgt;To investigate the feasibility of labeling iris pigment epithelial(IPE)cells of rabbits with 5(and 6)carboxyfluorescein diacetate succinimidyl ester(CFSE). lt;brgt; lt;brgt;Methods lt;brgt;Enzyme-assisted microdissection was used to isolate the cultured rabbitprime;s IPE cells.The third or forth subcultured IPE cells were incubated with 2.5,5,10,20,and 40 mu;mol/L of CFSE for 1,5,and10min respectively.The fluorescence intensity was detected by flow cytometry,and the leakage of CFSE and its dyeing were observed by fluorescence antibody labeling. lt;brgt;Results lt;brgt;Incubation with 20 mu;mol/L CFSE under 37℃for1minute was the most optimal condition for IPE cells labeling.The coloration of IPE cells stained by CFSE lasted 4 weeks.There was no leakage of dye from labeled rabbit IPE cells to non-labeled human IPE cells in mixed culture process. lt;brgt; lt;brgt;Conclusion lt;brgt;With the advantages of high rate of dyeing,long time of tracing,safety and convenience,CFSE can be used as a new method to label the rabbitprime;s IPE cells. lt;brgt; lt;brgt;(Chin J Ocul Fundus Dis, 2006, 22: 261-264)