P-103 Three-dimensional oviductal organoid model to study spermatozoa-oviduct interaction in humans

Abstract

Abstract Study question Is it possible to establish an in vitro model that recapitulating human oviduct to investigate sperm-oviduct interaction Summary answer Three-dimensional (3D) oviductal organoid model was established from either primary human oviductal tissues or immortalized human OE-E6/67 cell line, based on our protocol. What is known already The sperm reservoir in oviduct is formed to maintain the fertilizing capacity of spermatozoa until ovulation by the binding of sperm to the epithelial lining of the oviduct, which is also significant to select sperm with normal chromatin structure and superior fertilization ability. The regulation and mechanism of sperm reservoir formation in human is still unknown, mainly due to the ethical issue and technical difficulty in obtaining enough human oviduct. We previously demonstrated that sperm fucosyltransferase-5 (sFUT5), a carbohydrate-binding protein on spermatozoa, is responsible for spermatozoa-oviduct interaction in humans. Study design, size, duration Human oviductal epithelial cell line immortalized by HPV 16 E6/E7 open reading frame by retroviral expression system was employed to establish the co-culture model. Fresh human samples (human spermatozoa,N = 30; 1-2 cm primary oviductal tissue,N = 15) were collected in hospital with signed consent. Fluorescent pre-labelled sperm were co-cultured with organoids for 2 hours. At least three replicates were conducted for each assay. Participants/materials, setting, methods Morphological characterization and markers expressions of the organoid were determined by immunohistochemistry and confocal microscopy analysis. The sperm binding capacity of the oviductal organoid was studied by co-culture system. Sperm chromatin structure of the organoid-bound sperm was assessed by flow cytometry-based TUNEL assay. Affinity chromatography followed by nano-liquid chromatography–mass spectrometry was used to identify the sFUT5-binding proteins on ovidutal epithelial cells (OECs) and their expressions on OECs were validated by immunostaining/flow cytometry. Main results and the role of chance The organoid exhibited a hollow structure surrounded by a single layer of OECs. Immunohistochemistry analysis revealed the high expressions of epithelial marker E-cadherin (basolateral membrane), secretory marker pair-box 8 (PAX8) and proliferative marker Ki67. Expression of ciliated cell marker, acetylated tubulin (AcTUB) can also be detected. The modification of culture environment successfully reversed the OEC organoids polarity as demonstrated by immunostaining using antibodies against ZO-1 (apical marker) and E-cadherin (basolateral marker), making the organoid accessible during the co-culture. These apical-out OEC organoids have significantly higher sperm binding capacities than their basal-out counterparts. Furthermore, OEC organoid-bound spermatozoa possessed more intact DNA than the unbound spermatozoa. The results indicate the relevance of using OEC organoid-spermatozoa co-culture model as a tool to assess spermatozoa-oviduct interaction in humans. By using immuno-affinity chromatography and mass spectrometry analysis, cell adhesion molecule 4 (CADM4) was then identified as a potential sFUT5-interacting protein on OECs. This result was further supported by flow cytometry and immunofluorescent staining. 3-D oviductal organoid model demonstrates profound potential for in vitro investigation of human oviduct physiology. Limitations, reasons for caution Our 3D model may not fully represent the entire cellular complexity and tubular architecture of the oviductal epithelium. Further investigation on the sperm morphology and DNA integrity and analysis on organoid transcriptome will enhance our understanding on oviduct in human reproduction. Wider implications of the findings The results from co-culture may give a clue to future study on whether oviductal organoid can be applied clinically for functional sperm selection in in vitro fertilization. Our apical-out organoid model may also be applied to study tubal ectopic pregnency. Trial registration number not applicable