123 GENISTEIN TRANSPORT ACROSS THE BOVINE OVIDUCT EPITHELIUM

Abstract

The oviduct plays a vital role in regulating the environment surrounding the gametes and early mammalian embryo. However, the permeability of the oviduct to circulating dietary-derived compounds remains relatively unknown. The present study has investigated the barrier properties of the oviduct epithelium in vitro to the movement of genistein, a soya isoflavone and analogue of 17β-estradiol that naturally occurs in the diet and has been reported to exert teratogenic effects. Bovine oviduct epithelial cells (BOECs) were isolated from abattoir-derived reproductive tracts at the mid-luetal phase. The purity of the cell isolate was confirmed using flow cytometry to determine the proportion of cells that expressed CK18 (epithelia), and Vimentin (fibroblasts). Cells were seeded at a density of 1 × 10⁶ mL^–1 on polyethylene terephthalate transwell porous supports (Corning) and maintained between two media-filled chambers for 10 to 12 days, until they formed a polarised confluent monolayer, as confirmed by transepithelial resistance (TEER) greater than 700 Ωcm². To assess the rate of transport, genistein was added to the basal compartment at physiologically relevant levels (100 µM) and the apical compartment was sampled at regular time points for 120 mins. The concentration of genistein in the apical and basal media was measured by HPLC. Furthermore, we compared the rate of genistein transport at physiological (39°C) and room temperature to indicate whether transport was temperature dependent. Rates of transport are expressed as mean apparent permeability coefficient and were compared between groups by a Student’s t-test. Genistein crossed the bovine oviduct epithelium at a linear rate that was higher than spontaneous diffusion across a blank membrane support (12.7 × 10^–3 cm^–2 µM^–1 v. 7.32 × 10^–3 cm^–2 µM^–1, n = 4; P = 0.0075). The rate of genistein transport by epithelial cells was unchanged when cells were assayed at room temperature (12.7 × 10^–3 cm^–2 µM^–1 v. 13.11 × 10^–3 cm^–2 µM^–1, n = 3; P = 0.76), respectively. No significant difference in the directionality of transport was found. Furthermore, TEER was maintained at approximately 700 Ωcm², indicating that the cells remained confluent for the duration of the experiment. These data suggest that the bovine oviduct epithelial cell monolayer facilitates genistein movement from the basal to the apical compartment in vitro. Furthermore, the observation that the rate of transport is unchanged by temperature suggests a passive, trans-cellular, physicochemical mechanism, rather than an active biological process. Regardless of the mechanism, the oviduct epithelium is permeable to genistein, and may even facilitate its transport into the lumen, suggesting that gametes and early embryos could be exposed to this compound in vivo. This is relevant given the previously reported finding indicating that this naturally occurring dietary isoflavone has detrimental effects on early development (Newbold et al. 2001 Cancer Res. 61, 4325–4328). Furthermore, the results demonstrate the potential use of this epithelial model in characterising the transport or barrier properties of the oviduct epithelium towards a range of circulating xenobiotics.