Differentiation of the corpus luteum of the mink (Mustela vison): Mitogenic and steroidogenic potential of luteal cells from embryonic diapause and postimplantation gestation

Abstract

The mink corpus luteum (CL) involutes after ovulation and remains dormant, synthesizing low amounts of progesterone until reactivated to terminate embryonic diapause. We examined the mitotic and steroid synthetic capacity of luteal cells from the diapause and postimplantation phases of mink gestation. Cells from diapause divided in vitro, reaching confluence in 7-8 days. Three phenotypes were distinguishable: a fusiform cell in whorls, a hypertrophied epithelioid cell, and a small epithelioid cell. The first and second cell types divided in vitro after confluence, evidenced by localization of proliferating cell nuclear antigen (PCNA) in their nuclei. The small epithelioid cells were present in cell nests and showed no PCNA activity. Cells derived from reactivated CL did not reach confluence and had no PCNA activity. Progesterone accumulation was enhanced in luteal cells from diapause by LH, FSH, and dibutyryl (Bu2) cAMP, and by LH and (Bu2)cAMP in cells from reactivated CL. In luteal cells from the diapause phase of gestation, LH and (Bu2)cAMP induced increases in mRNA coding for steroidogenic acute regulatory protein, while cytochrome P450 side-chain cleavage enzyme mRNA was increased by prolactin, LH and (Bu2)cAMP. Cellular concentrations of 3β-hydroxysteroid dehydrogenase-Δ5-4-isomerase mRNA were increased by prolactin and (Bu2)cAMP. Thus, luteinization in the mink CL does not engender exit from the cell cycle, as both fusiform and hypertrophied cells from diapause divide in vitro. Reactivation appears to represent terminal differentiation. LH is capable of stimulating steroidogenesis in vitro in luteal cells from diapause, and prolactin and LH appear to have both specific and overlapping stimulatory effects on the CL of this species.