Steroid metabolism by germ cells and spermatozoa in men after vasoepididymostomy.

The ability of germ cells (spermatocytes and spermatids) and spermatozoa present in human ejaculate to metabolize steroids was studied in men with obstructive infertility who had undergone vasoepididymostomy as corrective surgery. Steroid metabolism by spermatozoa in men who had undergone vasovasostomy was also investigated. Germ cells converted testosterone mainly to androstenedione. In addition to androstenedione, dihydrotestosterone and androstanediols were also formed in incubations using spermatids. Both types of germ cells converted estradiol to estrone. Spermatozoa from subjects who had undergone vasoepididymostomy or vasovasostomy converted testosterone to androstenedione as in normal men, while spermatozoa from infertile subjects converted testosterone mainly to dihydrotestosterone. Seminal fluid, free of germ cells, did not show steroid-metabolizing capability.     

Steroid metabolism by human mammary carcinoma.

The ability of human mammary tumors to convert 7alpha 3H-testerone to estrogens was examined in order to determine whether this bore any relationship to estrogen receptor and steroid sulfurylation levels; such levels being indicative of hormone dependency. In 8 out of 9 tumors, formation of estradiol-17beta from testosterone was demonstrated. Those tumors showing the lowest conversion of testosterone to estradiol-17beta possessed the highest levels of dehydroepiandrosterone sulfotransferase which lends support to data implicating sulfurylation in the regulation of steroid metabolism in human tumors. All tumors activated sulfate to adenosine-3'-phospho-5'-phosphosulfate and the concentrations were significantly correlated withe the recorded levels of dehydroepiandrosterone sulfate. Estrogen receptor levels did not show any obvious relationship to the other parameters.     

Steroid metabolism by human breast and rat mammary carcinomata

The metabolism of dehydroepiandrosterone (DHA) and testosterone by both human breast carcinomata and dimethylbenzanthracene (DMBA)-induced rat mammary carcinomata has been investigated.The rat and human carcinomata converted DHA to testosterone and both DHA and testosterone to 5α-dihydrotestosterone, 5α-androstanediol and 16α-hydroxytestosterone. Tentative evidence is also presented to indicate that some rat adenocarcinomata can convert androgen precursors into estradiol-17β.Although quantitative differences between incubations occurred, the spectrum of steroid transformations was similar in both human and rat tumours. The DMBA-induced rat tumour may therefore prove to be a valuable experimental model for human carcinoma tissue with regard to further steroidogenic studies.     

Steroid metabolism by cells from human chorion laeve isolated on Percoll gradients

Collagenase-dispersed cells from human chorion laeve were examined on Percoll gradients. The 3 beta-hydroxysteroid dehydrogenase (a trophoblast marker) and steroid sulfatase activities of the cells were measured and a system was developed to isolate enriched preparations of the trophoblast cells. No cells were found to sediment at Percoll concentrations greater than 50%, and using continuous gradients of Percoll there appeared to be cells with different 3 beta-hydroxysteroid dehydrogenase (3 beta HSD): steroid sulfatase ratios sedimenting in different regions of the gradient. Cells with a high ratio were found in the denser region of the gradient. Continuous gradients provided inadequate separations of distinct populations of cells, thus to obtain a more reproducible system to isolate cells, discontinuous gradients of Percoll were studied. A discontinuous gradient composed of 5, 20, 40, and 60% Percoll was developed and three bands of cells were found sedimenting at the 20, 40 and 60% interfaces, respectively. The number and appearance of cells at the 20 and 60% interfaces varied from tissue to tissue. In contrast, the cells sedimenting at the 40% interface were less variable, a substantial number was found to be present in every tissue studied, they were similar in appearance to the trophoblast cells and had high 3 beta HSD:sulfatase ratios.     

Evaluation of uridine metabolism in human and animal spermatozoa

The objective of this study was to elucidate the role of uridine for spermatozoa, since this pyrimidine nucleoside was found in millimolar concentration in human seminal plasma. Here, the degradative activity of uridine-phosphorylase [EC 2.4.2.3] and the salvage activity of uridine kinase [EC 2.7.1.48] were detected in human spermatozoa. HPLC analysis depicted the uptake of exogeneous 14C-labelled adenine, but not of uridine and of hypoxanthine, into nucleotide pools of boar spermatozoa. On addition of uridine, the computer-assisted semen analysis (CASA) of human cells revealed a reduction of the percentage of motile spermatozoa in contrast to an elevation of some velocity parameters. It is concluded that exogeneous uridine could function as suppressor for early capacitation and as a substrate for phosphorolysis, if ribose is needed, rather than to satisfy a demand for intracellular pyrimidine nucleotides.     

Steroid hormones and the fertilizing capacity of spermatozoa

The effects of eleven different steroid hormones on $\text{in vitro}$ development of fertilizing capacity by hamster sperm were examined. Capacitation of epididymal sperm occurred only in the presence of female genital tract secretions. Fertilizing ability of sperm was poor if estradiol-17β, cortisol, chlormadinone acetate, medroxyprogesterone acetate, or megestrol acetate were present in the incubation medium at 10^?5M, whereas similar concentrations of estradiol-17α, progesterone, norethisterone acetate, ethynodiol diacetate, or norgestrel had little effect. Testosterone was a weak inhibitor of capacitation. Capacitation activity of female uterus and oviduct washings was higher at estrus than diestrus. This activity was reduced by treating intact animals with progesterone, cortisol, or testosterone, but increased by estradiol-17β or HCG. Estradiol-17α has no effect. Activity was low in pregnant or ovariectomized hamsters. Treatment of ovariectomized animals with estradiol-17β increased capacitation activity, but estradiol-17α, HCG or progesterone treatment was ineffective.     

Steroid metabolism in human teratocarcinoma cell line PA 1

Human ovarian teratocarcinoma cells of line PA 1, (Zeuthen et al., 1979[1]) used as model for early embryonic cells, were analyzed for their in vitro capacity to convert steroids. The cells were incubated for 20 h with radioactive pregnenolone, progesterone, dehydroepiandrosterone, androstenedione, testosterone or estradiol-17 beta, or with non-radioactive progesterone, 6 alpha- or 6 beta-hydroxyprogesterone, 3 beta-hydroxy-5 alpha-pregnan-20-one, dehydroepiandrosterone or estradiol-17 beta. The metabolites were analyzed by thin layer chromatography or studied by gas chromatography-mass spectrometry. The results indicate that PA 1 cells are able to metabolize, although to a restricted amount, a variety of steroids, most markedly progesterone. The metabolites were almost exclusively found in the medium. The main metabolite of progesterone was 3 beta, 6 alpha-dihydroxy-5 alpha-pregnan-20-one. Minor formation of progesterone from pregnenolone could be detected. Human chorionic gonadotropin did not have any effect on pregnenolone metabolism. No formation of estradiol-17 beta or estrone from dehydroepiandrosterone, androstenedione or testosterone could be detected. However, estradiol-17 beta was shown to be converted mainly to estrone. These findings indicate that undifferentiated PA 1 teratocarcinoma cells like certain mouse teratocarcinoma cells, seem not to be steroidogenic but are capable of metabolizing naturally occurring steroid hormones and their precursors.     

Uptake and metabolism of androgens by bovine spermatozoa

Spermatozoa from bovine ejaculates and cauda epiditymidis were incubated with either tritiated 17 beta-hydroxy-5 alpha-androstane-3-one (DHT) or 5 alpha-androstane-3 alpha, 17 beta-diol (3 alpha-diol). Examination of the medium incubations demonstrated metabolic conversion of both DHT and 3 alpha-diol when these steriods were incubated with ejaculated sperm. In addition to this interconversion, the following metabolities were identified: 5 alpha-androstane-3 beta, 17 beta-diol, (3 beta-diol), androsterone and 5 alpha-androstane-3, 17-dione (5 alpha-A-dione). Incubations with cauda spermatozoa showed similar metabolic patterns. Androgen binding was exhibited by both sperm types. Examination of the washed cauda sperm pellet, following incubations with 3 alpha-diol showed that the incubated steroid was the most abundantly bound. DHT and 5 alpha-androst-16-en-3 alpha-ol (delta 16-3 alpha-ol1 were also detected. The major part of the radioactivity bound in the sperm pellet was identified as DHT when this steroid was used as the substrate; the remaining radioactivity consisted of 3 alpha-diol and delta 16-3 alpha-ol. Investigations of ejaculated sperm pellets gave similar results apart from the additional identification of 5 alpha-androst-16-en-3 one (delta 16-3-one) and 5 alpha-androst-16-en-3 beta-ol (delta 16-3 beta-ol (delta 16-3 beta-ol).     

Steroid metabolism by avian ovarian cells during follicular maturation

The profiles of steroid hormones produced by ovarian cells from the domestic hen were examined. Theca cells from the immature, small white follicles (SWFT), the third largest (T3), and largest (T1) preovulatory follicles, and the ruptured, postovulatory follicle (POFT) were incubated for 3 h at 37 degrees with [3H] progesterone (Prog) or [3H] pregnenolone (Preg). Granulosa cells from the largest preovulatory follicle were incubated with [3H] Preg or were coincubated with theca cells and [3H] Preg. The production of specific steroid metabolites was determined on the basis of coelution of radioactivity with known standard compounds, using an isocratic high-pressure liquid chromatography (HPLC) technique. Granulosa cells converted 93% of [3H] Preg substrate to Prog. More Prog was utilized by T3 cells than by T1 and SWFT cells, either when [3H] Prog was the substrate or when coincubated with granulosa cells and [3H] Preg. The major metabolites of Prog were androstenedione, 17-hydroxyprogesterone, and an unidentified compound with an elution time of 53 min. The POFT cells metabolized [3H] Prog to the same extent as T3 cells did, but their profile of steroidogenesis favored production of the unidentified 53 min metabolite. SWFT cells utilized the least amount of [3H] Preg substrate. The results point to marked changes in enzyme activities in theca cells during maturation and following ovulation.