Valerie L. Slott

A Dose-Response Analysis of Methoxychlor-Induced Alterations of Reproductive Development and Function in the Rat

In the present study rats were dosed from weaning, through puberty and gestation, to Day 15 of lactation with methoxychlor at 25, 50, 100, or 200 mg/kg/day. Morphological landmarks of puberty were measured, including the ages at vaginal opening, first estrus, and first estrous cycle in females and at preputial separation in males. In the female, estrous cyclicity, fertility, litter size, number of implantation sites, organ weights, and ovarian and uterine histology were also measured. The viability of the offspring (F1) and their fertility were evaluated using a continuous breeding protocol. Males were necropsied after breeding, the reproductive organs were weighed, and the cauda epididymal sperm counts were determined. One testis was used for histopathology, while the other was used to quantify interstitial fluid (IF) content, IF testosterone concentration, and testicular sperm production. Testosterone and androgen-binding protein were measured in the caput epididymis, and sperm motility and morphology were evaluated from a caudal sample. The serum and pituitary were saved for hormonal determinations. Methoxychlor accelerated the age at vaginal opening and first estrus, and the vaginal smears were cornified. Growth was retarded at 100 and 200 mg/kg/day and fertility was reduced when the females were bred with untreated or similarly treated males. In the highest-dose group, the mated females went from constant estrus into pseudopregnancy following mating, but they had no implants. In males, methoxychlor treatment markedly reduced growth, seminal vesicle weight, cauda epididymal weight, caudal sperm content, and pituitary weight. Puberty was delayed in the two highest-dosage groups. Testicular sperm measures were much less affected than caudal measures. Testis weight and histology were slightly affected, and testicular sperm production, sperm morphology, and motility were unaffected. Endocrine function of the testes and pituitary was altered by methoxychlor administration. Leydig cell testosterone production, in response to human chorionic gonadotropin challenge, was reduced and pituitary levels of prolactin, thyroid-stimulating hormone (TSH), and follicle-stimulating hormone (FSH) were altered. In contrast, serum levels of prolactin, FSH, and luteinizing hormone were unaffected. Serum TSH was reduced by 50% of control at 100 and 200 mg/kg/day, while pituitary levels were increased. Gonadotropin-releasing hormone concentration in the mediobasal hypothalamus was also elevated. In spite of the many reproductive alterations, the fertility of treated males was not reduced when they were mated with untreated females.(ABSTRACT TRUNCATED AT 400 WORDS)

Importance of glutathione in the acquisition and maintenance of sperm nuclear decondensing activity in maturing hamster oocytes

Sperm nuclear decondensing activity in mammalian oocytes is dependent upon the maturational state of the oocyte. It is maximal in mature, metaphase II oocytes and minimal or absent in immature germinal vesicle (GV) and fertilized pronuclear oocytes. Previous studies suggested that this difference may be due to the relative ability of an oocyte to reduce the protamine disulfide bonds in the sperm nucleus. The results of this study show that mature hamster oocytes contain significantly more glutathione (GSH), about 8 mM, and hence more disulfide reducing power, as compared with GV (4 mM) or pronuclear (6 mM) oocytes. Furthermore, the acquisition of sperm nuclear decondensing activity by maturing oocytes can be prevented or delayed by blocking GSH synthesis with L-buthionine-S,R-sulfoximine during the early stages of oocyte maturation. This is the first evidence that modulation of GSH levels during oocyte maturation and fertilization may be a mechanism by which sperm nuclear decondensing activity is regulated.

Methods for assessing rat sperm motility

Computer-assisted sperm analysis (CASA) systems are becoming more widely used. With this spread of technology come more data from toxicology studies, designed to determine if treatment with putative toxicants affects sperm motion parameters. While these CASA methods provide us with more ways to evaluate toxicity and thus perhaps increase our chances of successfully protecting human health, there is also a greater likelihood that different laboratories will use different methods of collecting data on sperm motility. Different systems used with different methods in different laboratories will inevitably generate data that are difficult to compare. In a prospective attempt to address this issue of comparability and limit the problems, a group of individuals using CASA systems to analyze rat sperm motility convened to discuss methodologic issues, share data, and try to reach a consensus about methods for performing these studies. This article shares those meetings and data in the hope that common methods will enhance interlaboratory comparisons.

Optimization of the Hamilton-Thorn Computerized Sperm Motility Analysis System for Use with Rat Spermatozoa in Toxicological Studies

To optimize the Hamilton-Thorn Motility Analyzer (HTM; Hamilton-Thorn Research, Beverly, MA) for use in reproductive toxicology studies with rat spermatozoa, the accuracy and precision of the instrument were assessed under a variety of instrument settings. Videotapes of both fast- and slow-swimming sperm were analyzed repeatedly to obtain data across a range of sperm velocities as might be encountered as a consequence of exposure to reproductive toxicants. Acquisition rates were varied across the HTM menu choices (30, 19, 10, or 7 frames/sec) as were the number of frames analyzed (5 to 20) at each framing rate. For fast-swimming samples (mean straight-line velocity (VSL) approximately 130 microns/sec) generally good agreement between computer-assisted sperm analysis (CASA) and manually obtained data was found for percentage of motile sperm and straight-line velocity; i.e., CASA values were within 10% of manual values for most frame/rate combinations. The accuracy of these measures held true over a wide range of sperm concentrations and percentage motilities. However, CASA measures were less accurate for sperm samples of lower velocities (mean VSL approximately 50 microns/sec and mean VSL approximately 30 microns/sec) in that the velocity of very slow sperm was overestimated (particularly at 30 frames/sec). A soft-ware change (6.5R) and performing analyses at 19 instead of 30 frames/sec improved straight-line accuracy for the slow sperm and enhanced the discrimination between fast (presumably control) and slow (presumably treated) sperm samples. These data show that this motility analyzer could be successfully configured to evaluate rodent sperm samples. The use of such CASA systems in toxicology studies will provide valuable information that may improve human reproductive risk assessment.

Acute Inhalation Exposure to Epichlorohydrin Transiently Decreases Rat Sperm Velocity

The effect of inhaled epichlorohydrin on rat sperm motility characteristics was evaluated. Male F-344 rats were exposed to 100 ppm epichlorhydrin via inhalation for 4 hr in the morning of Day 0 and killed immediately and on Days 1, 2, 6, and 14 postexposure. Videotapes of cauda epididymal sperm were analyzed (300-350 sperm/sample) with a Hamilton Thorn motility analyzer (HTM-2000, Hamilton Thorn Research, Danvers, MA). Epichlorohydrin did not affect the percentage of motile sperm at any time. However, transient changes in sperm velocity were found. On Day 1 postexposure mean progressive (straight line) and mean path (smoothed curvilinear) velocity were significantly decreased to 80 and 85% of control, respectively. The progressive velocities of sperm from both control and treated rats were normally distributed, indicating a general effect of epichlorohydrin on all sperm as opposed to a more severe effect on a specific sperm subpopulation. Sperm velocity was not significantly affected at later times. Other endpoints (testis and epididymis weights, testicular spermatid counts, and cauda epididymal sperm reserves) were unaltered by epichlorohydrin. Thus, inhaled epichlorohydrin at 100 ppm produced specific, transient decreases in rat sperm velocity. Furthermore, computer-assisted sperm analysis was able to detect these relatively subtle, toxicant-induced changes in rat sperm velocity, demonstrating the utility of this technology in reproductive toxicology studies.

Multiple effects of ethane dimethanesulfonate on the epididymis of adult rats

Ethane dimethanesulfonate (EDS), a Leydig cell toxicant which results in transient infertility, was used in a 4 day postexposure experimental protocol designed to identify any effects this compound might exert on the epididymis. The techniques of efferent duct ligation and testosterone (T) implantation were used to negate the role of testicular effects on the epididymal parameters. Numerous evaluations were performed including light and electron microscopy, computer assisted sperm motion analyses, and electrophoresis of sperm membrane proteins. EDS was shown to affect the epididymis in a dose-dependent fashion. The action of EDS on the epididymis is in part due to Leydig cell cytotoxicity and the resulting decrease in circulating androgen since T implantation prevented some of the changes in sperm proteins and motility. However, neither efferent duct ligation nor T implantation prevented the formation of sperm granulomas in the caput epididymidis, the distinct morphological alterations of the corpus epididymidis, the modification of certain sperm membrane proteins, or the decrease in the progressive motility and velocity of sperm following EDS treatment. Although we cannot prove these effects of EDS are due to a direct action on the epididymis, it is now clear that EDS has a distinct action on the epididymis which is unrelated to circulating T or testicular fluid.

Unilateral depletion of testicular glutathione levels in the rat following intratesticular injections of diethylmaleate and buthionine sulfoximine

A method was developed to selectively deplete glutathione (GSH) in a single rat testis. Using intratesticular injections of a mixture of two GSH-depleting agents, diethylmaleate and buthionine sulfoximine, testicular GSH levels were decreased to 33-54% of control 2 hr after injection and remained suppressed for 24 hr. GSH levels in the contralateral testis and liver were not affected by this treatment. Comparisons between GSH-depleted and vehicle-injected (contralateral) testes, evaluated 2 weeks later, showed that although testis and epididymal weights and cauda epididymal sperm reserves were slightly reduced (to greater than or equal to 90% of controls), no changes were seen in testicular spermatid counts or in the morphology or motility of cauda epididymal sperm. An increase in histologically abnormal tubules localized to the injection site occurred in some GSH-depleted testes; however, the proportion of normal tubules containing step 19 spermatids was not affected. Thus, intratesticular injections of GSH-depleting agents selectively lowered GSH levels in the treated testis, with minimal adverse effects. This protocol can now be applied to investigate specific roles of GSH in the testes, particularly with regard to the possible modulation of the effects of testicular toxicants.