ارزیابی ارزش تشخیصی غلظت تستوسترون مادری حین آبستنی برای تعیین جنسیت جنین در اسب

نوع مقاله : تولید مثل

نویسندگان

گروه مامایی و بیماری‌های تولیدمثل دام، دانشکده دامپزشکی، دانشگاه تهران، تهران، ایران

چکیده

زمینه مطالعه: تعیین جنسیت جنین در صنعت اسب به دلایل اقتصادی از اهمیت برخوردار است. بنابراین، روش های مختلفی برای تعیین جنسیت جنین در اسب توسعه پیدا کرده است، ولی تکنیک های حاضر دارای محدودیت هایی هستند. اخیراً، ارزیابی غلظت تستوسترون مادری به عنوان روشی ساده و ارزان جهت تشخیص جنسیت جنین پیشنهاد شده است، اما یافته ها در گونه های مختلف متناقض هستند.
هدف: هدف مطالعه حاضر اندازه گیری غلظت تستوسترون گردش خون مادیان های آبستن با جنین های نر و ماده به منظور سنجش ارزش تشخیصی غلظت تستوسترون مادری برای تعیین جنسیت جنین اسب بود.
روش کار: نمونه های خون در ماه های سه، شش و نه آبستنی از مادیان ها (تعداد = 20) اخذ شد. نمونه ها سانتریفیوژ شده و تا زمان آنالیز هورمونی غلظت تستوسترون با استفاده از کیت الایزا در منفی 20 درجه سانتی گراد ذخیره شدند. جنسیت کره ها در زمان تولد و بر اساس مشاهده اندام تناسلی خارجی تعیین شد.
نتایج: غلظت تستوسترون در ماه های سوم، ششم و نهم آبستنی و نه غلظت تجمعی تستوسترون تفاوتی میان مادیان های دارای کره نر و ماده نداشت (05/0 < P). اما غلظت تستوسترون در طول آبستنی در تمامی مادیان ها فارق از جنسیت جنین آنها تغییر کرد و در ماه شش بالاتر از ماه های سه و نه بود (0001/0 > P).
نتیجه‌گیری: در نتیجه، مطالعه حاضر نشان داد که غلظت تستوسترون مادری نمی تواند برای تعیین جنسیت جنین در اسب استفاده شود. اما مطالعه حاضر مبین تغییرات غلظت تستوسترون در مقاطع مختلف آبستنی در مادیان بود.

کلیدواژه‌ها


Introduction

 

The gender of offspring has been indicated in various species due to scientific and economic reasons. Numerous studies have been conducted to understand mechanisms contributing to offspring sex allocation (Abouhamzeh et al., 2020; Gharagozlou et al., 2016; Mozaffari Makiabadi et al., 2022). The sex of offspring could also be of importance in horses, considering the horse breed and its application (Gharagozlou et al., 2014; Rezagholizadeh et al., 2015; Samper et al., 2012a; Samper et al., 2012b). For instance, breeders of polo horses prefer to have female foals, whereas male foals are favorable for show jumping (Gharagozlou et al., 2014; Rezagholizadeh et al., 2015; Samper et al., 2012a; Samper et al., 2012b).

Given the significance of foal gender in the equine industry, various methods have been developed to ascertain the sex of the fetus during pregnancy (Busato et al., 2021). In this context, ultrasonography could be used to diagnose fetal sex during gestation, but the period for application of ultrasonography is limited and could not be used throughout pregnancy (Busato et al., 2021). Furthermore, analysis of cell-free fetal DNA in maternal circulation has been successfully used to determine fetal sex; however, this technique requires special equipment, which restricts its usage in the equine industry (de Leon et al., 2012).

Considering the limitations of prevailing techniques for determining fetal sex, Kibushi et al. (2016) tested the measurement of maternal testosterone concentration as an alternative method for diagnosing fetal sex in bovines. They observed a higher testosterone concentration in cows carrying male fetuses than in cows carrying female fetuses. Moreover, the cut-off concentration of testosterone for the prediction of calf gender was of acceptable sensitivity and specificity (Kibushi et al., 2016). A former study by Meulenberg and Hofman (1991) on humans also showed a greater concentration of testosterone in women with male fetuses than in women with female fetuses. However, application of this method in equines resulted in discrepant outcomes as testosterone concentration, which was evaluated using the radioimmunoassay technique, was higher in mares carrying female fetuses than mares carrying male fetuses (Busato et al., 2021). The findings of the study by Busato et al. (2021) were unexpected since it is the testes of male fetuses producing testosterone, but not the ovaries of female fetuses, during gestation (Legacki et al., 2017; Scarlet et al., 2021).

Therefore, the present study was conducted to reexamine testosterone concentration in mares pregnant with male and female fetuses to elucidate whether maternal measurement of testosterone could serve as a diagnostic method for fetal sex determination in equines.

Materials and Methods

Study Design and Animals

The present study was approved by Animal Ethics Committee at the University of Tehran in terms of animal welfare and ethics. The study was cross-sectional, in which blood samples were collected from 20 mares of ages (8.80 ± 1.38 years) and parities (including 7 nulliparous and 13 parous mares). To ease the statistical analysis of the effect of age on dependent variables, mares were divided into two age categories, including mares with ≤ 10 years old age (n = 12) and mares with > 10 years old age (n = 8). The mares were housed in a warm-blood horse farm in Qazvin province, Iran. Breedings were performed by a natural covering of mares using an individual stallion in the herd. Pregnancy diagnosis was implemented using rectal ultrasonographic examination 14 to 16 days after confirmation of ovulation by ultrasonographic examination. Given that breeding dates and pregnancy diagnosis were precisely recorded in the herd, the timepoints associated with the third, sixth, and ninth months of pregnancy could easily be determined for blood sampling in this study. The gender of the foal was ascertained at birth based on observation of external genitalia.

Blood Sampling and Testosterone Assay

Blood samples were collected from the jugular vein of mares at the third, sixth, and ninth months of gestation. The samples were centrifuged for 15 minutes at 2000 rpm, and the resultant serum was maintained at -20°C until hormonal assessment. Testosterone was evaluated using an ELIZA kit (Roche Diagnostics, Mannheim, Germany) based on manufacturer instructions. The applied testosterone ELIZA kit's detection limit, intra-assay CV, and inter-assay CV were 12 pg/mL, 2.9 %, and 4.8 %, respectively.

Statistical Analysis

Data associated with testosterone concentration were analyzed using the GLM procedure by a repeated measures model. Multiple comparisons were conducted using the LSMEANS statement. Data associated with the sex ratio of foals were analyzed using the GENMOD procedure, including function link logit in the model. All analyses were conducted in SAS version 9.4 (SAS Institute Inc., Carry, NC, USA). Differences were considered significant at P-value< 0.05.

Results

The concentration of testosterone in mares was not affected by the interaction effect of fetal gender by time (P > 0.05; Figure 1A) and the main effect of fetal gender (P>0.05; Figure 1B). But maternal testosterone concentration was affected by the main effect of time and was higher at the sixth month of pregnancy than in the third and ninth months of pregnancy (P<0.0001; Figure 1C). Moreover, concertation of testosterone during pregnancy was not different between ≤ 10 years old and > 10 years old mares (P>0.05; Figure 2A) and between nulliparous and parous mares (P>0.05; Figure 2B).

Irrespective of testosterone concentration, analysis of data associated with the sex ratio of offspring revealed that ≤ 10 years old mares were more likely to produce male foals as compared with > 10 years old mares (odds ratio = 9.00, 95% confidence interval = 1.14-71.04; P<0.05; Table 1). However, the parity of mares had no significant impact on the sex ratio of foals (P>0.05; Table 1), which implied that maternal age's effect on the sex ratio of offspring was not parity-related.

 

Figure 1. A) The interaction effect of fetal gender by time on testosterone concentration in pregnant mares. B) The main effect of fetal gender on testosterone concentration in pregnant mares. C) The main effect of gestation time on testosterone concentration in pregnant mares. abVarious letters indicate a significant difference (P<0.0001).

 

Figure 2. A) Concentration of circulating testosterone in ≤ 10 and > 10 years old mares during pregnancy. B) Concentration of circulating testosterone in nulliparous and parous mares. abVarious letters indicate a significant difference (P<0.05) 

Table 1. Effect of age and parity of mares on the sex ratio of offspring. Values in parenthesis are actual numbers

Effect

Class

Sex ratio (%)

OR

95% CI

P-value

Age

≤ 10 years old

75.00 (8/12)

9.00

1.14-71.04

0.04

 

> 10 years old

25.00 (2/8)

 

 

 

 

 

 

Parity

Nulliparous

57.14 (4/7)

1.14

0.18-7.28

0.89

 

Parous

53.85 (7/13)

OR: odds ratio; CI: confidence interval

Discussion

 

Given the importance of fetal sex diagnosis during pregnancy in equine industry (Gharagozlou et al., 2014; Rezagholizadeh et al., 2015; Samper et al., 2012a; Samper et al., 2012b) the present study was conducted to assess the association of maternal circulating testosterone concentration with fetal gender in mares. In this context, the present study showed no significant difference in serum testosterone concentration between mares carrying male and female fetuses at the third, sixth, and ninth months of gestation, implicating that maternal circulating testosterone may not serve as a useful indicator of fetal sex in equine. In a recent study, Busato et al. (2021) found comparable concentrations of testosterone in male-fetus- and female-fetus-baring mares at the sixth and seventh months of pregnancy, similar to the present study; however, they observed higher concentrations of testosterone in mares carrying female fetuses than those carrying male fetuses at fifth and eighth months of gestation (Busato et al., 2021). The contradictory findings of these two studies might be related to different measurement methods applied by each of these studies to analyze testosterone concentration, which requires further studies to be elucidated. Unlike equines, greater testosterone concentrations were found in females carrying male fetuses than in those carrying female fetuses in bovines (Kibushi et al., 2016) and humans (Meulenberg & Hofman, 1991). These phenomena imply disparity among species either at a fetal level and development of gonads or at the maternal level, particularly placental function and physiology, which needs further research to become understood.

Nevertheless, temporal dynamics of serum testosterone were observed over the course of gestation in mares as circulating testosterone elevated from month three to six of pregnancy and declined afterwards up to month nine. In this sense, it has been reported that the blood testosterone level increased in mares during pregnancy up to months seven and eight of gestation, at which circulating testosterone peaked (Silberzahn et al., 1984). Furthermore, Satué et al. (2019) revealed that maternal blood testosterone in pregnant mares initiated to increase in months two and three of pregnancy, plateaued between months four and six of pregnancy, decreased from month seven to nine of pregnancy, and experienced a peak in month 10 of pregnancy (Satué et al., 2019). On the other hand, Legacki et al. (2016) mapped alterations of steroid hormones during equine pregnancy using mass spectrometry. They reported that testosterone concentration ranged between 0.10 and 0.34 ng/ml from week 6 to 14 of gestation, but it was not debatable afterward (Legacki et al., 2016). Although all studies substantiated alterations of circulating testosterone in pregnant mares during gestation, the pattern of these changes seems to be discrepant among various studies, which might be due to the timepoints selected for blood sampling and/or the methodology and kits used for hormonal analysis.

Another interesting result of the present study was the effect of maternal age on fetal sex. It was found that younger mares were more likely to produce male offspring as compared with older mares. It should be noted that this effect of maternal age did not depend on the history of experiencing pregnancy. Moreover, the effect of a stallion on the fetal sex ratio has been reported previously (Gharagozlou et al., 2014), but in the present study, all investigated mares were bred by a single stallion, and so the effect of a stallion on sex ratio was not a confounding factor in this study. In line with present research findings, a study by Santos et al. (2015) showed that the percentage of males dwindled with the increase in the age of mares (Santos et al., 2015). Many changes in mares occur during aging, including changes in the development of ovarian follicles and oocytes (Ginther et al., 2008; Rambags et al., 2014; Rizzo et al., 2019), embryonic and fetal growth (Cuervo-Arango et al., 2018; Derisoud et al., 2021; Squires et al., 1999) and even the structure and function of the uterus (Ousey et al., 2012), which can be considered as potential influencing factors (Busato et al., 2021). Concerning potential contributing mechanisms, factors affecting the sex ratio of offspring could be divided into two categories of preconceptional and postconceptional determinants. With the former, androgens, estrogens, and the immune system of the female reproductive tract have been reported to the skewed sex ratio of offspring by impacting gametes and/or their interaction with oviduct (Almiñana et al., 2014; Emadi et al., 2014; Gharagozlou et al., 2016). With the latter, maternal body condition and glucose concentration have been observed to dimorphically affect the survival of male and female embryos, thereby impacting the sex ratio (Cameron et al., 2008). Nevertheless, the exact mechanisms underlying the effect of maternal age on the sex ratio of offspring warrants further studies to be deciphered.

Conclusion

The present study showed no significant difference in maternal testosterone concentrations between mares carrying male fetuses and mares carrying female fetuses at the third, sixth, and ninth months of gestation. Therefore, it appeared that evaluation of circulating testosterone in pregnant mares could not serve as a diagnostic method for determining fetal sex in horses.

Acknowledgments

The current research was supported by the University of Tehran (Grant number: 7508010/6/21). The authors would like to express their gratitude to the staff at the warm-blood horse farm (Qazvin, Iran) for their kind assistance.

Conflict of Interest

The authors declared no conflict of interest.

Abouhamzeh, B., Youssefi, R., Akbarinejad, V., & Mirsadeghi, E. (2020). Effect of feeding male mice with palm, fish, and sunflower oils on sperm characteristics and sex ratio of offspring. Veterinary Research Forum, 11(4), 319-323.       [DOI:10.30466/vrf.2018.92060.2227]
Almiñana, C., Caballero, I., Heath, P. R., Maleki-Dizaji, S., Parrilla, I., Cuello, C.,. Fazeli, A. (2014). The battle of the sexes starts in the oviduct: Modulation of oviductal transcriptome by X and Y-bearing spermatozoa. BMC Genomics, 15(1). [DOI:10.1186/1471-2164-15-293] [PMID] [PMCID]
Busato, E. M., Weiss, R. R., Abreu, A. C. M. R. d., Bergstein-Galan, T. G., Marcondes, F. A. B., Kozicki, L. E., . . . Dornbusch, P. (2021). Correlation of maternal concentrations of plasma testosterone with fetal sex in horses. Ciencia Rural, 51. [DOI:10.1590/0103-8478cr20200237]
Cameron, E. Z., Lemons, P. R., Bateman, P. W., & Bennett, N. C. (2008). Experimental alteration of litter sex ratios in a mammal. Proceedings of the Royal Society B: Biological Sciences, 275(1632), 323-327. [DOI:10.1098/rspb.2007.1401] [PMID] [PMCID]
Cuervo-Arango, J., Claes, A. N., & Stout, T. A. E. (2018). Horse embryo diameter is influenced by the embryonic age but not by the type of semen used to inseminate donor mares. Theriogenology, 115, 90-93.                [DOI:10.1016/j.theriogenology.2018.04.023] [PMID]
de Leon, P. M. M., Campos, V. F., Dellagostin, O. A., Deschamps, J. C., Seixas, F. K., & Collares, T. (2012). Equine fetal sex determination using circulating cell-free fetal DNA (ccffDNA). Theriogenology, 77(3), 694-698. [DOI:10.1016/j.theriogenology.2011.09.00 5] [PMID]
Derisoud, E., Auclair-Ronzaud, J., Palmer, E., Robles, M., & Chavatte-Palmer, P. (2021). Female age and parity in horses: How and why does it matter? Reproduction, Fertility and Development, 34(2), 52-116.               [DOI:10.1071/RD21267] [PMID]
Emadi, S. R., Rezaei, A., Bolourchi, M., Hovareshti, P., & Akbarinejad, V. (2014). Administration of estradiol benzoate before insemination could skew secondary sex ratio toward males in Holstein dairy cows. Domestic Animal Endocrinology, 48(1), 110-118. 
Gharagozlou, F., Akbarinejad, V., Youssefi, R., & Rezagholizadeh, A. (2014). Effect of sire-associated factors on secondary sex ratio of offspring in equine. Journal of Equine Veterinary Science, 34(7), 926-929. [DOI:10.1016/j.jevs.2014.04.003]
Gharagozlou, F., Youssefi, R., Vojgani, M., Akbarinejad, V., & Rafiee, G. (2016). Androgen receptor blockade using flutamide skewed sex ratio of litters in mice. Veterinary Research Forum, 7(2), 169-172.
Ginther, O. J., Gastal, M. O., Gastal, E. L., Jacob, J. C., Siddiqui, M. A. R., & Beg, M. A. (2008). Effects of age on follicle and hormone dynamics during the oestrous cycle in mares. Reproduction, Fertility and Development, 20(8), 955-963.                [DOI:10.1071/RD08121] [PMID]
Kibushi, M., Kawate, N., Kaminogo, Y., Hannan, M. A., Weerakoon, W. W. P. N., Sakase, M., Tamada, H. (2016). Fetal gender prediction based on maternal plasma testosterone and insulin-like peptide 3 concentrations at midgestation and late gestation in cattle. Theriogenology, 86(7), 1764-1773. doi:10.1016/j.theriogenology.2016.05.039 [DOI:10.1016/j.theriogenology.2016.05.039] [PMID]
Legacki, E. L., Ball, B. A., Corbin, C. J., Loux, S. C., Scoggin, K. E., Stanley, S. D., & Conley, A. J. (2017). Equine fetal adrenal, gonadal and placental steroidogenesis. Reproduction, 154(4), 445-454.          [DOI:10.1530/REP-17-0239] [PMID]
Legacki, E. L., Scholtz, E. L., Ball, B. A., Stanley, S. D., Berger, T., & Conley, A. J. (2016). The dynamic steroid landscape of equine pregnancy mapped by mass spectrometry. Reproduction, 151(4), 421-430. [DOI:10.1530/REP-15-0547] [PMID]
Meulenberg, P. M. M., & Hofman, J. A. (1991). Maternal testosterone and fetal sex. Journal of Steroid Biochemistry and Molecular Biology, 39(1), 51-54.  [DOI:10.1016/0960-0760(91)90012-T]
Mozaffari Makiabadi, M. J., Akbarinejad, V., Heidari, F., Gharagozlou, F., & Vojgani, M. (2022). Greater Reproductive Performance in Holstein Dairy Cows with Moderate Length of Anogenital Distance at First Service Postpartum. Iranian Journal of Veterinary Medicine, 16(1), 46-56.               [DOI:10.22059/ijvm.2020.309538.1005125]
Ousey, J. C., Kölling, M., Newton, R., Wright, M., & Allen, W. R. (2012). Uterine haemodynamics in young and aged pregnant mares measured using Doppler ultrasonography. Equine Veterinary Journal, 44(SUPPL. 41), 15-21. [DOI:10.1111/j.2042-3306.2011.00446.x] [PMID]
Rambags, B. P., van Boxtel, D. C., Tharasanit, T., Lenstra, J. A., Colenbrander, B., & Stout, T. A. (2014). Advancing maternal age predisposes to mitochondrial damage and loss during maturation of equine oocytes in vitro. Theriogenology, 81(7), 959-965. [DOI:10.1016/j.theriogenology.2014.01.020] [PMID]
Rezagholizadeh, A., Gharagozlou, F., Akbarinejad, V., & Youssefi, R. (2015). Left-sided ovulation favors more male foals than right-sided ovulation in thoroughbred mares. Journal of Equine Veterinary Science, 35(1), 31-35. [DOI:10.1016/j.jevs.2014.11.001]
Rizzo, M., Ducheyne, K. D., Deelen, C., Beitsma, M., Cristarella, S., Quartuccio, M., de Ruijter-Villani, M. (2019). Advanced mare age impairs the ability of in vitro-matured oocytes to correctly align chromosomes on the metaphase plate. Equine Veterinary Journal, 51(2), 252-257. [DOI:10.1111/evj.12995] [PMID] [PMCID]
Samper, J. C., Morris, L., & Plough, T. A. (2012b). The Use of Sex-Sorted Stallion Semen in Embryo Transfer Programs. Journal of Equine Veterinary Science, 32(7), 387-389. [DOI:10.1016/j.jevs.2012.05.056]
Samper, J. C., Morris, L., Peña, F. J., & Plough, T. A. (2012a). Commercial Breeding with Sexed Stallion Semen: Reality or Fiction? Journal of Equine Veterinary Science, 32(8), 471-474.       [DOI:10.1016/j.jevs.2012.06.018]
Santos, M. M., Maia, L. L., Nobre, D. M., Oliveira Neto, J. F., Garcia, T. R., Lage, M. C. G. R., . . . Valle, G. R. (2015). Sex ratio of equine offspring is affected by the ages of the mare and stallion. Theriogenology, 84(7), 1238-1245. [DOI:10.1016/j.theriogenology.2015.07.001] [PMID]
Satué, K., Marcilla, M., Medica, P., Ferlazzo, A., & Fazio, E. (2019). Testosterone, androstenedione and dehydroepiandrosterone concentrations in pregnant Spanish Purebred mare. Theriogenology, 123, 62-67. doi:10.1016/j.theriogenology.2018.09.025 [DOI:10.1016/j.theriogenology.2018.09.025] [PMID]
Scarlet, D., Handschuh, S., Reichart, U., Podico, G., Ellerbrock, R. E., Demyda-Peyrás, S., . . . Aurich, C. (2021). Sexual differentiation and primordial germ cell distribution in the early horse fetus. Animals, 11(8). [DOI:10.3390/ani11082422] [PMID] [PMCID]
Silberzahn, P., Zwain, I., & Martin, B. (1984). Concentration increase of unbound testosterone in plasma of the mare throughout pregnancy. Endocrinology, 115(1), 416-419. [DOI:10.1210/endo-115-1-416] [PMID]
Squires, E. L., McCue, P. M., & Vanderwall, D. (1999). The current status of equine embryo transfer. Theriogenology, 51(1), 91-104. [DOI:10.1016/S0093-691X(98)00234-9].