Effects of Heat-Stress on Oocyte Number and Quality and In Vitro Embryo Production in Holstein Heifers

Autores

DOI:

https://doi.org/10.22456/1679-9216.122371

Resumo

Background: This study aimed to determine the effects of environmental temperature on the number and quality of oocytes and embryo production rates obtained by performing ovum pick up (OPU). Heat stress leads to long-term, short-term, visible, and invisible effects in dairy cows. Its effects on reproduction are evident in all stages, from oocyte development to birth. Disturbance in ovarian follicle development, follicular dominance deficiency, anoestrus, polyspermia, embryonic
losses, decreased fetal growth, and abortion are some examples of responses to these effects. The aim of the present study was aimed to determine the effects of ambient temperature on oocyte quality and number and embryo production rates.
Materials, Methods & Results: The animal material used in this study comprised 10 Holstein heifers. At the beginning of the study, the heifers were 13-15 months old. OPU was performed at different times of the year, and weather conditions were recorded. Grouping according to ambient temperature was done as < 10°C (group 1), 10-25°C (group 2), and > 25°C (group 3). The veterinary ultrasonography device and a set of compatible intravaginal OPU probe, catheter, and aspiration device were used for OPU application. All antral follicles with diameters of 2-8 mm in the ovaries were aspirated. The aspirated follicle fluids were examined under a stereo microscope, and the cumulus-oocyte complexes (COC) were collected and classified according to their structure. A, B, and C-quality oocytes were included in the in vitro embryo production process. After performing 69 OPUs on random days of the cycle, the number of oocytes per OPU was found to be 8.72, 6.32, and 6.85 in groups 1, 2, and 3, respectively (P < 0.05). The number of viable oocytes per OPU was 6.83, 4.64, and 4.65 in groups 1, 2, and 3, respectively (P < 0.05). The statistical difference between the first group and the other groups was significant for cleavage and blastocyst counts (P < 0.05).
Discussion: All the negative effects of heat stress on animals resulted from the increased body temperature. Reproductive performance is adversely affected by high temperatures and humidity during periods of high ambient temperatures. Metabolic heat is released, and the heat load increases due to the metabolism of nutrients in cattle. Internal body temperature is regulated via the dissipation of metabolic heat to the environment. The amount of heat dissipated via conduction and
convection depends on the unit body weight, surface area, skin and coat color, difference in temperature gradient of the animal and ambient temperature, and humidity. In the present study, it was determined that the blastocyst development rates of the oocytes obtained in the warm season (>25°C [group 3]) were lower than those of the other groups. It was concluded that this may be because the oocytes developed under chronic heat stress in the animals, and several cycles were required to enhance oocyte quality and developmental potential. Additional studies are needed to investigate the response of oocytes obtained with OPU to heat stress during embryonic developmental stages and to determine the sensitivity and effects of embryonic tissue damage according to developmental stages. Based on the results of the present study, it was concluded
that performing OPU and in vitro embryo production (IVEP) when the ambient temperature is close to the thermoneutral limits may increase the blastocyst development rates.


Keywords: blastocyst, heat stress, heifer, in vitro embryo production, oocyte quality, ovum pick-up.

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Biografia do Autor

Sakine Ülküm Çizmeci, Selcuk University

Department of Obstetrics and Gynecology

Assistant Prof.

Dursun Ali Dinç, Selcuk University

Department of Obstetrics and Gynecology 

Profesör

Omer Faruk Yesilkaya, Selcuk University

Department of Obstetrics and Gynecology

Research assistant

Muhammed Furkan Çiftçi, Selcuk University

Department of Obstetrics and Gynecology

Research assistant

Abdurrahman Takcı, Cumhuriyet University

Department of Obstetrics and Gynecology

Assistant Prof.

Mustafa Numan Bucak, Selcuk University

Department of reproduction an Artificial Insemination

Referências

Abdelatty A.M., Iwaniuk M. E., Potts S.B. & Gad A. 2018. Influence of maternal nutrition and heat stress on bovine oocyte and embryo development. International Journal of Veterinary Science and Medicine. 6: 1-5.

Aggarwal A. & Upadhyay R. 2013. Thermoregulation. In: Heat Stress and Animal Productivity. London: Springer, pp.2-20.

Altınccekic S. & Koyuncu M. 2012. Farm animals and stress. Journal of Animal Production. 53(1): 27-37.

Ari U.C. 2015. Physiologic and Hormonal Effects of Heat Stress on Reproduction in Cattle. In: Turkiye Klinikleri Reproduction and Artificial Insemination - Special Topics. 1(1): 1-10.

Atrian P. & Shahryar H.A. 2012. Heat Stress in Dairy Cows (A Review). Research in Zoology. 2(4): 31-37.

Bényei B., Gáspárdy A. & Barros C.W.C. 2001. Changes in embryo production results and ovarian recrudescence during the acclimatisation to the semiarid tropics of embryo donor Holstein-Friesian cows raised in a temperate climate. Animal Reproduction Science. 68(1-2): 57-68.

Bridges P.J., Brusie M.A. & Fortune J.E. 2005. Elevated (heat stress) in vitro reduces androstenedione and estradiol and increases progesterone secretion by follicular cells from bovine dominant follicles. Domestic Animal Endocrinology. 29: 508-522.

De Rensis F. & Scaramuzzi RJ. 2003. Heat stress and seasonal effects on reproduction in the dairy cow-a review. Theriogenology. 60: 1139-1151.

De Rensis F., Saleri R., Garcia-Isierto I., Scaramuzzi R. & Lopes-Gaitus F. 2021. Effects of Heat Stress on Follicular Physiology in Dairy Cows. Animals. 11(3406): 1-9.

Durmuş M. & Koluman N. 2019. Hormonal Changes caused on Ruminant Animals exposed to High Environment Temperature. Journal of Animal Production. 60 (2): 159-169.

El-Sayed A. & Kamel M. 2020. Climatic changes and their role in emergence and re-emergence of diseases. Environmental Science and Pollution Research. 27(18): 22336-22352.

Fair T. 2003. Follicular oocyte growth and acquisition of developmental competence. Animal Reproduction Science. 78: 203-216.

Farooq U., Samad H.A., Shehzad F. & Qayyum A. 2010. Physiological responses of cattle to heat stress. World Applied Sciences Journal. 8: 38-43.

Gendelman M., Aroyo A., Yavin S. & Roth Z. 2010. Seasonal effects on gene expression, cleavage timing, and developmental competence of bovine preimplantation embryos. Reproduction. 140(1): 73-82.

Grondahl M.L., Christiansen S.L., Kesmodel U.S., Agerholm I.E., Lemmen J.G., Lundstrom P., Bogstad J., Raaschou-Jensen M. & Ladelund S. 2017. Effect of women’s age on embryo morphology, cleavage rate and competence-A multicenter cohort study. PLoS One. 12: 1722456.

Gürer F. 2003. Oocyte maturation in vivo and in vitro. In: Hassa H. (Ed). Clinical Approach and IVF Laboratory Practices in Infertile Cases. Eskisehir: Osmangazi Publishing, pp.229-240.

Hammond E.R. & Morbeck D.E. 2019. Tracking Quality: can embryology key performance indicators be used to identify clinically relevant shifts in pregnancy rate? Human Reproduction. 34: 37-43.

Hansen P.J. & Arrchiga C.F. 1999. Strategies for managing reproduction in the heat-stressed dairy cows. Journal of Animal Science. 77(2): 36-50.

Hansen P.J., Drost M., Rivera R.M., Paula-Lopes F.F., Al-Katanani Y.M., Krininger III C. E. & Chase Jr. C.C. 2001. Adverse impact of heat stress on embryo production: causes and strategies for mitigation. Theriogenology. 55(1): 91-103.

Hill D.L. & Wall E. 2017. Weather influences feed intake and feed efficiency in a temperate climate. Journal of Dairy Science. 100(3): 2240-2257.

Hunter R.H.F. & López-Gatius F. 2020. Intra-follicular temperature acts to regulate mammalian ovulation. Acta Obstetricia et Gynecologica Scandinavica. 99: 301-302.

Hunter R.H.F. 2012. Temperature gradients in female reproductive tissues. Reproductive BioMedicine Online. 24: 377-380.

Hutchinson J.C.D & Brown G.D. 1969. Penetrance of cattle coats by radiation. Journal of Applied Physiology. 26(4): 1-11.

Hutchinson J.C.D & Sykes A.H. 1953. Physiological acclimatization of fowls to a hot humid environment. The Journal of Agricultural Science. 43(03): 294-322.

Ju J.C. 2005. Cellular responses of oocytes and embryos under thermal stress: hints to molecular signaling. Animal Reproduction. 2(2): 79-90.

Kadzere C.T., Murphy M.R., Silanikove N. & Maltz E. 2002. Heat stress in lactating dairy cows: a review. Livestock Production Science. 77: 59-91.

Krihara M. & Shioya S. 2002. Dairy cattle management in a hot environment. 1-9. Access: https://www.fftc.org.tw/htmlarea_file/library/20110801153254/eb529.pdf.

Kutlu B. & Varisli O. 2012. The Pregnancy rate of cattle, which was inseminated in different season in Sanliurfa. Harran Üniversitesi Üniversitesi Veteriner Fakültesi Dergisi. 1(2): 97-102.

Lopes F.F.D.P., Lima R.S., Risolia P.H.B., Ispada J., Assumpção M.E.O. & Visintin J.A. 2012. Heat stress induced alteration in bovine oocytes: functional and cellular aspects. Animal Reproduction. 9(3): 395-403.

López-Gatius, F. & Hunter, R.H.F. 2017. Clinical relevance of pre-ovulatory follicular temperature in heat-stressed lactating dairy cows. Reproduction in Domestic Animals. 52: 366-370.

López-Gatius F. & Hunter R.H.F. 2019. Pre-ovulatory follicular temperature in bi-ovular cows. Journal of Reproduction and Development. 65: 191-194.

López-Gatius F. & Hunter R.H.F. 2019. Pre-ovulatory follicular cooling correlates positively with the potential for pregnancy in dairy cows: Implications for human IVF. Journal of Gynecology Obstetrics and Human Reproduction. 48: 419-422.

Naranjo-Gómez J.S., Uribe-García H.F., Herrera-Sánchez M.P., Lozano-Villegas K.J., Rodríguez-Hernández R. & Rondón-Barragán I.S. 2021. Heat stress on cattle embryo: gene regulation and adaptation. Heliyon. 7(3): e06570.

Negron-Perez V.M., Fausnacht D.W. & Rhoads M.L. 2019. Invited review: Management strategies capable of improving the reproductive performance of heat-stressed dairy cattle. Journal of Dairy Science. 102: 10695-10710.

Paes V.M., Vieira L.A., Correira H.H.V., Sa N.A.R., Moura A.A.A., Sales A.D., Rodrigues A.P.R., Magalhaes-Padilha D.M., Santos F.W., Apgar G.A., Campello C.C., Camargo L.S.A. & Figueiredo J.R. 2016. Effect of heat stress on the survival and development of in vitro cultured bovine preantral follicles and on in vitro maturation of cumulus-oocyte complex. Theriogenology. 86: 994-1003.

Petyim S, Bage R, Forsberg M, Rodriguez-Martinez, H. & Larsson B. 2001. Effects of repeated follicular puncture on ovarian morphology and endocrine parameters in dairy heifers. Journal of Veterinary Medicine Series A. 48: 449-463.

Polsky L. & von Keyrerlink M.A.G. 2017. Invited review: effects of heat stress on dairy cattle welfare. Journal of Dairy Science. 100: 8645-8657.

Razza E.M., Pedersen H.S., Stroebech L., Fontes P.K., Kadarmideen H.N., Callesen H., Pihl M., Nogueira F.G. & Hyttel P. 2018. Simulated physiological oocyte maturation has side effects on bovine oocytes and embryos. The Journal of Assisted Reproduction and Genetics. 36(3): 413-424.

Renaudeau D., Collin A., Yahav S., De Basilio V., Gourdine J.L. & Collier R.J. 2012. Adaptation to hot climate and strategies to alleviate heat stress in livestock production. Animal. 6(5): 707-728.

Rispoli L.A., Lawrence J.L., Payton R.R., Saxton A.M., Schrock G.E., Schrick F.N. & Edwards J.L. 2011. Disparate consequences of heat stress exposure during meiotic maturation: embryo development after chemical activation vs fertilization of bovine oocytes. Reproduction. 142(6): 831-843.

Rocha A., Randel R.D., Broussard J.R., Lim J.M., Blair R.M., Roussel J.D., Godke R.A. & Hansel W. 1998. High environmental temperature and humidity decrease oocyte quality in Bos taurus but not in Bos taurus cows. Theriogenology. 49(3): 657-665.

Roth Z. 2008. Heat stress, the follicle, and its enclosed oocyte: mechanisms and potential strategies to improve fertility in dairy cows. Reproduction in Domestic Animals. 43: 238-244.

Roth Z., Arav A., Bor A., Zeron Y., Braw-Tal R. & Wolfenson D. 2001. Improvement of quality of oocytes collected in the autumn by enhanced removal of impaired follicles from previously heat-stressed cows. Reproduction.122(5): 737-744.

Roth Z. 2018. Symposium review: Reduction in oocyte developmental competence by stress is associated with alterations in mitochondrial function. Journal of Dairy Science. 101(4): 3642-3654.

Rust J.M. 2019. The impact of climate change on extensive and intensive livestock production systems. Animal Frontiers. 9(1): 20-25.

Sakatani M., Yamanaka K., Balboula A.Z., Takenouchi N. & Takahashi M. 2015. Heat stress during in vitro fertilization decreases fertilization success by disrupting anti-polyspermy systems of the oocytes. Molecular Reproduction and Development. 82(1): 36-47.

Souza-Cácares M.B., Fialho A.L.L., Silva W.A.L., Cardoso C.J.T., Pöhland R., Martins M.I.M. & Melo-Sterza F.A. 2019. Oocyte quality and heat shock proteins in oocytes from bovine breeds adapted to the tropics under different conditions of environmental thermal stress. Theriogenology. 130: 103-110.

Tao S. & Dahl G.E. 2013. Invited review: Heat stress effects during late gestation on dry cows and their calves. Journal of Dairy Science. 96(7): 4079-4093.

Van Zanten H.H., Herrero M., Van Hal O., Röös E., Muller A., Garnett T., Pierre J.G., Schader C. & De Boer I.J. 2018. Defining a land boundary for sustainable livestock consumption. Global Change Biology. 24(9): 4185-4194.

Wang J., Li J., Wang F., Xiao J., Wang Y., Yang H., Li S. & Cao Z. 2020. Heat stress on calves and heifers: a review. Journal of Animal Science and Biotechnology. 11: 79.

Wankar A.K., Rindhe S.N. & Doijad N.S. 2021. Heat stress in dairy animals and current milk production trends, economics, and future perspectives: the global scenario. Tropical Animal Health and Production. 53(70): 1-12.

Wilson S. J., Mairon R.S., Spain J.N. Spe,iers D.E. Keisler D.H. & Lucy M.C. 1998. Effects of controlled heat stress on ovarian function of dairy cattle. Lactating cows. Journal of Dairy Science. 81(8): 2124-2131.

Arquivos adicionais

Publicado

2022-04-18

Como Citar

Çizmeci, S. Ülküm, Dinç, D. A., Yesilkaya, O. F., Çiftçi, M. F., Takcı, A., & Bucak, M. N. (2022). Effects of Heat-Stress on Oocyte Number and Quality and In Vitro Embryo Production in Holstein Heifers. Acta Scientiae Veterinariae, 50. https://doi.org/10.22456/1679-9216.122371

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v. 50 (2022): ARTICLES

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Articles

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Copyright (c) 2022 Sakine Ülküm ÇİZMECİ, Dursun Ali Dinç, Omer Faruk Yesilkaya, Muhammed Furkan Çiftçi, Abdurrahman Takcı, Mustafa Numan Bucak

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