Indian Journal of Animal Research

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Indian Journal of Animal Research, volume 58 issue 9 (september 2024) : 1435-1443

The Potential Impacts of Selecting Viable Oocytes on Further Embryonic Development in Mammals: A Review

A.A. Mohammed1,*, S. Al-Suwaieg1, I. AlGherair1, A. Mohammed2, A. Mohammed2
1Department of Animal and Fish Production, College of Agriculture and Food Sciences, King Faisal University, P.O. Box 402, Al-Ahsa 31982, KSA.
2College of Human Medicine, Assiut University, Egypt.
Cite article:- Mohammed A.A., Al-Suwaieg S., AlGherair I., Mohammed A., Mohammed A. (2024). The Potential Impacts of Selecting Viable Oocytes on Further Embryonic Development in Mammals: A Review . Indian Journal of Animal Research. 58(9): 1435-1443. doi: 10.18805/IJAR.BF-1789.

Selecting viable fully grown germinal and matured oocytes were positively effect on further embryonic development and live birth. The use of feed and hormonal supplementation and biotechnologies to enhance oocyte competence was evaluated. In addition, the oocytes were selected based on ovarian follicular stage, follicles and oocytes morphology, follicular fluid characters and gene expression. Changes were obtained in oocyte maturation, fertilization and further embryo cleavage and development over selecting viable oocytes. The larger follicle diameter, the translucent follicle and the higher blood supply the higher developmental competence of resulting oocytes. The higher surrounding cumulus cells and homogeneity of cytoplasm the higher developmental competence of oocytes. In addition, oocytes obtained during luteal stage compared to those obtained during follicular phase were highly or comparably developed to embryos. Furthermore, follicular fluid characters and gene expression might predict the embryonic developmental competence of oocytes in addition to their viable staining with brilliant cresyl blue. In conclusion, the characters of ovarian follicles, oocytes, follicular fluid and gene expression have significant implications on further oocyte developmental competence in different mammalian species.

Significant strides of progresses is achieved in selecting the higher developmental competence oocytes through the characters of ovarian follicles, oocytes morphology, follicular fluid and gene expression (Mohammed et al., 2005; Mlyczyńska et al., 2023). It has been known that several factors affect the ovarian follicle diameters and the contents of oocytes and follicular fluid parameters (Contreras-Solís et al.,  2021; Castro-Modesto et al., 2022; Mohammed et al., 2020, 2024a,b,c,d; Cañón-Beltrán et al.,  2024).

Oocyte developmental competence is gradually acquired during the processes of follicle growth and maturation (Al Zeidi et al., 2022a,b; Mohammed et al., 2022; Aljubran et al., 2023). Modification of follicle environment through the use of feed and hormonal supplementation and biotechnologies to enhance oocyte competence was confirmed in several studies (Gordon 2003; Costa et al., 2023; Mohammed et al., 2024a,b,c). Several studies concerning the nutrition and feed additives, hormonal supplementation indicated that they were pivotal factors in determining the ovarian follicle development and oocyte quality that resulted in varied reproductive performances in different animal species and human (Mohammed, 2018, 2019; Mohammed et al., 2022; 2024a,b,c,d; Ali et al., 2021; Al-Mufarji et al., 2022a,b; Mohammed and Al-Suwaiegh 2023; Al-Mafurji et al., 2023). Bragança et al. (2020) found that progestogen administered to sheep did not affect the pattern of ovarian first wave follicle populations and the resulting oocyte quality during ovarian stimulation with FSH. Primordial follicle activation and survival during in vitro culture of bovine ovarian tissue to control oxidative stress upon melatonin treatment was confirmed through different mechanisms (Silva et al., 2024). Lucia Dos Santos Silva et al. (2023) reviewed the role of antioxidants in prevention follicular damage caused by oxidative stress in the in vitro culture of preantral follicles. Therefore, our objectives were to highlight key aspects of nutrition, feed supplements and hormones on follicle and oocyte development in addition to selecting viable oocytes according to follicular and luteal cycle stages, morphology of follicles and oocytes, follicular fluid characters and gene expression (Fig 1-3).

Fig 1: Effects of nutrition on ovarian follicle development and oocyte quality.



Fig 2: Factors responsible for selection of viable oocytes.



Fig 3: Morphological, molecular and metabolic assessment of oocyte quality.



The current study was carried out according to the procedure approved by Deanship of Scientific Research, King Faisal University, Saudi Arabi from September to March 2024. The earlier reports concerning the effects of nutrition, feed supplements and hormones in addition to follicular and luteal stages on oocytes developmental competence were utilized. In addition, the research papers concerning follicle and oocyte morphology, follicular fluid and gene expression in addition to assisted reproductive techniques were reviewed and discussed for selecting viable oocytes, increasing outcomes of reproduction and treatment of infertility. Therefore, our targets are to highlight key aspects of nutrition, feed supplements and hormones on follicle and oocyte development followed by selecting viable oocytes based on follicular and luteal estrous stages, morphology of follicles and oocytes, follicular fluid characters and gene expression.

Most reproduction management technologies and interventions are centered on the ovarian follicle development and the contents of oocytes and follicular fluid.
 
Nutrition and supplements
 
A plethora of molecules modified by the nutritional intake as amino acids, pyruvate, fatty acids, inorganic ions, second messengers, cytokines, growth factors effect on ovarian follicle development, oocyte quality, maturation and further embryonic development and live birth in different mammalian species (Mohammed, 2018, Mohammed et al., 2020, 2024a,c; Hye et al., 2020; Thuy Van et al., 2020; Fabozzi et al., 2021; Costa et al., 2023; Garza et al., 2023; Silva et al., 2023; Liu et al., 2024).

Protein played a crucial role in both follicle growth and development and the quality of resulting oocytes (Dupont et al., 2014; Gao, 2020; Rubio et al., 2021; Machado et al., 2020). Amino acids served as building blocks for protein synthesis that were essential for follicles’ growth and development, granulosa cell proliferation and oocyte quality. Protein in the oocyte was used for synthesis of RNA and to store materials for sustaining future embryo development until maternal zygotic transition or genome activation, which occured in most of mammalian species between the two- to the eight-cell stages (Li et al., 2013). In addition, certain proteins function as antioxidants,  protecting follicles and oocytes from oxidative stress, which damage DNA and impair their development. On the other hand, unbalanced protein diet resulted in alterations of structure, function and biogenesis with increased levels of reactive oxygen species (Schutt et al., 2019).

Carbohydrates were essential sources of energy for the body function including the reproductive system (Dupont et al., 2014; Fabozzi et al., 2021). Ovarian follicular growth and development and oocytes require a readily available supply of energy through carbohydrates. Report of Mohammed et al. (2021) indicated accelerated and higher development of ovarian follicle with propylene glycol supplementation. On the other hand, the potential negative effects of high carbohydrate intake over increased oxidative stress and hormonal imbalances could be damaging to DNA and cellular components within the follicles and oocytes.

There are molecular mechanisms of functional fatty acids affecting follicular development, granulosa cell steroidogenesis and oocyte maturation (Zeng et al., 2023). There was a strong relationship between fat supplementation and follicle size and oocyte quality (Khatir et al., 2007; Yang et al., 2016; Labrecque et al., 2016). The unsaturated fatty acids yielded positive effects on reproductive performance but the saturated fatty acids were linked to negative outcomes as decreased follicle number and quality (Zeng et al., 2023). On the other hand, the negative effects of high-fat diets included increased inflammation and oxidative stress, hormonal imbalances and decreased blood flow (Dupont et al., 2014). Collectively, abnormal dietary consumption of carbohydrates, fatty acids, proteins, vitamins and minerals, had detrimental effects on ovarian functions, affecting not only the oocyte quality but also the quality of embryos and implantation of a healthy embryo (Noli et al., 2020).
 
Feed supplements
 
Effects of nutritive and non-nutritive feed supplements on reproductive performances in mammals has been discussed (Mohammed et al., 2024a,b). The nutritive and non-nutritive feed supplements change rumen microorganism, feed utilization, body weight gain, blood and plasma profiles (Mohammed et al., 2024a,b,c). Such improvements over feed supplement/s lead to improvement in ovarian follicle development and the resulting oocyte quality, embryos and newborns in addition to amelioration of reproductive dysfunctions (Al-Mafurji et al., 2022a,b).

The essential macronutrient and antioxidant micronutrient improved the reproductive performances through significant increase in concentrations of reproductive hormones, numbers and sizes of ovarian follicles in addition to increase in oocyte and embryo quality (Senosy et al., 2017, 2018, 2019; Mohammed, 2018; Ali et al., 2021). In addition, green algae as a source of beta-carotene was supplemented to support oocyte and embryo quality in goats  (Silva et al., 2023). The microalgae Chlorella did not enhance the quality of oocytes whereas it improved the quality of embryos and stimulated their mitochondrial function. Previous reports on Dunallela saliena resulted in improvement in levels of reproductive hormones, oocytes and embryo development and (Senosy et al., 2017; Mohammed, 2018; Ali et al., 2021). Therefore, the continuous research in nutritive and non-nutritive feed supplements was necessitated for both animals and humans. Therefore, the future prospective studies to find beneficial new feed additives was an emerging approach for improving ovarian structural development and the resulting quality of oocytes and embryos (Mohammed et al., 2024a,b,c,d).
 
Hormonal supplementation
 
Hormonal supplementation had various effects on ovarian follicle development, oocyte quality and embryo development, depending on the specific hormone, dosage and body health conditionin mammalian species (Gordon, 2003; Mohammed and Attaai, 2011). The important hormones related to ovarian follicular growth and maturation were follicle stimulating hormone, luteinizing hormone (LH), estrogen and progesterone. Follicle stimulating hormone (FSH) was used routinely in protocols of assisted reproductive techniques but excess FSH could lead to overstimulation and complications. Supplementation of LH and estrogen in specific contexts could support ovarian follicle and oocyte maturation but required careful management due to potential adverse effects. It was well-known that the physiological effects of progesterone during the pre-implantation stages of mammalian embryos was mediated by progesterone receptors and their gene expression. Although progesterone could not improve in vitro maturation rates, culture media supplemented with progesterone significantly improved mouse embryo development (Andersen, 1990; Mendoza et al., 2002; Gordon, 2003; Salehnia and Zavareh, 2013; Flores-Herrera et al., 2008). Growth hormone injection improved follicles and oocytes development in prepubertal lambs (Liu et al., 2023). Collectively, hormonal supplementation could be double-edgedto either give a positive or negative effect depending on several factors.
 
Follicular and luteal stage of the cycle
 
Ovarian follicles develop through two processes called initial and cyclic recruitments (McGee and Hsueh, 2000), which describe recruitment of dormant primordial follicles continuously into the growing follicle and antral follicles, respectively. After puberty, multiple antral ovarian follicular waves (2, 3 and 4 waves) were reported in several studies (Gordon, 2003; Baerwald and Pierson, 2020) during ruminant estrous or human menstrual cycles. It was estimated for bovine early antral follicles to take about 40 days to progress to preovulatory follicles.

The estrous cycle was divided to follicular and luteal phases (Gordon, 2003). Ovarian follicular waves or follicular and luteal stages were factors affecting the quality of oocytes, oocyte maturation and resulting embryo development (Mohammed et al., 2012, 2022). Some studies suggested that the estrous stage with its hormonal fluctuations can potentially influence oocyte quality in different mammalian species (Gordon, 2003; Majumdar et al., 2023; Dastjerdi et al., 2024). Some studies suggest higher oocyte quality in early follicular phase due to more favorable hormonal environment. Some other studies suggest negative impact of the corpus luteum on oocyte quality, particularly on smaller follicles.

Evidence concerning the importance of progesterone support during ovum pick-up and in vitro embryo production (OPU-IVP) was ascribed in studies related to transvaginal follicular aspiration in cattle and improvement of in vitro embryo production (Simmons et al., 2023). For treatment of fertility disorders, comparison of abnormalities during follicular phase in vitro maturation of oocytes compared with luteal phase in vitro maturation in women  was investigated (Hatirnaz et al., 2023). The results indicated differences in maturation and fertilization rates, quality of embryos or pregnancy outcomes between follicular phase and luteal phase in women with oocyte maturation abnormalities. Additionally, Suñol et al.,  (2023) compared follicular phase stimulation versus luteal phase stimulation in suboptimal women responders. The oocyte yield did not increase in follicular-phase stimulation compared to luteal-phase stimulation. De Wit et al., (2000) also found that the stage of oestrous cycle had no effect on the distribution of the cumulus-oocyte complexes (COC) over the grades of oocytes qualities or on the developmental capacity of COC. In human, stimulation of luteal phase in the same menstrual cycle was an effective strategy to rescue poor responders with follicular phase stimulation (Majumdar et al., 2023; Dastjerdi et al., 2024).
 
Morphology of follicles and quality of oocytes
 
The ovarian follicles are categorized to different groups including primordial follicles to preantral follicles and antral ovulatory follicles (Gordon, 2003) (Fig 4-5). Healthy antral follicles larger than 3 mm contain competent oocytes that are competent to develop into preimplantation and post implantation embryos (Mohammed et al., 2005). The sizes of ovarian follicles were different among mammalian species. They are categorized into small (<3 mm), medium (3-5 mm) and large follicles (>5 mm) in small ruminant species (Senosy et al., 2017; Al-Mufarji et al., 2023). Sizes of ovulatory follicles naturally resulted in multiple ovulations and influenced on the development of corpus luteum and fertility in cattle (Echternkamp et al., 2009).

Fig 4: Mouse ovary containing preantral and antral follicles.



Fig 5: Translucent ovarian follicles in sheep ovaries.



The effect of follicle size on oocyte quality was a complex issue and generally a positive correlation was noted between follicle size and oocyte quality. Large ovulatory follicles (≥16 mm) are more likely to yield mature oocytes that are capable of normal fertilization and development into high-quality embryos compared to small follicles (<13 mm) which produced immature oocytes with lower fertilization and cleavage rates in large ruminant species and humans as well (Kahraman et al., 2017). However, the relationship between follicle size and oocyte quality was not always clear and there could be exceptions where the age, follicular waves and health conditions, could also play a role in oocyte quality. Therefore, more research was needed to fully understand the complex interplay between follicle size and oocyte quality. Studies have shown that oocytes from larger follicles have higher fertilization rates and better competence for embryonic development (Mohammed unpublished report).
 
Follicular fluid characters
 
The correlation between follicular fluid characteristics and oocyte quality was complex and interesting field of research, with promising potential for improving assisted reproductive technologies (Mohammed et al., 2005, 2020). Follicular fluid (FF) surrounds the oocyte within the ovarian follicle and provides a crucial microenvironment for growth and development of the oocyte. Analyzing the chemical composition of FF offered insights into the ovarian follicle health and viability of the resulting oocyte (Mohammed et al., 2005; 2019a,b, 2020). Several studies had identified positive correlations between specific molecules in follicular fluid and oocyte quality such as insulin-like growth factors (IGFs) and their binding proteins (IGFBPs), which were often associated with higher maturation and fertilization rates of oocytes (Mohammed et al., 2019a). In addition, the higher levels of total antioxidant capacity (TAC) in follicular fluid seemed to indicate the presence of high quality oocytes in mature follicles. Furthermore,  metabolites and certain cytokines have also shown promising connections to oocyte quality (Mohammed et al., 2019a,b; 2020).

Follicular fluid composition changed during the estrous cycle due to follicular growth and development and nutritional level as well (Mohammed et al., 2012). Other components still need further studies to define the changes at cellular level (Mohammed et al., 2019b). Finally, the research on the correlation between follicular fluid characteristics and oocyte quality was promising but still evolving due to differences in experimental design, animal species and the analytical methods used (Mohammed et al., 2020).
 
Gene expression
 
Complex relationship was noted between gene expression and oocyte quality. Gene expression in oocytes was influenced by intrinsic and extrinsic factors (Jentoft et al., 2023). The intrinsic factors include genetic encoding, age of female and epigenetic modifications. The extrinsic factors include follicular environment, maternal health, environmental factors and in vitro culture conditions during assisted reproductive techniques.

Functional molecules were produced through gene expression at different stages of oocyte development that played crucial roles in various processes (Maside et al., 2021). Gene expression regulated various aspects of oocytes including zona pellucida formation, spindle apparatus development, enzymes and molecules involved in energy production and utilization, molecules involved in the communication of oocyte with the surrounding cells (Wassarman and Litscher, 2021). For example, the zona pellucida genes encode sperm receptors, which were required for fertilization (Evsikov et al., 2009). The nutritional factors such as protein or lipids helped in regulation of gene expression in developing follicles and oocytes, influencing various processes crucial for successful development and maturation (Schutt et al., 2019; Sharma et al., 2020; Alves et al., 2021).
Nutritive and non-nutritive feed additives/supplements and hormonal injection are positively or negatively effect on ovarian follicle development and the resulting oocytes. Selecting viable oocytes was necessitated for assisted reproductive technology, which could be according to follicular and luteal phases of the estrous cycle, morphology of follicles and oocytes, follicular fluid characters and gene expression. Therefore, the future prospective studies to find newer methods for selection of viable oocytes was a continuous approach for improving reproductive performances.
The authors want to thank and acknowledge Deanship of Scientific Research, King Faisal University, Saudi Arabia for funding and support (GrantA055).
There is no conflict of interest for authors to declare.

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  47. Mohammed, A.A., AlGherair I., Al-Suwaiegh S., Al-Khamis S., Alessa, F., Al-Madni, A. and Al-Ghamdi, A. (2024a). Effects of nutritive and non-nutritive feed supplements on feed utilization, growth and reproductive performances in mammals. Indian Journal Animal Research. doi: 10.18805/ IJAR.BF-1744.

  48. Mohammed, A.A., Al-Hizab, F., Al-Suwaiegh, S., Alshaheen, T., Kassab, A., Hamdon, H., Senosy, W. (2021). Effects of propylene glycol on ovarian Restoration, reproductive performance, metabolic status and milk production of farafra ewes in subtropics. Fresenius Environmental Bulletin. 30(7): 8192-8202.

  49. Mohammed, A.A., Al-Saiady, M., El-Waziry, A., Alshaheen, T. (2024d). Effects of dietary omega-3 fatty acids on reproductive performance and biochemical parameters of lactating cows in arid subtropics. Pakistan Journal of Zoology. (Accepted). 

  50. Mohammed, A.A., Al-Shaheen, T., Al-Suwaiegh, S. (2019a). Changes of follicular fluid composition during estrous cycle: The effects on oocyte maturation and embryo development in vitro. Indian Journal of Animal Research. 54(7): 797- 804. doi: 10.18805/ijar.B-1030.

  51. Mohammed, A.A., Al-Shaheen, T. and Al-Suwaiegh, S. (2020). Effects of Myo-inositol on physiological and reproductive traits through blood parameters, oocyte quality and embryo transfer in mice. Indian Journal of Animal Research.  doi: 10.18805/ijar.B-1300.

  52. Mohammed, A.A., Al-Suwaiegh, S., AlGherair, I., Al-Khamis, S., Alessa, F., Al-Awaid, S., Alhujaili, W.F., Mohammed, A., Mohammed, A. (2024b). The potential impacts of antioxidant  micronutrients on productive and reproductive performances of mammalian species during stressful conditions in mammals. Indian Journal Animal Research. doi: 10.18805/ IJAR.BF-1773.

  53. Mohammed, A.A., Al-Suwaiegh, S., AlGherair, I., Al-Khamis, S., Al- Awaid, S., Al-Sornokh, H., Alhujaili, W.F., Mohammed, A., Mohammed, A. (2024c). Morphological characteristics of ovarian tissues and follicular fluid metabolites of female lambs and ewes in subtropics. Indian Journal Animal Research. doi: 10.18805/IJAR.BF-1756. 

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