Bisphenol A (BPA), an endocrine-disrupting chemical, has received tremendous attention in the past few decades because of its detrimental health effects. Growing evidence supports that BPA is capable to alter the reproductive performance of the exposed individual. In spermatozoa, it has been reported that BPA increased oxidative stress by the overproduction of reactive oxygen species (ROS), subsequently affects the sperm function, biochemical properties, and fertility. Since antioxidants minimize cellular oxidative stress, therefore may have protective effects against BPA-induced stress. In the present study, we incubated mice spermatozoa for 6 h in a condition that support in vitro fertilization. The sperm incubation media was additionally supplemented with either BPA or BPA together with antioxidants, such as glutathione, vitamin C, and vitamin E. Our results showed that antioxidant significantly decreased the production of ROS that subsequently supports motility and acrosomal integrity of BPA-exposed spermatozoa. Particularly, glutathione and vitamin E inhibit protein kinase-A dependent phosphorylation of sperm proteins subsequently prevented precocious acrosome reaction. In addition, both antioxidants were found to restore fertilization and early embryo development potentiality of BPA-exposed spermatozoa. Therefore, we conclude that antioxidants minimize oxidative stress in spermatozoa in a BPA containing micro-environment, thus avoiding BPA-mediated harmful consequences. The current finding has both theoretical and clinical significance for developing potential remedies of the BPA toxicity.

The ability of conventional semen analysis to predict male fertility is questionable. Since the prediction of male fertility is extremely of importance for the artificial insemination and profitable farm managements in animals, the development of highly sensitive biomarker of male fertility is a prime concern. Porcine Seminal Protein I (PSP-I) and Porcine Seminal Protein II (PSP-II) have been known that they are related with motility, and viability of spermatozoa. Thus, we investigated PSP-I and PSP-II level in boar spermatozoa to predict boar’s fertility. The expressions of PSP-I and PSP-II in spermatozoa from 21 individual boars with different fertility and litter size (litter size ranges from 10.3 – 14.2) were examined using qRT-PCR. Litter size was determined in 530 saws after artificial insemination (AI). In addition, sperm motility, motion kinematics, and capacitation status were measured using computer-assisted sperm analysis and Hoechst 33258/chlortetracycline fluorescence staining, respectively. PSP-I and PSP-II showed significantly negative correlation with litter size (r=0.578; P=0.006 and r=0.456; P=0.038, respectively). Furthermore, receiver-operating curves (ROC) was used to determine the accuracy for the prediction of boar fertility. Therefore we divided into 2 groups based on the median value of litter size. When selecting higher litter size group, PSP-I can predict litter size with overall accuracy 90.48% (sensitivity 88.89, specificity 91.67, negative predictive value 91.67, and positive predictive value 88.89) and PSP-II can predict with overall accuracy 81.82% (sensitivity 55.56, specificity 100.00, negative predictive value 76.47, and positive predictive value 100.00). Interestingly, PSP-I and PSP-II were found to increase 0.76 pups than average litter size (average 12.48) in tested boars. To best of our knowledge, this study is the first trial to investigate the correlation between PSP-I, PSP-II, and litter size. Therefore, we suggest that PSP-I and PSP-II could be considered as promising biomarkers for predicting male fertility and litter size outcome in field condition.

Bisphenol‒A (BPA) is a known endocrine‒disrupting chemical used extensively to manufacture plastic bottles, canned food linings, thermal receipts, and other commonly used items. BPA is capable of inducing chromosomal alterations in germ cell line, thereby produced transgenerational effects on brain function, social recognition, reproductive diseases, sperm quality, gene expression, and obesity. Here, we aimed to investigate the transgenerational effects of BPA on murine male fertility. Six-week-old male mice (F0) were gavaged with corn oil (control), two different doses of BPA (5 mg, and 50 mg·kg bw-1·day-1),andethinylestradiol(EE,0.4mg·kg bw-1·day-1), dailyfor6weeks. Treated male mice were mated with wild‒type female and sibling pairs were bred up to the third generation (F3) in a similar manner with no further BPA exposure. Testes and spermatozoa were collected from 14-week-old males of all generation (F0 to F3) to evaluate testis weight, sperm function, and fertility. We found that high concentration of BPA significantly increased testicular weight in F2. Although the sperm viability, capacitation status, and intracellular ROS levels were not affected by BPA, however, sperm count, motility, hyperactivated motility, and intracellular ATP levels were significantly altered by BPA, dose dependently. In majority of the cases the effects were prominent in F2 followed by F1 and F0, whereas the effects were diminished in F3 generation. Simultaneously, high concentration of BPA significantly decreased cleavage and blastocyst formation rate in both F1 and F2. Similar inhibitory effects on cleavage and blastocyst were also noted in F1 by low dose of BPA. Depending on these findings we conclude that BPA decreases the fertility potential of exposed males and has an adverse impact on sperm function and fertility in subsequent generations.