Tributyltin chloride alters the structural, genomic, and epigenomic integrity of postejaculatory mammalian sperm

Nurture vs nature: how can we optimize sperm quality?

Sperm cryopreservation offers a long-term preservation of male genetic materials for future assisted reproductive technologies. However, dramatic changes in temperature during freezing and thawing injure sperm cells. While motility is essential for AI and membrane integrity is crucial for in vitro fertilization (IVF), sperm DNA integrity is a common index of fertilizing capability required for AI, IVF and intracytoplasmic sperm injection (ICSI). In endangered felids died unexpectedly, attempts have been made to recover as many DNA intact spermatozoa as possible from epididymis and testis to increase the opportunity to produce offspring in future. Although sperm from caudal epididymis has shown retained fertilizing capability after freezing and thawing (27.3% conception rate after unilateral intrauterine insemination), sperm recovery from the corpus epididymis has been suggested as an alternative to increase the amount of preserved genetic materials. To improve epididymal sperm quality, pre-treatment with single-layer centrifugation resulted in selection of sperm cells with intact DNA while post-thaw treatment with extracellular ATP incubation promoted the blastocyst rate. Cold storage of domestic cat testis for 7days at 4°C demonstrated <1% of sperm cells with fragmented DNA. Moreover, isolated testicular sperm cells, stored for 7days at 4°C, produced after ICSI poorer percentages of cleavage, morula and blastocyst than the fresh control. In wild felids, a death-to-necropsy time of 2hr after a jungle cat (Felis chaus) aged 10years died during anaesthesia plus another necropsy-to-sperm recovery time of 25hr has been reported to yield the post-thawed testicular sperm with 22.2% intact DNA. In summary, the chromatin structure of feline ejaculated and epididymal sperm seems to be tolerated to cold storage and cryopreservation; thus, fertilizing capability is well protected. In contrast, the cat testicular sperm DNA is generally damaged through the cryopreservation.

Sperm cyropreservation and oxidative damage. What does it mean?

BackgroundSperm freezing and cold storage are the two most common assisted reproductive technologies in the canine breeding industry. The freeze-thawing process causes significant detrimental changes in both sperm cell structure and function. Previous research has confirmed that excessive accumulation of un-scavenged free radicals (oxidative stress) plays an important role in the cryopreservation-induced damage to sperm cells. Also, the gradual accumulation of the free radicals during cold storage leads to a decline in the sperm quality markers. Melatonin is an endogenous neurohormone synthesized from tryptophan amino acid by pineal glands. Besides its several well-known physiologic roles, melatonin has a significant antioxidant potential through direct free radical scavenging properties. Therefore, the current study was designed to evaluate the potential in vitro protective properties of melatonin (0.5, 1, and 2 mM) on canine sperm cells after freezing or during long-term cold storage (9 days, 5 °C) on most important sperm in vitro fertility markers.ResultsMelatonin at 0.5, 1- or 2-mM concentrations could preserve significantly higher sperm total motility after 4 days of cold storage. However, only the 1- and 2 mM melatonin concentrations could result in better TM and PM values after 7 days of cold storage. Furthermore, melatonin supplementation could preserve higher sperm viability and acrosome integrity after 7 days of storage. Also, it could have significant protective effects on the cooled sperm DNA integrity. In the freezing section of the current research, melatonin at either 1- or 2-mM concentrations could not improve the sperm post-thaw TM and PM, whereas they improved sperm DNA integrity. Also, the post-thaw plasma membrane functional integrity and sperm velocity parameters were not affected by the treatment. Although DMSO (Dimethyl Sulfoxide) as the melatonin solvent could reduce the level of sperm lipid peroxidation and even improve the post-thaw sperm DNA integrity compared to the negative control, it reduced the post-thaw sperm progressive motility. However, the negative effects were reversed by concurrent melatonin supplementation at 1- and 2-mM concentrations.ConclusionThe addition of 1- or 2-mM melatonin to the canine sperm freezing and cooling media could improve sperm motility, viability, acrosome, and DNA integrity.

Studies examining the influence of seminal plasma on sperm function have shown both beneficial and detrimental effects. However, its effect on pre-frozen bovine epididymal sperm (BES) has not been documented. The objective of this study was to determine the effect of a 30-min incubation of BES in bovine seminal plasma (SEMP) prior to freezing on post-thaw sperm parameters. Paired testes were obtained from mature bulls (n = 10) at a local abattoir and transported to the laboratory (25–28°C) within 3–5 h postmortem. BES were harvested by multiple incisions from the caudae epididymides of each bull, pooled, and split into either Treatment A, 3 mL of egg yolk Tris-based medium (EYT) (No SEMP), or Treatment B, 3 mL of SEMP, each for 30 min in a 37°C water bath. SEMP was extracted from ejaculates of mature bulls (n = 6), and then pooled and stored at −20°C until used. Sperm from both treatments were re-suspended in EYT, adjusted to 70 × 106 sperm mL−1 and cooled to 4°C at 0.1°C min−1. Samples were diluted slowly over a 30-min period with 1:1 EYT medium containing 14% glycerol and loaded into 0.5-mL straws. Straws were frozen in liquid nitrogen vapors. For sperm analyses, straws were thawed in a water bath at 37°C for 40 s. Morphology was determined by staining with eosin-nigrosin. Viability and acrosome integrity were measured simultaneously with the combination of SYBR 14, propidium iodide, and PE-PNA. Mitochondrial activity was measured by the combination of MitoTracker Red and SYBR 14. DNA integrity was determined by acridine orange using the sperm chromatin structure assay (SCSA®; SCSA Diagnostics, Inc., Brookings, SD, USA). All assays were performed by multicolor flow cytometry. Differences between treatments were analyzed using one-way ANOVA (P &amp;lt; 0.05). In summary, all sperm quality parameters decreased significantly after thawing in both treatments (Table 1). A significantly higher overall and progressive motility post-thaw was achieved when sperm were incubated in SEMP prior to freezing. However, no difference was detected in sperm viability, acrosome integrity, mitochondrial activity, and DNA integrity between treatments. Also, SEMP reduced the quantity of distal droplets and broken tails post-thaw over that of no SEMP. Results indicate that incubation of BES in bovine seminal plasma prior to freezing improves post-thaw sperm quality. Table 1. Effect of bovine seminal plasma (SEMP) on quality parameters (mean ± SEM) of post-thaw bovine epididymal sperm

Study question Do common chemicals in plastic, BPAF and DBP, negatively impact sperm parameters and DNA integrity, and can oral antioxidant supplementation mitigate their impact? Summary answer Short-term, low-dose exposure to BPAF or DBP did not impact testicular/epididymal histology but caudal epididymal sperm parameters, particularly DNA integrity was significantly compromised. What is known already Plasticizers are among the most commonly produced chemicals worldwide with 90% of people showing detectable levels in their urine. As endocrine disruptors (EDCs), they act as estrogen mimetics but can also induce oxidative stress and form DNA adducts. Numerous studies have linked exposure to EDCs to impaired spermatogenesis, sperm DNA damage and male infertility. Limited studies suggest antioxidants may alleviate the reproductive toxicity of EDCs. This study measured the effects of short-term exposures to two common environmental EDCs (BPAF &amp; DBP) on the post-testicular compartment epididymis and investigate the efficacy of an oral antioxidant supplement to safeguard sperm DNA integrity. Study design, size, duration Adult male CD1 mice were exposed to low doses (50mg/kg) of BPAF or DBP with or without co-administration of antioxidant supplementation (Fertilix®) for 14 days and evaluated after euthanasia. Participants/materials, setting, methods All experiments were performed at the University Clermont Auvergne, Clermont-Ferrand, France. Mice were supplemented with BPAF, DBP or/and Fertilix® in their drinking water. The results of exposure of males were evaluated against controls and included: testicular and epididymal histology, epididymal ROS status via 4-HNE levels in caput protein extracts, general semen parameters: (count, motility, viability, acrosome integrity), sperm nuclear/DNA parameters [decondensation (Toluidine blue stain), fragmentation (TUNEL test), oxidation (8-OHdG residue level)]. Main results and the role of chance The histology of the testis and epididymis was unaffected by the exposure conditions used. An oxidative stress situation was evident by the EDC exposures, demonstrated by increased level of 4-HNE adducts in the epididymal caput protein extracts. Viability, total and progressive motility, and acrosome integrity of caudal epididymal spermatozoa remained unaltered in exposed animals compared with controls. Exposure to BPAF but not DBP significantly decreased sperm count. Sperm nuclear/DNA integrity assessed by the percentages of sperm with decondensed and oxidized nuclei was significantly increased in EDC-exposed animals. Sperm DNA fragmentation did not significantly increase in any group of exposed animals. Co-administration with Fertilix® significantly corrected the defective sperm parameters (nuclear decondensation and DNA base oxidation) with the exception of sperm count which did not return to control levels in BPAF+ Fertilix® treated animals. These data confirm that even at low doses and short-term exposures, epididymal spermatozoa are susceptible to DNA damage induced by environmental ROS-generating EDCs, confirming its association with male infertility. Limitations, reasons for caution The translation of these findings to humans needs to be confirmed, although the nuclear compartment of human sperm is more susceptible to oxidative alterations than that of the mouse. Wider implications of the findings These data demonstrate the susceptibility of post-testicular sperm cells to common environmental chemicals. They also support the use of appropriate antioxidant supplementation as an effective therapeutic choice for individuals with multiple exposures to environmental stressors such as ROS-generating EDCs. Trial registration number not applicable

Novel technologies for selecting the best sperm for in vitro fertilization and intracytoplasmic sperm injection

Famotidine, a histamine-2 receptor antagonist, is commonly used to relieve the acid-related gastrointestinal diseases; however, its effect on human sperm parameters, and hence on sperm function, is still undetermined. Here, we intended to measure human sperm motility, viability, and DNA integrity of ejaculated human sperm in the presence of famotidine at 0, 0.1, 1 and 10mM concentrations in vitro. Forty-nine semen samples of normal count, motility, and morphology were included in this study. Sperm motility was assessed using Makler counting chamber and a phase contrast optics (200× magnification), whereas sperm viability was assessed using eosin-nigrosin staining procedure. The effect of famotidine on sperm DNA integrity was measured using flow cytometry. Famotidine at 0.1, 1 or 10mM had insignificant effect on human sperm motility (progressive, p=.9594; and total, p=.8420), sperm viability (p=.6471), and content of DNA breaks in sperm (p>.05) compared with the control. In conclusion, famotidine at 0.1, 1 or 10mM did not alter human sperm motility, viability or DNA integrity in vitro. Although, these findings indicate safety of famotidine in human sperm, further in vivo studies are required to establish the drug's safety.

The determination of reproductive safety in men during and after cancer treatment

Egg yolk has been reported to have a beneficial effect on sperm quality following cryopreservation, and this led to its widespread use in semen extenders. However, egg yolk contains substances that inhibit respiration of sperm cells and diminish their motility rate. Moreover, it also contains low-density lipoproteins (LDL) that have a protective effect on sperm during the cryopreservation process. The objective of this study was improve cryopreservation of Nguni bull semen using egg yolk low-density protein. A total of 25 ejaculates were collected from 5 Nguni bulls aged 4 to 5 years using an electroejaculator during the natural breeding season. Collected raw semen samples were transported to the laboratory and evaluated for sperm motility, viability, plasma membrane, acrosome, and DNA integrity before dilution. Semen was randomly diluted with a sodium citrate extender supplemented with 20% egg yolk (control) and with 6, 8, 10, and 12% LDL concentrations. The diluted semen sample groups were equilibrated for 4h at 5°C. Following equilibration, semen was loaded into 0.25-mL straws and frozen in a controlled-rate programmable freezer. The groups of semen straws were then plunged into LN and transferred into LN tanks (−196°C) for storage. The frozen semen straws per treatment group were thawed at 37°C and evaluated for sperm motility, viability, plasma membrane, acrosome, and DNA integrity. Data were analysed with ANOVA using Stata V12 statistical software (StataCorp., College Station, TX), and treatment means were separated using Fisher’s protected t-test at the significant level of P&amp;lt;0.05. Sperm motility and membrane integrity were significantly higher (P&amp;lt;0.05) in frozen-thawed semen diluted with 8% LDL compared with the other concentrations. However, 6 and 8% LDL resulted in a significantly higher (P&amp;lt;0.05) live sperm, DNA, and acrosome integrity. Frozen-thawed semen diluted with 10 and 12% LDL resulted in the lowest percentages of sperm motility, live sperm, plasma membrane, acrosome, and DNA integrity following cryopreservation. In conclusion, extender containing 8% LDL resulted in improved Nguni bull semen parameters such as sperm motility, viability, plasma membrane, acrosome, and DNA integrity following cryopreservation. Further studies are required to determine the fertilizing capacity of semen diluted and frozen with LDL in vitro and in vivo.

Seminal oxidative stress occurs when there is an increased production of reactive oxygen species (ROS) and/or a decrease of antioxidant activity, promoting impaired sperm function. Peroxiredoxins (PRDX) are abundant in human semen and are important antioxidant enzymes, which act as ROS scavengers and modulators in ROS-dependent signaling. Our aim was to determine whether the levels of PRDX1 and PRDX6 and their oxidation on thiol groups are associated with a decrease in sperm motility and DNA integrity. We evaluated the sperm and seminal PRDX level in men (13 healthy controls, 15 men with clinical varicocele, and 17 men with idiopathic infertility). We assessed conventional semen parameters, sperm DNA integrity (by the sperm chromatin structure assay), lipid peroxidation in seminal plasma and spermatozoa (by the thiobarbituric acid reactive substances assay), and the amount and thiol oxidation of PRDX1 and PRDX6 (by immunoblotting). PRDXs were affected in seminal plasma (lower amounts) and in sperm samples (lower amounts and higher levels of thiol oxidation) characterized by lower sperm motility, higher lipid peroxidation, and sperm DNA damage. The thioloxidation ratio of PRDXs (thiol-oxidized PRDX/total PRDX) correlated negatively with sperm motility (total and progressive) and positively with sperm DNA damage and sperm lipid peroxidation. In conclusion, because of the lower amount of total PRDX1 and PRDX6 and the high thiol oxidation of these PRDXs, very little (less than 20%) protection due to PRDXs remains, and this is associated with impaired sperm function and poor DNA integrity and suggests an important role of PRDXs in the protection of human spermatozoa against oxidative stress.

Bovine sperm separation by Swim-up and density gradients (Percoll and BoviPure): Effect on sperm quality, function and gene expression

This study investigates the effect of freezing rates on the spermatological parameters of frozen and thawed Saanen goat semen. Equilibrated semen was frozen at 4 different freezing rates from +5 °C to -150 °C (G10: 10 °C/min, G12: 12 °C/min, G15: 15 °C/min, and G24: 24 °C/min) and stored in liquid nitrogen until use. Semen samples were examined for sperm motility, defective acrosomes (FITC-PSA), and DNA integrity using TUNEL after dilution with extender A at equilibration and postthaw stage. There was no significant difference among the freezing stages in terms of DNA fragmentation (P > 0.05). DNA integrity was partially affected by the freezing rate. The increase of freezing rate from 10 °C/min to 24 °C/min between +5 °C and -150 °C resulted in higher postthaw DNA damage. The study found that the freeze-thawing process is detrimental to postthawed goat semen motility (P 0.05). Although the freezing rates used in the present study had no effect on postthaw sperm motility and acrosome integrity (P > 0.05), sperm DNA integrity was affected.

Our aim was to evaluate the effect of neat semen vitrification on human sperm vital parameters and DNA integrity in men with normal and abnormal sperm parameters. Semen samples were 17 normozoospermic samples and 17 specimens with abnormal sperm parameters. Semen analysis was performed according to World Health Organization (WHO) criteria. Then, the smear was provided from each sample and fixed for terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) staining. Vitrification of neat semen was done by plunging cryoloops directly into liquid nitrogen and preserved for 7 days. The samples were warmed and re-evaluated for sperm parameters as well as DNA integrity. Besides, the correlation between sperm parameters and DNA fragmentation was assessed pre- and post vitrification. Cryopreserved spermatozoa showed significant decrease in sperm motility, viability and normal morphology after thawing in both normal and abnormal semen. Also, the rate of sperm DNA fragmentation was significantly higher after vitrification compared to fresh samples in normal (24.76 &plusmn; 5.03 and 16.41 &plusmn; 4.53, P = .002) and abnormal (34.29 &plusmn; 10.02 and 23.5 &plusmn; 8.31, P < .0001), respectively. There was negative correlation between sperm motility and sperm DNA integrity in both groups after vitrification. Vitrification of neat ejaculates has negative impact on sperm parameters as well as DNA integrity, particularly among abnormal semen subjects. It is, therefore, recommend to process semen samples and vitrify the sperm pellets.

BackgroundIn humans, it is now well documented that rising paternal age is correlated with decreased sperm DNA integrity and embryonic developmental failures. On the other side of the coin, it is also reported that very young fathers such as teenagers carry an increased risk of adverse birth outcomes. These observations suggest that, at least in humans, there is an age window for optimal sperm DNA integrity. In bovine, little is known about sperm DNA quality in young bulls and how it evolves with age. This study aimed to fill in this gap as it may be of importance for the bovine industry to know when exactly a bull is an optimal performer for reproductive programs.MethodsForty Nellore bulls were divided into three age groups: 1.8 to 2 years – young bulls; 3.5 to 7 years – adult bulls; and 8 to 14.3 years – aged bulls. Three ejaculates were collected from each bull, cryopreserved and evaluated for various parameters including: computer-assisted sperm analysis (CASA), plasma membrane and acrosome integrity, mitochondrial potential, sperm nuclear protamination, DNA oxidative damage, and Sperm Chromatin Structure Assay (SCSA).ResultsWe report here that young bulls presented superior values for motility, plasma and acrosomal membrane integrity, and high mitochondrial potential. However, they also presented higher values for sperm morphological abnormalities compared to adult and aged animal groups (p < 0.05). In addition, young bulls exhibited more defective protamination than older animals did. The oldest bulls showed more nuclear oxidative damage than the younger groups of bulls while both the young and aged groups were found more susceptible to DNA denaturation as revealed with the SCSA test (p < 0.05).ConclusionThese results indicate that young bulls spermatozoa best survived the freezing procedure, followed by adult and aged bulls. However, young and aged bulls were found to be more susceptible to DNA damage, respectively caused by protamine deficiency and oxidation. Therefore, although young bulls have correct semen parameters according to classical evaluation, our results indicate that they may show some structural nuclear immaturity.