Abstract
Hydrogen sulphide (H2S) is involved in the physiology and pathophysiology of different cell types, but little is known about its role in sperm cells. Because of its reducing properties, we hypothesise that H2S protects spermatozoa against the deleterious effects of oxidative stress, a condition that is common to several male fertility disorders. This study aimed i) to determine the total antioxidant capacities of Na2S and GYY4137, which are fast- and slow-releasing H2S donors, respectively, and ii) to test whether H2S donors are able to protect spermatozoa against oxidative stress. We found that Na2S and GYY4137 show different antioxidant properties, with the total antioxidant capacity of Na2S being mostly unstable and even undetectable at 150 µM. Moreover, both H2S donors preserve sperm motility and reduce acrosome loss, although the effects were both dose and donor dependent. Within the range of concentrations tested (3–300 µM), GYY4137 showed positive effects on sperm motility, whereas Na2S was beneficial at the lowest concentration but detrimental at the highest. Our findings show that Na2S and GYY4137 have different antioxidant properties and suggest that both H2S donors might be used as in vitro therapeutic agents against oxidative stress in sperm cells, although the optimal therapeutic range differs between the compounds.
Similar content being viewed by others
Introduction
Hydrogen sulphide (H2S) is the most recently discovered gaseous molecule that participates in a variety of biological functions, as do nitric oxide (NO) and carbon monoxide (CO). In mammals, H2S can be synthesised by enzymatic or non-enzymatic pathways1. Overall, it seems likely that most of the H2S produced within an organism is generated by the H2S-synthesising enzymes: cystathionine γ-lyase (CSE), cystathionine β-synthase (CBS), and 3-mercaptopyruvate sulphurtransferase (3-MST), with the latter coupled with cysteine aminotransferase (CAT)2.
In the male reproductive system, the expression of H2S-generating enzymes has been reported in the testis3,4, epididymis5, penile corpus cavernosum6, and spermatozoa7,8, which strongly suggests that this gasotransmitter is involved in sperm physiology to some extent. In a recent study, Wang et al. found that asthenospermic men show reduced levels of H2S in their seminal plasma and that exogenous H2S supplementation improves their sperm motility8. In contrast, in boar spermatozoa, H2S exerts no or negative effects on sperm motility, viability, and mitochondrial membrane potential9. With both positive and negative effects documented, there is still controversy concerning the role of H2S in sperm cells. This apparent discrepancy might, at least partly, be a result of H2S dose- and donor-dependent effects10.
According to their chemical structure and source, H2S donors include inorganic salts and derivatives of phosphorodithioate, garlic extracts, thioaminoacids, and anti-inflammatory drugs11. On the basis of their release mechanism, H2S donors can be classified in two categories: slow- and fast-releasing agents. Among the fast-releasing H2S donors, the inorganic salts sodium sulphide (Na2S) and sodium hydrosulphide (NaHS) are probably most frequently employed in biological studies. Both salts can be dissolved in aqueous solution, leading to an instantaneous release of H2S that mimics a bolus administration. Despite the common use of these donors in experimental studies, it is becoming increasingly clear that their gas release might not be representative of the physiological H2S levels in tissues and cells12. On the other hand, slow-releasing H2S donors, like the phosphorodithioate derivative GYY4137, produce a slow and continuous release of gas, which is more similar to the physiological conditions found within organisms12. For this reason, the use of different H2S donors in studies is useful to elucidate the biological activity and possible therapeutic effects12.
By virtue of its activity as a reducing agent, H2S attenuates the damage induced by oxidative stress in different cells and tissues (e.g. neurons13, gastric cells14, lung cells15). Oxidative stress is an underlying condition common to several male reproductive disorders, in which high levels of reactive oxygen species (ROS) cause sperm dysfunction (e.g. decreased sperm motility, impaired membrane and DNA integrity, increased lipid peroxidation) and infertility16,17. Previous studies have shown that H2S is able to alleviate the effects of oxidative stress on testicular functions4,8,18, but the in vitro effects of this gasotransmitter on sperm cells under a ROS-generating system still need to be elucidated.
The aim of this study was to evaluate the total antioxidant capacity and stability of the H2S donors Na2S and GYY4137 under standard conditions (38 °C, pH≈7) and at different times (i.e. 20, 120, and 210 minutes) during the incubation (experiment I). Because sperm motility under a ROS-generating system may drop in a few hours19,20 and based on the opposite modalities of H2S release by Na2S and GYY4137 (i.e. fast and slow release, respectively), these incubation times were chosen to determine the dynamics of the antioxidant activity of each donor during the early, mid, and late stages of incubation. Based on the results from experiment I and the physiological total antioxidant capacity of boar seminal plasma21, we then established a suitable range of concentrations of Na2S and GYY4137 to be tested in boar sperm samples under a ROS-generating system (experiment II). Although some Na2S and GYY4137 concentrations used in experiment II show a total antioxidant capacity that is below the range of detection by spectrophotometry, they were included in our experimental design because increasing evidence suggests that in vivo H2S levels range from low µM to high nM22. Next, we evaluated the effects of both donors on sperm motility, mitochondrial activity, plasma membrane integrity, acrosomal status, and lipid peroxidation. The results from this study elucidate the role of H2S donors in sperm samples under oxidative stress and the possible therapeutic implications of these compounds for alleviating the negative effects of ROS on sperm function.
Results
Experiment I. Total antioxidant capacity and stability of H2S donors
As can be seen from Table 1, Na2S and GYY4137 showed different total antioxidant capacities and stabilities during the incubation. Overall, the total antioxidant capacity of Na2S significantly decreased between 20 and 210 minutes of incubation, whereas that of GYY4137 tended to increase during this period and was significantly higher after 210 minutes than after 20 minutes of incubation at 2,400 and 1,200 µM (p < 0.05). Moreover, GYY4137 showed detectable levels of total antioxidant capacity at all concentrations tested, whereas Na2S was unstable within the range of 300 to 1,200 µM and was undetectable at 150 µM. Irrespective of the concentration considered, GYY4137 showed greater total antioxidant capacity than Na2S (Fig. 1).
Experiment II. Effect of H2S donors on boar sperm parameters under induced oxidative stress
Sperm motility
Overall, the effects of H2S on boar sperm motility under induced oxidative stress were dose- and donor-dependent (Table 2, Fig. 2). Thus, 3 and 30 µM GYY4137 and 3 µM Na2S preserved the sperm motility and kinetics under the ROS-generating system. Interestingly, all of the sperm kinetic parameters in these treatments did not differ from those of the control group without oxidative stress (CTR; p > 0.05). The results with both 3 and 30 µM GYY4137 showed higher percentages of total motility (TM) relative to that of the control group under oxidative stress (CTR-ox; p < 0.01). Moreover, a dose of 30 µM GYY4137 significantly increased the percentage of progressive motility (PM) over that in the CTR-ox group (p = 0.040). Although differences were not statistically significant, higher average path velocity (VAP) and straight-line velocity (VSL) were observed in samples treated with 3 µM GYY4137 than in those in the CTR-ox group (p = 0.071 and p = 0.064, respectively). On the other hand, the effects of Na2S were markedly dose dependent. At 300 µM, this fast-releasing H2S donor showed clear negative effects on sperm motility. No motile spermatozoa were observed in any replicate; therefore, no kinetics data could be provided. By contrast, at the lowest concentration, Na2S significantly increased the percentage of motile sperm cells relative to that in the CTR-ox group (p = 0.018). At a concentration of 30 µM, Na2S greatly decreased the TM, PM, VAP, and VSL (p < 0.05), although it did not affect the curvilinear velocity (VCL) and the remaining motion parameters in comparison with those of the CTR-ox group (p > 0.05). However, at this Na2S concentration, we observed some variability among the replicates with the percentage of motile spermatozoa ranging from 0 to almost 30%. There were no differences between the CTR-ox and H2S donor treatments in the amplitude of lateral head displacement (ALH), beat-cross frequency (BCF), linearity (LIN), straightness (STR), and wobble (WOB; p > 0.05).
Sperm mitochondrial status
At a concentration of 300 µM, Na2S showed clear negative effects on boar sperm mitochondrial status. In every replicate, there were no spermatozoa with active mitochondria (Table 3, Fig. 3). There were no differences between the CTR-ox group and the remaining treatment groups (p > 0.05).
Sperm plasma membrane integrity and lipid peroxidation
There was no significant effect of GYY4137 on sperm plasma membrane integrity at any of the concentrations used (p > 0.05, Table 3). On the other hand, 300 µM Na2S markedly impaired the plasma membrane integrity relative to the results obtained for the CTR-ox group (p < 0.001, Table 3, Fig. 3). No effects were observed at the remaining Na2S concentrations (p > 0.05). A similar pattern was observed for the sperm lipid peroxidation: higher values of malondialdehyde (MDA) per 108 spermatozoa were observed in samples treated with 300 µM Na2S than those in the CTR-ox group and the other treatment groups (p < 0.01, Fig. 4). No differences in the MDA levels were found between the CTR-ox group and the remaining treatment groups (p > 0.05).
Acrosomal status
We found that 300 µM Na2S impaired the acrosome integrity (normal apical ridge or NAR test) relative to that of the CTR group, both with and without oxidative stress (p < 0.001, Table 3, Fig. 3). No differences were observed in the NAR test results between the CTR-ox group and the other treatment groups (p > 0.05). On the other hand, all treatments showed lower percentages of acrosome-lost spermatozoa (evaluated with peanut agglutinin–fluorescein isothiocyanate, PNA-FITC) than that of the CTR-ox group (p ≤ 0.001, Table 3).
Discussion
In this study, we provide the first evidence, to the best of our knowledge, that Na2S and GYY4137 show different total antioxidant capacities and stabilities under standard conditions (38 °C, physiological pH) and after different periods (20, 120, and 210 minutes) of incubation. Our results also reveal that the total antioxidant capacity of Na2S is less stable than that of GYY4137, although the latter’s total antioxidant capacity tends to increase over time. This phenomenon should be taken into account in studies entailing cell incubation at 38 °C and at physiological pH, because the release of H2S by GYY4137 is both pH and temperature dependent12. Moreover, GYY4137 shows higher total antioxidant capacity than that of Na2S after any incubation time, with the total antioxidant capacity of Na2S at 150 µM even being undetectable by spectrophotometry after 20 minutes of incubation. The patterns observed in the antioxidant capacities of these H2S donors may not reflect their H2S release, given that the inorganic salts Na2S and NaHS lead to a larger but shorter gas release than GYY413723,24.
Our results show that both H2S donors partly palliate the damages provoked by oxidative stress in sperm cells, supporting the results found previously in other cells (neurons13,25, gastric cells14, testicular germ cells4) and organs (lungs15,26, testes18). In these studies, oxidative stress was induced by in vivo or in vitro ROS-generating systems, such as glutamate, hydrogen peroxide (H2O2), heat, tobacco smoke, ovalbumin sensitisation, and ischaemia-reperfusion injury. In our study, we used Fe2+/ascorbate, which induces lipid peroxidation and catalyses the production of hydroxyl radicals (•OH), the most powerful free radical known, by the Fenton reaction27. Moreover, several previous studies4,13,14,15,18,25,26 employed a single H2S donor, whereas two H2S-releasing agents were tested in our study. To date, few studies8,23,28 have investigated the biological effects of both fast- and slow-releasing H2S donors in cells under oxidative stress conditions. In agreement with these studies, our findings confirm that the effects of H2S donors are not only dose but also donor dependent. Moreover, for the first time to the best of our knowledge, the in vitro effects of fast- and slow-releasing H2S donors were evaluated in sperm cells in the presence of a ROS-generating system. Overall, we found that the slow-releasing H2S donor GYY4137 did not show any cytotoxic effect. Moreover, 3 and 30 µM GYY4137 preserved the boar sperm motility against the detrimental effects of oxidative stress. Interestingly, at both concentrations, the percentage of motile sperm cells was almost 50% higher than that of the CTR-ox samples and no kinetic parameters differed from those of the CTR group without oxidative stress. Moreover, 30 µM GYY4137 samples showed a higher percentage of progressive motility than those in the CTR-ox group. However, in contrast to other studies8,18, we did not find any effect of GYY4137 on the levels of lipid peroxidation, which may be due to the different cell type and donor concentration used in our study. Our findings also show that, in comparison with GYY4137, the effects of Na2S were markedly dose dependent. At a concentration of 3 µM, this fast-releasing H2S donor preserves boar sperm motility (40.5% higher than that in the CTR-ox samples), whereas it shows clear cytotoxic effects at 300 µM. This pattern may reflect the well-known biphasic biological dose–response curve of H2S: it acts as an antioxidant at low concentrations, but a pro-oxidant at high concentrations29. Interestingly, we also found that 30 µM Na2S was not cytotoxic (i.e. no effect was observed on the mitochondrial activity, plasma membrane integrity, acrosome integrity, or lipid peroxidation), but it strongly inhibited sperm motility. As in our findings, Zhao et al. found that 25 µM Na2S inhibits boar sperm motility although it does not affect the viability and mitochondrial membrane potential9. Likewise, NaHS has been shown to inhibit the motility of mouse and human spermatozoa8,30. In our study, the inhibitory effects of Na2S on sperm motility were described by using a comprehensive set of kinetic parameters provided by Computer-Assisted Sperm Analysis (CASA). Overall, 30 µM Na2S remarkably decreased the sperm motility, VAP, and VSL, but it did not affect the remaining motion parameters. In spite of some variability among replicates, a small percentage of sperm cells showed very slow but progressive movement. With regard to the mechanism of action, Zhao et al. found that the inhibitory effects of Na2S on sperm motility are related to the adenosine 5′-monophosphate-activated protein kinase (AMPK) and protein kinase B (AKT) pathways9, whereas a more recent study revealed that H2S promotes the secretion of K+ in the epididymis; this suppresses sperm motility and may contribute to keeping the sperm cells in a quiescent state before ejaculation5. Another plausible explanation for the reduced sperm motility elicited by Na2S can be provided by the inhibitory effect of H2S on cytochrome c oxidase (complex IV), the final component of the electron transport chain that plays a key role in aerobic respiration and adenosine triphosphate (ATP) generation29. Because mammalian spermatozoa devote most of the energy generated as intracellular ATP to motility31, a reduction in ATP levels would lead to an immediate decrease in sperm motility. In this way, for instance, cardiac cells treated with 25 µM Na2S showed over 80% decreased O2 consumption rate relative to the baseline32. In contrast to the effects observed at low concentrations, high concentrations of Na2S showed clear detrimental effects: no motility or active mitochondria were observed in any sample treated with 300 µM Na2S. The toxic effects were acute and led to immediate failure of sperm motility and mitochondrial activity (personal observations). This phenomenon can be explained by the high levels of ROS induced by Na2S9, an explanation corroborated by the increased levels of lipid peroxidation and the low percentage of sperm with intact plasma membrane and acrosome (NAR) found in our study. In contrast to our findings, in testicular germ cells, Li et al. found that treatment with NaHS in the concentration range of 1–200 µM for 30 minutes does not affect cell viability, although cell injuries are induced at 1 mM4. This result might be because, unlike other male germ cells, spermatozoa have limited antioxidant defences. Spermatozoa lack the necessary cytoplasmic-enzyme repair systems, and their membranes are particularly rich in polyunsaturated fatty acids, which make these cells particularly susceptible to the damage caused by oxidative stress16. Another reason might be related to the use of open systems (e.g. four-well plates and Petri dishes) that lead to quick volatilisation of the gas during cell incubation33. It is known that Na2S volatilises very quickly33, and the use of closed systems, such as the one used in our study, delays this process and leads to more consistent results regarding the effects of H2S donors on cell biology. Our results also show that Na2S and GYY4137 partly reduce the damage induced by high ROS levels on acrosomal status by decreasing the percentage of acrosome-lost (PNA-FITC) spermatozoa relative to that in the CTR-ox group. However, neither of the two donors showed any positive effect on the acrosome integrity evaluated by the NAR test. This divergence could be explained by the different acrosomal attributes considered by these two methodologies: NAR evaluated in unstained samples by phase-contrast microscopy versus outer acrosomal membrane integrity assessed by PNA-FITC staining with epifluorescence microscopy34,35. Because acrosome integrity is a requisite for fertilisation and the ROS levels affect sperm function36,37, it remains to be tested whether Na2S and GYY4137 may preserve the fertilising potential of sperm cells under oxidative stress. Semen handling and storage decrease boar sperm quality and fertilising ability, probably because of oxidative stress38,39, so H2S donors may be useful for the optimisation of semen extenders used in artificial insemination programmes. In the porcine industry, higher efficiency of artificial insemination outcomes may have major economic implications because this assisted reproductive technology is the main tool for pig gene dissemination worldwide40.
Several mechanisms are involved in the ROS scavenging properties of H2S. One of these mechanisms involves H2S itself by virtue of its reducing properties13. In this way, the total antioxidant capacities of Na2S and GYY4137 were tested in this study based on the compounds’ abilities to reduce 2,2′-azino-bis(3-ethylbenz-thiazoline-6-sulfonic acid) (ABTS) previously oxidised with H2O241. Another mechanism that may explain the capacity of H2S donors to palliate the damages provoked by oxidative stress concerns the enhancement of the cellular antioxidant defences. Previous studies found that H2S increases glutathione synthesis, decreases ROS production, and stimulates the activities of superoxide dismutase, glutathione peroxidase, and glutathione reductase4,9,13,25,26. Moreover, H2S decreases the apoptosis rate, increases the protein expression ratio of Bax/Bcl-2, and stimulates Cyp19 gene expression, among other effects4,18,42. Because spermatozoa are transcriptionally inactive43, it is likely that H2S donors protect sperm cells against ROS damage through their proper reducing activity, as well as by increasing the ratio of reduced to oxidised glutathione and stimulating superoxide dismutase and glutathione peroxidase activities, which represent the major antioxidant defence system of sperm cells44. Further studies are nevertheless required to investigate the mechanisms of action of H2S donors in sperm cells under oxidative stress.
In conclusion, our study provides evidence about the antioxidant properties of two H2S donors, Na2S and GYY4137; this evidence will be useful for future studies aiming to test the antioxidant effect of this gasotransmitter. Our findings clearly show that Na2S has a shorter and less stable total antioxidant capacity than that of GYY4137; it is even undetectable by spectrophotometry at 150 µM. However, it is important to stress out that the antioxidant capacity of GYY4137 tends to increase over time. We also found that both H2S donors preserve sperm motility and protect the acrosomal status against the detrimental consequences of oxidative stress, although the effects were clearly both dose and donor dependent. Within the range of concentrations tested (3–300 µM), GYY4137 showed positive effects on sperm motility, whereas Na2S was detrimental at the highest concentration but beneficial at the lowest. Taken together, our results suggest that Na2S and GYY4137 may be used as in vitro therapeutic agents against oxidative stress in sperm cells, although the optimal therapeutic range varies between H2S donors.
Methods
Reagents were purchased from Sigma–Aldrich (Prague, Czech Republic), unless otherwise indicated.
Ethics statement
This study did not involve animal handling because the sperm samples were purchased as artificial insemination doses from a pig breeding company (Chovservis, Hradec Králové, Czech Republic).
Experiment I
This experiment was designed to evaluate the total antioxidant capacity and stability of Na2S and GYY4137 at 20, 120, and 210 minutes during incubation at 38 °C in a water bath. The solutions were prepared shortly before the experiment and kept in microcentrifuge tubes tightly sealed with the attached cap (certified free of DNA, DNase, RNase, and endotoxins (pyrogens); material: virgin polypropylene; volume: 600 µl; Neptune Scientific, San Diego, CA, USA) during the whole incubation. For each concentration of H2S donor, analyses were performed on the same tube throughout the incubation period. Moreover, each microcentrifuge tube contained the same volume (i.e. 200 µl) of H2S donor or phosphate-buffered saline (PBS; blank) solution. The experiment was replicated four times.
H 2 S donor preparation
Na2S (Na2S × 9 H2O) and GYY4137 (C11H16NO2PS2·C4H9NO × CH2Cl2) were prepared in PBS (pH≈7) solution at final concentrations of 2,400, 1,200, 600, 300, and 150 µM.
Total antioxidant capacity of H 2 S donors
The total antioxidant capacity was determined by spectrophotometry (Libra S22, Biochrom, Harvard Bioscience Company, Cambourne, United Kingdom) at 660 nm by using the method described previously41. The principle of this assay is based on the antioxidant’s capacity to reduce ABTS previously oxidised with H2O2. A standard curve was established by using known concentrations of 6-hydroxy-2,5,7,8-tetramethylchroman-2-carboxylic acid (Trolox). The total antioxidant capacity was expressed as Trolox equivalents (µM or mM). The assay was run in duplicate for each sample.
Experiment II
This experiment was designed to test whether H2S donors protect sperm cells against the deleterious effects of oxidative stress.
Sample collection and experimental design
Artificial insemination doses from 18 boars of different breeds were purchased from a pig breeding company. Sperm-rich fractions were collected by the gloved-hand method, diluted with Solusem® extender (AIM Worldwide, Vught, Netherlands; pH≈7), and transported to the laboratory at 17 °C. The sperm motility and morphology were then checked, and only samples with at least 75% of motile and morphologically normal sperm were used for the experiments. Sperm samples from three boars were pooled to reduce the effect of male variability and were centrifuged at 167 g for 3 minutes at 17 °C to remove debris and dead sperm cells. The sperm concentration was then checked by using a Bürker chamber, adjusted to 30–40 × 106 spermatozoa/ml with Solusem®, and finally diluted 1:1 (v/v) with Solusem® supplemented with 0.2% (w/v) of bovine serum albumin (BSA; ethanol-fractionated lyophilised powder). Thus, the final sperm and BSA concentrations were 15–20 × 106 spermatozoa/ml and 0.1%, respectively. Sperm samples were then randomly split into eight microcentrifuge tubes tightly sealed with the attached cap (certified free of DNA, DNase, RNase, and endotoxins (pyrogens); material: virgin polypropylene; volume: 2 ml; Neptune Scientific, San Diego, CA, USA): CTR, CTR-ox, and Na2S or GYY4137 at 300, 30, and 3 µM under oxidative stress. Oxidative stress was induced by adding a solution composed of 0.1 mM FeSO4 and 0.5 mM sodium ascorbate (Fe2+/ascorbate) to the sperm samples. Because the effects of this ROS-generating system are clearly evident after 210 minutes of sperm incubation19, sperm analyses were performed at 0 hour (after 20 minutes of incubation for the CTR group only) and after 210 minutes of incubation at 38 °C in a water bath. The experiment was replicated six times with six independent semen pools.
Sperm motility
Sperm motility was evaluated by using CASA (NIS-Elements; Nikon, Tokyo, Japan, and Laboratory Imaging, Prague, Czech Republic), after loading 5 µl of sperm sample into a pre-warmed (38 °C) Spermtrack chamber (PROiSER R + D S.L., Paterna, Spain; chamber depth: 20 µm). A total of ten sperm kinetic parameters were obtained by analysing six random fields: TM (%), PM (%),VAP (µm/s), VCL (µm/s), VSL (µm/s), ALH (μm), BCF (Hz), LIN (VSL/VCL, %), STR (VSL/VAP, %), and WOB (VAP/VCL, %). The settings parameters were as follows: frames per second, 60; minimum frames acquired, 31; VAP ≥ 10 μm/s to classify a spermatozoon as motile, STR ≥ 80% to classify a spermatozoon as progressive19. A minimum of 200 sperm cells were analysed for each sample.
Sperm mitochondrial status
Mitochondrial status was evaluated as previously described45, with minor modifications. Briefly, aliquots of sperm samples were incubated with rhodamine 123 (5 mg/ml, w/v, in dimethyl sulfoxide, DMSO) and propidium iodide (0.5 mg/ml, w/v, in PBS) for 15 minutes at 38 °C in the dark. Subsequently, samples were centrifuged at 500 g for 5 minutes, the supernatant was removed, and the sperm pellet was resuspended in PBS. Then, 200 spermatozoa were evaluated by using epifluorescence microscopy (40× objective; Nikon Eclipse E600, Nikon, Tokyo, Japan): the spermatozoa showing bright green fluorescence in the midpiece were considered to have active mitochondria.
Sperm plasma membrane integrity
The sperm plasma membrane integrity was evaluated as previously described46,47. Aliquots of sperm samples were incubated with carboxyfluorescein diacetate (0.46 mg/ml, w/v, in DMSO), propidium iodide (0.5 mg/ml, w/v, in PBS), and formaldehyde solution (0.3%, v/v) for 10 minutes at 38 °C in the dark. Then, 200 spermatozoa were evaluated by using epifluorescence microscopy (40× objective). The spermatozoa showing green fluorescence over the entire head area were considered to have intact plasma membrane.
Lipid peroxidation
Lipid peroxidation was assessed with the thiobarbituric acid reactive substances (TBARS) assay, as previously described19,48. At the end of each incubation period, sperm aliquots were collected and stored at −80 °C until analysis. The absorbance of each sample was then measured by spectrophotometry at 532 nm. A standard curve was established by using known concentrations of 1,1,3,3-tetramethoxypropane (MDA). The levels of lipid peroxidation are shown as µmol of MDA per 108 spermatozoa. The assay was run in duplicate for each sample.
Acrosomal status
Acrosome integrity was assessed after sample fixation in 2% (v/v) glutaraldehyde solution and by examination with phase-contrast microscopy (40× objective)34. For each sample, 200 spermatozoa were evaluated, and the percentage of sperm cells with NAR was determined. Acrosome loss was evaluated according to the protocol previously described49. Briefly, after methanol fixation and double washing with PBS, the samples were incubated with PNA-FITC (100 µg/ml, w/v, in PBS) for 10 minutes at 38 °C in the dark. Epifluorescence microscopy (40× objective) was used to evaluate 200 spermatozoa, and the cells showing no fluorescence over the acrosome were considered as acrosome-lost spermatozoa.
Statistical analysis
Data were analysed with the statistical program SPSS, version 20 (IBM Inc., Chicago, IL, USA). Shapiro-Wilk’s and Levene’s tests were used to analyse the normal distribution and the variance homogeneity of the data, respectively. The Mann–Whitney U-test was applied to check for differences between the total antioxidant capacities of Na2S and GYY4137 at the same concentration, whereas the repeated-measures Friedman test was used to compare the total antioxidant capacities of the H2S donors across the incubation times. The generalized linear model (GZLM) was performed to analyse the effects of the type and concentration of H2S donor on the sperm variables. The statistical significance was determined at p < 0.05. Data are shown as the mean±standard error.
Data availability
All data generated or analysed during this study are included in this article and its supplementary information file.
References
Kolluru, G. K., Shen, X., Bir, S. C. & Kevil, C. G. Hydrogen sulfide chemical biology: pathophysiological roles and detection. Nitric Oxide-Biol. Chem. 35, 5–20 (2013).
Wang, R. Physiological implications of hydrogen sulfide: a whiff exploration that blossomed. Physiol. Rev. 92, 791–896 (2012).
Sugiura, Y. et al. Cadmium exposure alters metabolomics of sulfur-containing amino acids in rat testes. Antioxid. Redox Signal. 7, 781–787 (2005).
Li, G., Xie, Z. Z., Chua, J. M., Wong, P. C. & Bian, J. Hydrogen sulfide protects testicular germ cells against heat-induced injury. Nitric Oxide-Biol. Chem. 46, 165–171 (2015).
Gao, D. D. et al. Cellular mechanism underlying hydrogen sulfide mediated epithelial K+ secretion in rat epididymis. Front. Physiol. 9, 1886, https://doi.org/10.3389/fphys.2018.01886 (2019).
D’Emmanuele di Villa Bianca, R. et al. Hydrogen sulfide as a mediator of human corpus cavernosum smooth-muscle relaxation. Proc. Natl. Acad. Sci. USA 106, 4513–4518 (2009).
Martínez-Heredia, J., de Mateo, S., Vidal-Taboada, J. M., Ballescà, J. L. & Oliva, R. Identification of proteomic differences in asthenozoospermic sperm samples. Hum. Reprod. 23, 783–791 (2008).
Wang, J. et al. Hydrogen sulfide as a potential target in preventing spermatogenic failure and testicular dysfunction. Antioxid. Redox Signal. 28, 1447–1462 (2018).
Zhao, Y. et al. Hydrogen sulfide and/or ammonia reduces spermatozoa motility through AMPK/AKT related pathways. Sci. Rep. 6, 37884, https://doi.org/10.1038/srep37884 (2016).
Song, Z. J. et al. Hydrogen sulfide donors in research and drug development. Med. Chem. Commun. 5, 557–570 (2014).
Wu, D., Hu, Q. & Zhu, Y. Therapeutic application of hydrogen sulfide donors: the potential and challenges. Front. Med 10, 18–27 (2016).
Rose, P., Dymock, B. W. & Moore, P. K. GYY4137, a novel water-soluble, H2S-releasing molecule in Methods in Enzymology (eds. Cadenas, E. & Packer, L.) 143–167 (Elsevier, 2015).
Kimura, Y. & Kimura, H. Hydrogen sulfide protects neurons from oxidative stress. FASEB J. 18, 1165–1167 (2004).
Yonezawa, D. et al. A protective role of hydrogen sulfide against oxidative stress in rat gastric mucosal epithelium. Toxicology 241, 11–18 (2007).
Han, W., Dong, Z., Dimitropoulou, C. & Su, Y. Hydrogen sulfide ameliorates tobacco smoke-induced oxidative stress and emphysema in mice. Antioxid. Redox. Signal. 15, 2121–2134 (2011).
Agarwal, A., Virk, G., Ong, C. & du Plessis, S. S. Effect of oxidative stress on male reproduction. World J. Mens Health 32, 1–17 (2014).
Aitken, R. J., Gibb, Z., Baker, M. A., Drevet, J. & Gharagozloo, P. Causes and consequences of oxidative stress in spermatozoa. Reprod. Fertil. Dev. 28, 1–10 (2016).
Ning, J. Z. et al. The protective effects of GYY4137 on testicular torsion/detorsion injury in rats. Int. J. Clin. Exp. Med. 11, 3387–3395 (2018).
Pintus, E., Kadlec, M., Jovičić, M., Sedmíková, M. & Ros-Santaella, J. L. Aminoguanidine protects boar spermatozoa against the deleterious effects of oxidative stress. Pharmaceutics 10, 212, https://doi.org/10.3390/pharmaceutics10040212 (2018).
Martín Muñoz, P. et al. Redox cycling induces spermptosis and necrosis in stallion spermatozoa while the hydroxyl radical (OH•) only induces spermptosis. Reprod. Domest. Anim. 53, 54–67 (2018).
Barranco, I. et al. High total antioxidant capacity of the porcine seminal plasma (SP-TAC) relates to sperm survival and fertility. Sci. Rep. 5, 18538, https://doi.org/10.1038/srep18538 (2015).
Cooper, C. E. & Brown, G. C. The inhibition of mitochondrial cytochrome oxidase by the gases carbon monoxide, nitric oxide, hydrogen cyanide and hydrogen sulfide: chemical mechanism and physiological significance. J. Bioenerg. Biomembr. 40, 533–539 (2008).
Whiteman, M. et al. The effect of hydrogen sulfide donors on lipopolysaccharide-induced formation of inflammatory mediators in macrophages. Antioxid. Redox Signal. 12, 1147–1154 (2010).
Kim, T. J., Lee, Y. J., Ahn, Y. J. & Lee, G. J. Characterization of H2S releasing properties of various H2S donors utilizing microplate cover-based colorimetric assay. Anal. Biochem. 574, 57–65 (2019).
Kimura, Y., Goto, Y. & Kimura, H. Hydrogen sulfide increases glutathione production and suppresses oxidative stress in mitochondria. Antioxid. Redox Signal. 12, 1–13 (2010).
Benetti, L. R. et al. Hydrogen sulfide inhibits oxidative stress in lungs from allergic mice in vivo. Eur. J. Pharmacol. 698, 463–469 (2013).
Buettner, G. R. & Jurkiewicz, B. A. Catalytic metals, ascorbate and free radicals: Combinations to avoid. Radiat. Res. 145, 532–541 (1996).
Cao, X. et al. Renal protective effect of hydrogen sulfide in cisplatin-induced nephrotoxicity. Antioxid. Redox Signal. 29, 455–470 (2018).
Szabo, C. et al. Regulation of mitochondrial bioenergetic function by hydrogen sulfide. Part I. Biochemical and physiological mechanisms. Br. J. Pharmacol. 171, 2099–2122 (2014).
Wiliński, B. et al. Sodium hydrosulfide exerts a transitional attenuating effect on spermatozoa migration in vitro. Folia Biol. 63, 145–149 (2015).
Storey, B. T. Mammalian sperm metabolism: oxygen and sugar, friend and foe. Int. J. Dev. Biol. 52, 427–437 (2008).
Elrod, J. W. et al. Hydrogen sulfide attenuates myocardial ischemia-reperfusion injury by preservation of mitochondrial function. Proc. Natl. Acad. Sci. USA 104, 15560–15565 (2007).
DeLeon, E. R., Stoy, G. F. & Olson, K. R. Passive loss of hydrogen sulfide in biological experiments. Anal. Biochem. 421, 203–207 (2012).
Pursel, V. G., Johnson, L. A. & Rampacek, G. B. Acrosome morphology of boar spermatozoa incubated before cold shock. J. Anim. Sci 34, 278–283 (1972).
Mortimer, D., Curtis, E. F. & Miller, R. G. Specific labelling by peanut agglutinin of the outer acrosomal membrane of the human spermatozoon. J. Reprod. Fertil. 81, 127–135 (1987).
Sancho, S. & Vilagran, I. The boar ejaculate: sperm function and seminal plasma analyses in Boar Reproduction: Fundamentals and New Biotechnological Trends (eds. Bonet, S., Casas, I., Holt, W. V. & Yeste, M.) 471–516 (Springer, 2013).
Awda, B. J., Mackenzie-Bell, M. & Buhr, M. M. Reactive oxygen species and boar sperm function. Biol. Reprod 81, 553–561 (2009).
Kumaresan, A. et al. Preservation of boar semen at 18 degrees C induces lipid peroxidation and apoptosis like changes in spermatozoa. Anim. Reprod. Sci. 110, 162–171 (2009).
Lopez Rodriguez, A., Van Soom, A., Arsenakis, I. & Maes, D. Boar management and semen handling factors affect the quality of boar extended semen. Porcine Health Manag. 3, 15, https://doi.org/10.1186/s40813-017-0062-5 (2017).
Roca, J., Parrilla, I., Bolarin, A., Martinez, E. A. & Rodriguez-Martinez, H. Will AI in pigs become more efficient? Theriogenology 86, 187–196 (2016).
Erel, O. A novel automated direct measurement method for total antioxidant capacity using a new generation, more stable ABTS radical cation. Clin. Biochem. 37, 277–285 (2004).
Hassan, E., Kahilo, K., Kamal, T., El-Neweshy, M. & Hassan, M. Protective effect of diallyl sulfide against lead-mediated oxidative damage, apoptosis and down-regulation of CYP19 gene expression in rat testes. Life Sci. 226, 193–201 (2019).
Grunewald, S., Paasch, U., Glander, H. J. & Anderegg, U. Mature human spermatozoa do not transcribe novel RNA. Andrologia 37, 69–71 (2005).
Tvrdá, E., Kňažická, Z., Bárdos, L., Massányi, P. & Lukáč, N. Impact of oxidative stress on male fertility—A review. Acta Vet. Hung. 59, 465–484 (2011).
Fraser, L., Lecewicz, M. & Strzezek, J. Fluorometric assessments of viability and mitochondrial status of boar spermatozoa following liquid storage. Pol. J. Vet. Sci. 5, 85–92 (2002).
Harrison, R. A. P. & Vickers, S. E. Use of fluorescent probes to assess membrane integrity in mammalian spermatozoa. J. Reprod. Fertil. 88, 343–352 (1990).
Grieblová, A., Pintus, E. & Ros-Santaella, J. L. Integrity of head and tail plasmalemma is associated with different kinetic variables in boar sperm. Anim. Reprod. Sci. 184, 218–227 (2017).
Brzezińska-Ślebodzińska, E., Ślebodziński, A. B., Pietras, B. & Wieczorek, G. Antioxidant effect of vitamin E and glutathione on lipid peroxidation in boar semen plasma. Biol. Trace Elem. Res. 47, 69–74 (1995).
García-Vázquez, F. A. et al. Morphometry of boar sperm head and flagellum in semen backflow after insemination. Theriogenology 84, 566–574 (2015).
Acknowledgements
This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
Author information
Authors and Affiliations
Contributions
E.P. and J.L.R.-S. conceived and designed the experiments; E.P., M.J., M.K. and J.L.R.-S. performed the experiments; E.P. and J.L.R.-S. analysed the data; E.P. wrote the paper; E.P., M.J., M.K. and J.L.R.-S. revised and edited the paper.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Pintus, E., Jovičić, M., Kadlec, M. et al. Divergent effect of fast- and slow-releasing H2S donors on boar spermatozoa under oxidative stress. Sci Rep 10, 6508 (2020). https://doi.org/10.1038/s41598-020-63489-4
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-020-63489-4
- Springer Nature Limited
This article is cited by
-
Antimicrobial peptides and proteins as alternative antibiotics for porcine semen preservation
BMC Veterinary Research (2024)
-
N-thiocarboxyanhydrides, amino acid-derived enzyme-activated H2S donors, enhance sperm mitochondrial activity in presence and absence of oxidative stress
BMC Veterinary Research (2023)
-
Evidence of endogenously produced hydrogen sulfide (H2S) and persulfidation in male reproduction
Scientific Reports (2022)