Effects of N-acetyl-cysteine supplementation on sperm quality, chromatin integrity and level of oxidative stress in infertile men

Oxidative stress and reactive oxygen species (ROS), known as free radicals, are oxidizing agents with a high reactive capacity. ROS may have either endogenous or exogenous origin and may cause defective spermatogenesis and male infertility [1]. Many environmental, physiological, and genetic factors have been implicated with sperm functions and infertility [2]. In particular, oxidative stress (OS) has been suggested to affect male fertility and the physiology of spermatozoa [3]. In physiological conditions, spermatozoa produce little ROS, which are required for sperm physiology (sperm hyperactivation, capacitation, acrosome reaction) and also for natural fertilization [4].

Increased pathological ROS generation leads to sperm dysfunction (lipid peroxidation), decreased semen quality and sperm DNA damage [5]. In fact, oxidative stress damages sperm genes with the occurrence of single- and/or double stranded DNA [6]. Therefore, scavenging excess ROS is essential for normal spermatogenesis and fertilization [7].

In infertile men’s semen, leukocytes and immature or abnormal spermatozoa are often the two main sources of ROS [8]. Spermatozoa are susceptible to oxidative damage because their plasma membranes are rich in polyunsaturated fatty acids and have low concentrations of scavenging enzymes [9]. At the same time, antioxidants, which protect the cell from excessive ROS-induced lipid peroxidation, are also present in the ejaculate [10]. Antioxidant capacity in the idiopathic infertile male population is lower than that of fertile men, who exhibit significantly greater seminal ROS production [11]. However, it is unclear whether reduced semen antioxidant capacity necessarily causes sperm dysfunction (including sperm DNA damage) [12, 13]. The association between sperm DNA damage and semen ROS is the basis for the use of antioxidants in the treatment of sperm DNA damage and sperm quality. Dietary antioxidants may also have positive effects on sperm parameters [14].

N-acetyl-cysteine (NAC), a derivative of amino acid L-cysteine, is currently used mainly as an antioxidant [15]. NAC also contributes to glutathione (GSH) synthesis [16] and may help restore the depleted pool of GSH often caused by oxidative stress and inflammation [17, 18]. NAC has free radical scavenging activity both in vivo [19] and in vitro [20, 21]. In addition, daily treatment with NAC results in a significant improvement in sperm motility in comparison to placebo [22]. Comhaire et al. also found that NAC improved sperm concentration and acrosome reaction while reducing ROS and oxidation of sperm DNA [23]. Based on the above, the present study was conducted to investigate the effects of daily oral NAC supplementation on the quality of semen parameters, chromatin integrity and reproductive hormones in asthenoteratozoospermic men.

The present study assessed the effects of NAC supplementation on semen parameters and antioxidant status in asthenoteratozoospermic men partners of infertile couples. The three-month supplementation with NAC significantly improved sperm parameters (count, motility and normal morphology) from pre-treatment baseline. Based on our findings and other studies [19, 22], medical therapy with oral antioxidants can improve the quality of semen parameters. Recently, Buhling et al. [28] reported that male infertility is associated with a decreased intake of some antioxidant nutrients, such as vitamins A, C, and E, carnitine, folate, zinc, and selenium. N-acetylcysteine (NAC) is a thiol-based antioxidant that plays an important role in the protection of cellular constituents against oxidative damage. The hypothetical action of NAC originates from its ability to stimulate and sustain intracellular levels of reduced glutathione and also to detoxify ROS [15]. Safarinejad et al. [22] also reported significant improvements in all semen parameters in subjects receiving selenium or NAC, with an additive effect on the combination group. The effects of NAC on ROS and sperm motility may be mediated by a modulation of mitochondrial activity: 2 mM NAC, alone or combined with methyl donors, B6 and zinc was shown to protect human sperm mitochondria from the decay of their membrane potential and to decrease mitochondrial ROS production in bovine sperm following in vitro incubation up to 180 min [29].

The association between sperm DNA damage and ROS is the basis for the use of antioxidants in the hope of reducing sperm DNA damage. Both exogenous and endogenous ROS can induce sperm DNA damage in vitro, confirming that ROS may play a role in the etiology of sperm DNA damage in infertile men [30, 31] .

There are a few reports on the effects of dietary antioxidant supplementation on sperm DNA integrity. Most of such clinical studies have evaluated men with high levels of sperm DNA damage. Treatment with antioxidant supplements is generally associated with reduced levels of sperm DNA damage and/or improved fertility potential [32, 33]. GSH is a critical intracellular antioxidant that helps limit the impact of oxidative stress and protect vital cellular components (lipids, proteins, DNA) against harmful peroxidation. NAC effects on GSH rely on the presence of the free sulfyhydryl group as a ready source of reducing equivalents to quench radical species [16]. Likewise, we show here that supplementation of infertile individuals with 600 mg/day of NAC significantly reduces DNA fragmentation from 19.34 ± 0.47 before treatment to 15.14 ± 0.46 after treatment and also improves sperm protamine content.

In addition, significant inverse correlations were observed between the percentage of TUNEL-positive cells versus sperm motility or morphology, indicating that NAC protects sperm chromatin integrity and reduces DNA fragmentation. The improved DNA integrity could be partly related to enhanced chromatin maturity, i.e. the improved replacement of histones with protamine. Higher amounts of protamines in sperm mean that a relaxed chromatin state has been converted to a compact and stable structure that reduces the accessibility of ROS to DNA. These observations are in line with previous studies indicating that a correct P1:P2 ratio reflects a proper replacement of histones with protamines, which correlates significantly with the rate of DNA fragmentation [34]. NAC may benefit protamination by feeding the one-carbon metabolism, which, besides increasing GSH and antioxidant capacity of sperm, provides activated methyl groups for epigenetic DNA reprogramming [35].

Spermatogenesis is highly controlled by the hormonal milieu of the testis and any alteration in the hormonal profile, besides influencing the rate and quality of spermatogenesis, may deeply affect chromosomal ploidy and integrity of sperm chromatin [36]. The increased pre-treatment gonadotropin levels (FSH and LH) found in our patients are likely related to a state of hypogonadism, causing aberration in the process of spermatogenesis, which improves with NAC supplementation as confirmed by the increase in serum testosterone levels. These results align with a previous study that reported improved serum testosterone after supplementation with NAC [22]. Increased testosterone provides a negative feedback to the hypothalamus and pituitary, leading to reductions in both GnRH pulse frequency and pituitary responsiveness to GnRH, ultimately resulting in reduced gonadotropin release [37].

Bidmeshkipour et al. [38] reported that TAC levels in the seminal plasma of asthenospermic men were significantly lower than those of healthy men, accordingly, the effect of NAC on MDA and TAC was investigated in the seminal plasma. Our results showed a significant decline in concentrations of MDA, a specific marker of lipid peroxidation, while TAC significantly increased after treatment with NAC. Thus, NAC reduced the severity of oxidative stress leading to reduced lipid peroxidation and DNA fragmentation as verified by MDA and TUNEL assay. The improved DNA maturity assessed by CMA3 staining was an indirect effect of NAC. Indeed, oxidative stress hampers chromatin reprogramming including DNA methylation, which has important consequences on the formation of the protamine shield protecting DNA from oxidative stress and thereby DNA damage.

In addition, TAC correlated positively with markers of sperm quality such as motility and negatively with markers of sperm damage including abnormal morphology, protamine deficiency and DNA fragmentation. As expected, opposite correlations were found for MDA, a marker of lipid peroxidation. Taken together, this correlation analysis emphasizes the role of oxidative stress and anti-oxidant capacity in the quality of sperm benefiting from NAC supplementation [39]. In addition to in vivo supplementation of NAC, this antioxidant has also been used to protect sperm from cryo-injury. Despite, numerous studies suggesting NAC can protect sperm from cro-injury but similar effect was not observed in all species [40].

ROS appears to play an important role in the generation of sperm DNA damage, impairment of semen parameters, and failure of sperm functions leading to male supplementation with NAC for at least 3 months in asthenoteratozoospermic men partners of infertile couples, who benefited from reverting these damages, likely due to its positive effect on the antioxidant defenses.