Analysis of the effects of polyphenols on human spermatozoa reveals unexpected impacts on mitochondrial membrane potential, oxidative stress and DNA integrity; implications for assisted reproductive technology.

The need to protect human spermatozoa from oxidative stress during assisted reproductive technology, has prompted a detailed analysis of the impacts of phenolic compounds on the functional integrity of these cells. Investigation of 16 individual compounds revealed a surprising variety of negative effects including: (i) a loss of mitochondrial membrane potential (Δψm) via mechanisms that were not related to opening of the permeability transition pore but associated with a reduction in thiol expression, (ii) a decline in intracellular reduced glutathione, (iii) the stimulation of pro-oxidant activity including the induction of ROS generation from mitochondrial and non-mitochondrial sources, (iv) stimulation of lipid peroxidation, (v) the generation of oxidative DNA damage, and (vi) impaired sperm motility. For most of the polyphenolic compounds examined, the loss of motility was gradual and highly correlated with the induction of lipid peroxidation (r=0.889). The exception was gossypol, which induced a rapid loss of motility due to its inherent alkylating activity; one consequence of which was a marked reduction in carboxymethyl lysine expression on the sperm tail; a post-translational modification that is known to play a key role in the regulation of sperm movement. The only polyphenols that did not appear to have adverse effects on spermatozoa were resveratrol, genistein and THP at doses below 100µM. These compounds could, therefore, have some therapeutic potential in a clinical setting.

Involvement of homocysteine, homocysteine thiolactone, and paraoxonase type 1 (PON-1) in the etiology of defective human sperm function.

This study reports, for the first time, the significant (p ≤ 0.01) accumulation of homocysteine residues in low density, defective sperm suspensions isolated from patients attending an infertility clinic. This overabundance of homocysteine was not related to a deficiency in folate availability but may have been a reflection of the oxidative stress that characterizes such defective sperm populations. Direct addition of the homocysteine cyclic congener, homocysteine thiolactone, to human spermatozoa resulted in the rapid induction of mitochondrial reactive oxygen species (ROS) generation (p < 0.001), the stimulation of lipid peroxidation (p < 0.01), the promotion of tyrosine phosphorylation (p < 0.001), and the suppression of sperm motility (p < 0.001) in the absence of any significant impact on DNA integrity. The parent homocysteine molecule was less active and took 24 h to stimulate mitochondrial ROS production possibly because of the need to convert this compound to the corresponding thiolactone before it could exert a measureable biological effect. Thiolactone was also effective in suppressing the carboxymethylation of key proteins in the sperm tail, which are thought to be involved in the regulation of sperm movement. The major enzyme responsible for removing thiolactone from proteins, paraoxonase (PON-1), was shown to be a major target for alkylation by lipid aldehydes, such as 4-hydroxynonenal, generated as a consequence of oxidative stress. Exposure of human spermatozoa to such aldehydes resulted in a dose-dependent accumulation of homocysteine in spermatozoa (p < 0.03). These results suggest that one of the consequences of oxidative stress in mammalian spermatozoa is the inhibition of PON-1, which then enhances the availability of homocysteine thiolactone to interact with the epsilon-amino group of lysine residues on sperm proteins, triggering a raft of significant biological changes in these cells that ultimately compromise sperm function.

Potential importance of transition metals in the induction of DNA damage by sperm preparation media.

STUDY QUESTION: What are the mechanisms by which the preparation of spermatozoa on discontinuous density gradients leads to an increase in oxidative DNA damage? SUMMARY ANSWER: The colloidal silicon solutions that are commonly used to prepare human spermatozoa for assisted reproduction technology (ART) purposes contain metals in concentrations that promote free radical-mediated DNA damage. WHAT IS KNOWN ALREADY: Sporadic reports have already appeared indicating that the use of colloidal silicon-based discontinuous density gradients for sperm preparation is occasionally associated with the induction of oxidative DNA damage. The cause of this damage is however unknown. STUDY DESIGN, SIZE, DURATION: This study comprised a series of experiments designed to: (i) confirm the induction of oxidative DNA damage in spermatozoa prepared on commercially available colloidal silicon gradients, (ii) compare the levels of damage observed with alterative sperm preparation techniques including an electrophoretic approach and (iii) determine the cause of the oxidative DNA damage and develop strategies for its prevention. The semen samples employed for this analysis involved a cohort of >50 unselected donors and at least three independent samples were used for each component of the analysis. PARTICIPANTS/MATERIALS, SETTING, METHODS: The setting was a University biomedical science laboratory. The major techniques employed were: (i) flow cytometry to study reactive oxygen species generation, lipid peroxidation and DNA damage, (ii) computer-aided sperm analysis to measure sperm movement and (iii) inductively coupled mass spectrometry to determine the elemental composition of sperm preparation media. MAIN RESULTS AND THE ROLE OF CHANCE: Oxidative DNA damage is induced in spermatozoa prepared on PureSperm(®) discontinuous colloidal silicon gradients (P < 0.001 versus repeated centrifugation) because this medium contains metals, particularly Fe, Al and Cu, which are known to promote free radical generation in the immediate vicinity of DNA. This damage can be significantly accentuated by reducing agents, such as ascorbate (P < 0.001) and inhibited by selective chelation (P < 0.001). This problem is not confined to PureSperm(®); analysis of additional commercial sperm preparation media revealed that metal contamination is a relatively constant feature of such products. LIMITATIONS, REASONS FOR CAUTION: While the presence of metals, particularly transition metals, may exacerbate the levels of oxidative DNA damage seen in human spermatozoa, the significance of such damage has not yet been tested in suitably powered clinical trials. WIDER IMPLICATIONS OF THE FINDINGS: The results explain why the preparation of spermatozoa on discontinuous colloidal silicon gradients can result in oxidative DNA damage. The results are of immediate relevance to the development of safe, effective protocols for the preparation of spermatozoa for ART purposes. STUDY FUNDING/COMPETING INTERESTS: The study was funded by the Australian Health and Medical Research Council. One of the authors (R.J.A.) has had a consultantship with a biotechnology company, NuSep, interested in the development of electrophoretic methods of sperm preparation. He has no current financial interest in this area. None of the other authors have a conflict of interest to declare.

Functional deletion of Txndc2 and Txndc3 increases the susceptibility of spermatozoa to age-related oxidative stress.

Oxidative stress in the male germ line is known to be a key factor in both the etiology of male infertility and the high levels of DNA damage encountered in human spermatozoa. Because the latter has been associated with a variety of adverse clinical outcomes, including miscarriage and developmental abnormalities in the offspring, the mechanisms that spermatozoa use to defend themselves against oxidative stress are of great interest. In this context, the male germ line expresses three unique forms of thioredoxin, known as thioredoxin domain-containing proteins (Txndc2, Txndc3, and Txndc8). Two of these proteins, Txndc2 and Txndc3, retain association with the spermatozoa after spermiation and potentially play an important role in regulating the redox status of the mature gamete. To address this area, we have functionally deleted the sperm-specific thioredoxins from the male germ line of mice by either exon deletion (Txndc2) or mutation of the bioactive cysteines (Txndc3). The combined inactivation of these Txndc isoforms did not have an overall impact on spermatogenesis, epididymal sperm maturation, or fertility. However, Txndc deficiency in spermatozoa did lead to age-dependent changes in these cells as reflected by accelerated motility loss, high rates of DNA damage, increases in reactive oxygen species generation, enhanced formation of lipid aldehyde-protein adducts, and impaired protamination of the sperm chromatin. These results suggest that although there is considerable redundancy in the systems employed by spermatozoa to defend themselves against oxidative stress, the sperm-specific thioredoxins, Txndc2 and Txndc3, are critically important in protecting these cells against the increases in oxidative stress associated with paternal age.

On methods for the detection of reactive oxygen species generation by human spermatozoa: analysis of the cellular responses to catechol oestrogen, lipid aldehyde, menadione and arachidonic acid.

Oxidative stress is known to have a major impact on human sperm function and, as a result, there is a need to develop sensitive methods for measuring reactive oxygen species (ROS) generation by these cells. A variety of techniques have been developed for this purpose including chemiluminescence (luminol and lucigenin), flow cytometry (MitoSOX Red, dihydroethidium, 4,5-diaminofluorescein diacetate and 2',7'-dichlorodihydrofluorescein diacetate) and spectrophotometry (nitroblue tetrazolium). The relative sensitivity of these assays and their comparative ability to detect ROS generated in different subcellular compartments of human spermatozoa, have not previously been investigated. To address this issue, we have compared the performance of these assays when ROS generation was triggered with a variety of reagents including 2-hydroxyestradiol, menadione, 4-hydroxynonenal and arachidonic acid. The results revealed that menadione predominantly induced release of ROS into the extracellular space where these metabolites could be readily detected by luminol-peroxidase and, to a lesser extent, 2',7'-dichlorodihydrofluorescein. However, such sensitivity to extracellular ROS meant that these assays were particularly vulnerable to interference by leucocytes. The remaining reagents predominantly elicited ROS generation by the sperm mitochondria and could be optimally detected by MitoSOX Red and DHE. Examination of spontaneous ROS generation by defective human spermatozoa revealed that MitoSOX Red was the most effective indicator of oxidative stress, thereby emphasizing the general importance of mitochondrial dysregulation in the aetiology of defective sperm function.