Development of a model for studying the developmental consequences of oxidative sperm DNA damage by targeting redox-cycling naphthoquinones to the Sertoli cell population.

Oxidative stress can be induced in the testes by a wide range of factors, including scrotal hyperthermia, varicocele, environmental toxicants, obesity and infection. The clinical consequences of such stress include the induction of genetic damage in the male germ line which may, in turn, have serious implications for the health and wellbeing of the progeny. In order to confirm the transgenerational impact of oxidative stress in the testes, we sought to develop an animal model in which this process could be analysed. Our primary approach to this problem was to induce Sertoli cells (robust, terminally differentiated, tissue-specific testicular cells whose radioresistance indicates significant resistance to oxidative stress) to generate high levels of reactive oxygen species (ROS) within the testes. To achieve this aim, six follicle-stimulating hormone (FSH) peptides were developed and compared for selective targeting to Sertoli cells both in vitro and in vivo. Menadione, a redox-cycling agent, was then conjugated to the most promising FSH candidate using a linker that had been optimised to enable maximum production of ROS in the targeted cells. A TM4 Sertoli cell line co-incubated with the FSH-menadione conjugate in vitro exhibited significantly higher levels of mitochondrial ROS generation (10-fold), lipid peroxidation (2-fold) and oxidative DNA damage (2-fold) than the vehicle control. Additionally, in a proof-of-concept study, ten weeks after a single injection of the FSH-menadione conjugate in vivo, injected male mice were found to exhibit a 1.6 fold increase in DNA double strand breaks and 13-fold increase in oxidative DNA damage to their spermatozoa while still retaining their ability to initiate a pregnancy. We suggest this model could now be used to study the influence of chronic oxidative stress on testicular function with emphasis on the impact of DNA damage in the male germ line on the mutational profile and health of future generations.

Functions and effects of reactive oxygen species in male fertility.

Reactive oxygen species (ROS) are implicated in all aspects of cellular functions. While the importance of ROS as signalling molecules is well described, ROS are also associated with stress pathologies. Within the reproduction field, there are associations with reduced fertility as a result of lipid peroxidation, protein dysfunction, premature cell death and DNA damage which readily occur in spermatozoa. These oxidative insults can arise in vivo, or in vitro as a result of sperm storage, purification and processing. Following a brief description of the production, homeostasis and functions of ROS in mammalian sperm function, this review paper will focus on describing the predominant sources of ROS in the ejaculate, the effects of ROS on a cellular and molecular level, and the actions of ROS from the whole animal perspective. There is highlighting of some studies, which have revealed the mechanisms for these observations, along with some strategies to ameliorate or prevent the instigation of the oxidative stress cascade before irreversible damage to spermatozoa occurs.