It is well established that age-related decline of the biological capacity of a woman to reproduce is primarily related to the poor developmental potential of her gametes. This renders female ageing the most significant determinant of success in IVF. Starting with a reference picture of the main molecular and cellular failures of aged oocytes, granulosa cells and follicular microenvironment, this review focuses on age-related biochemical mechanisms underlying these changes. According to the most relevant concept of ageing, age-associated malfuction results from physiological accumulation of irreparable damage to biomolecules as an unavoidable side effect of normal metabolism. More than a decade after the free radical theory of ovarian ageing, biological and clinical research supporting the involvement of oxidative injuries in follicle ageing is discussed. Looking for the aetiology of oxidative stress, we consider the effect of ageing on ovarian and follicular vascularization. Then, we propose a potential role of advanced glycation end-products known to be involved in the physiological ageing of most tissues and organs. We conclude that future investigation of age-related molecular damage in the different ovarian components will be imperative in order to evaluate the possibility to save or rescue the developmental potential of aged oocytes.
Mitochondria of spermatozoa are different from the corresponding organelles of somatic cells, in both their morphology and biochemistry. The biochemical differences are essentially related to the existence of specific enzyme isoforms, which are characterized by peculiar kinetic and regulatory properties. As mitochondrial energy metabolism is a key factor supporting several sperm functions, these organelles host critical metabolic pathways during germ cell development and fertilization. Furthermore, spermatozoa can use different substrates, and therefore activate different metabolic pathways, depending on the available substrates and the physico-chemical conditions in which they operate. This versatility is critical to ensure fertilization success. However, the most valuable aspect of mitochondria function in all types of cells is the production of chemical energy in the form of ATP which can be used, in the case of spermatozoa, for sustaining sperm motility. The latter, on the other hand, represents one of the major determinants of male fertility. Accordingly, the presence of structural and functional alterations in mitochondria from asthenozoospermic subjects confirms the important role played by these organelles in energy maintenance of sperm motility. The present study gives an overview of the current knowledge on the energy-producing metabolic pathways operating inside human sperm mitochondria and critically analyse the differences with respect to somatic mitochondria. Such a comparison has also been carried out between the functional characteristics of human sperm mitochondria and those of other mammalian species. A deeper understanding of mitochondrial energy metabolism could open up new avenues of investigation in bioenergetics of human sperm mitochondria, both in physiological and pathological conditions.
In this work we report a relatively simple and fast method for analysing oxygen consumption and therefore mitochondrial functionality, in individual human ejaculates. This oxygraphic method requires a low number of cells, is highly reproducible and linearly correlates with sperm concentration. Our results have shown that oxygen uptake by mitochondria of demembranated sperm cells from normozoospermic subjects is significantly stimulated by a large set of respiratory substrates and ADP. The respiratory control ratio (RCR) values indicate a good coupling between respiration and phosphorylation by sperm mitochondria and thus a well preserved integrity of the mitochondria themselves. Interestingly, whereas the rates of oxygen uptake, as expected, changed with different sperm concentrations, the RCR values remained constant, thus demonstrating a linear response of the assay. In asthenozoospermic subjects, however, a significant decrease in the sperm respiratory efficiency was found. The results obtained suggest that this method, besides its potential clinical application, could be useful for a deeper understanding of the biochemical properties of sperm mitochondria and their role in ATP production in human spermatozoa.
Freshly ejaculated sperm acquire the fertilizing potential by a continuing process that occurs during sperm transport through the female genital tract, and it is physiologically not complete until the spermatozoon reaches the oocyte. The process termed capacitation can be mimicked in vitro by using appropriate capacitation media. Despite its importance, the molecular mechanisms underlying capacitation are poorly understood. This work deals with a proteomic approach to the analysis of protein profile variations in human normospermic samples as a consequence of three hours in vitro capacitation. 2DE gels were produced per freshly ejaculated sperm and per capacitated sperm and several quantitative and qualitative significant variations were found. Among the MS obtained identifications, proteins with a significant decrease after capacitation were found to be involved in protein fate, metabolism, and flagellar organization; on the contrary, increasing proteins were found to be related to cellular stress. Interestingly, the detected flagellar organization proteins decreased during capacitation whereas their corresponding fragments increased. A swim-up selected and three-hour capacitated sperm subpopulation has also been resolved by 2DE, and its synthetic gel has been analyzed for the variations observed in the entire sperm population. An immunofluorescence analysis of this sperm typology was carried out with antiactin and antitubulin antibodies.
The role of mitochondria in sperm motility was the subject of several investigations. However, different views on this topic emerged among scientists. In particular, very little is known on the mechanisms of energy production occurring during human sperm capacitation and related processes. In this study, we have investigated the mitochondrial respiratory efficiency in human sperm samples from normozoospermic subjects before and after swim-up selection and incubation under capacitating condition. Sperm cells, selected by swim-up treatment, were incubated up to 24 h and then demembranated by hypotonic swelling at selected times. The oxygen uptake rate was measured in both basal and swim-up selected samples by a polarographic assay. Mitochondria of swim-up selected cells showed an impressive oxygen consumption rate, which was about 20 times higher than that measured in basal samples. The high mitochondrial respiratory efficiency remained stable up to 24 h after the swim-up treatment. The respiration control ratio, the substrate specificity and the inhibitor sensitivity in the swim-up selected samples were similar to those of basal samples thereby suggesting that the physiology of mitochondria was preserved after the swim-up treatment. Furthermore, the remarkably high mitochondrial respiration in swim-up selected samples allowed the oxygraphic analysis of just 200,000 sperm cells. Sperm selection and incubation under capacitating condition are therefore associated with a high activity of the mitochondrial respiratory chain. The sperm oxygen consumption rate could be useful to exclude mitochondria malfunctioning in male infertility.
Our results suggest that a decrease in leukocytospermia after rofecoxib therapy was associated with recovery of all seminal characteristics in basal and swim-up selected samples. This general improvement could justify the positive outcome of ART after anti-inflammatory therapy.
BackgroundThe status characterized by the imbalance between pro-oxidants and antioxidants molecules, defined as oxidative stress, has been suggested to be involved in the pathogenesis of subfertility in females. This study aims to evaluate the impact of a complete micronutrients supplementation on oxidative stress levels in follicular microenvironment as well as on in vitro fertilization (IVF) outcome.MethodsThis preliminary study was conducted between January 2014 and July 2015 at the Siena University Hospital Infertility Clinic. Serum and follicular fluid were collected from infertile women aged > 39 years who underwent two in vitro fertilization cycles: in the first cycle they were treated with GnRH-antagonist protocol and gonadotropins for controlled ovarian hyperstimulation, whereas in the second cycle ovarian stimulation protocol was associated to micronutrients supplementation, starting three months earlier. Protein oxidation levels and total antioxidant capacity in serum and in follicular fluid were evaluated in IVF cycles with or without micronutrients supplementation. Differences in IVF outcome parameters were statistically evaluated.ResultsTwo-dimensional electrophoresis analyses demonstrated that when patients assumed micronutrients before IVF cycles, follicular fluid and serum proteins were protected from oxidative damage. Comparable results were obtained when total antioxidant capacity was measured. Moreover, the mean number of good quality oocytes retrieved when patients received micronutrients supplementation was significantly increased.ConclusionThe additional treatment with micronutrients, starting three months before IVF cycles, protects the follicular microenvironment from oxidative stress, thus increasing the number of good quality oocytes recovered at the pick up.
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