Project description:Our aim was to define seminal plasma proteome signatures of infertile patients categorized according to their seminal parameters using TMT-LC-MS/MS. To that extent, quantitative proteomic data was analyzed following two complementary strategies: (i) the conventional approach based on standard statistical analyses of relative protein quantification values; and (ii) a novel strategy focused on establishing stable-protein pairs. By conventional analyses, the abundance of some seminal plasma proteins was found to be positively correlated with sperm concentration. However, this correlation was not found for all the peptides within a specific protein, bringing to light the high heterogeneity existing in the seminal plasma proteome due to both the proteolytic fragments and/or the post-translational modifications. This issue was overcome by conducting the novel stable-protein pairs analysis proposed herein. A total of 182 correlations comprising 24 different proteins were identified in the normozoospermic-control population, while this proportion was drastically reduced in infertile patients with altered seminal parameters (18 in patients with reduced sperm motility, 0 in patients with low sperm concentration and 3 in patients with no sperm in the ejaculate). These results suggest the existence of multiple etiologies causing the same alteration in seminal parameters. Additionally, the repetition of the stable-protein pair analysis in the control group by adding the data from a single patient at a time enabled to identify alterations in the stable-protein pairs profile of individual patients with altered seminal parameters. These results suggest potential underlying pathogenic mechanisms in individual infertile patients, and might open up a window to its application in the personalized diagnostic of male infertility.

Project description:The male gamete is not completely mature after ejaculation and requires further events in the female genital tract to acquire fertilizing ability, including the processes of capacitation and acrosome reaction. In order to shed light on dynamic protein changes experienced by the sperm cell in preparation for fertilization, a comprehensive quantitative proteomic profiling based on isotopic peptide labeling and liquid chromatography followed by tandem mass spectrometry was performed on spermatozoa from three donors of proven fertility under three sequential conditions: purification with density gradient centrifugation, incubation with capacitation medium, and induction of acrosome reaction by the exposure to the calcium ionophore A23187. After applying strict selection criteria for peptide quantification and for statistical analyses, 36 proteins with significant changes in their relative abundance within sperm protein extracts were detected. Moreover, the presence of peptide residues potentially harboring sites for post-translational modification was revealed, suggesting that protein modification may be an important mechanism in sperm maturation. In this regard, increased levels of proteins mainly involved in motility and signaling, both regulated by protein modifiers, were detected in sperm lysates following incubation with capacitation medium. In contrast, less abundant proteins in acrosome-reacted cell lysates did not contain potentially modifiable residues, suggesting the possibility that all those proteins might be relocated or released during the process. Protein-protein interaction analysis revealed a subset of proteins potentially involved in sperm maturation, including ERLIN2, GGH, TMED 10, and ATP synthases. These results contribute to the current knowledge of the molecular basis of human fertilization and propose new candidates to be validated as modulators of male fertility.

Project description:Scarcely understood defects lead to asthenozoospermia which results in poor fertility outcomes. Incomplete knowledge of these defects hinders the development of new therapies and reliance on interventional therapies, such as in vitro fertilization, increases. Sperm cells, being transcriptionally and translationally silent, necessitate the proteomic approach to study the sperm funnction. We have performed a differential proteomics analysis of human sperm and seminal fluid and identified over 1,700 proteins. We have included 667 proteins in sperm and 430 proteins in seminal plasma dataset for further analysis. Statistical and mathematical analysis combined with pathway analysis and self organizing maps clustering and correlation was performed on the dataset. It was found that sperm proteomic signature combined with statistical analysis as opposed to the seminal plasma proteomic signature can differentiate the normozoospermic versus the asthenozoospermic sperm samples.

Project description:Seminal plasma contributes to the safe environment for sperm maturation, sperm viability and fertilization in mammals (Kumar 2013). Moreover, seminal plasma is a promising source for the study of potential reproductive biomarkers, because it is a complex mixture of secretions from testis, epididymis and male accessory sex glands (González-Cadavid et al. 2014). The protein composition of mammalian seminal plasma varies among species, and has important effects on sperm function (Mortarino et al. 1998). In rabbits, seminal plasma has a positive effect in maintaining sperm motility and viability during in vitro storage (Castellini et al. 2000). To study proteins on a large scale, the application of a proteomic approach is mandatory (Dietrich 2014). Rabbit seminal plasma proteome has been proved different between rabbit genetic line A (maternal) and R (growth) (Viudes-de-Castro et al. (2004), Safaa et al. (2008), Casares-Crespo 2016) and between seasons (Casares-Crespo 2016). In these previous studies a traditional 1 dimension polyacrylamide gel was done, identifying only major proteins visible after Coomassie Colloidal Blue staining and obtaining the relative quantity of these protein bands. On the contrary, new approaches such as liquid chromatography in-gel or in-solution digestion coupled with mass spectrometric analysis are a powerful, yet relatively uncomplicated strategy to identify and characterize proteins. Mass spectrometry-based proteomics has become the tool of choice for identifying and quantifying the proteome of an organism (Karpievitch 2010). Therefore, the present study was conducted to describe the seminal plasma proteome of rabbits, compare the differentially expressed seminal plasma proteins between genetic lines A and R and study the effect of season in rabbit seminal plasma proteome.

Project description:Breeding schemes for meat production in rabbits involved a three-way cross of specialized lines in which a paternal line inseminates maternal crossbred females. Paternal line or terminal sire are selected for growth traits, being the males used for the production of fertile dose at the insemination centres and farms. So high growth rate males must produce, in addition, semen in sufficient quantity and quality to meet the demand of insemination and, nevertheless, several studies have been showed that selection for growth have effects on reproduction performance in female and males. In rabbits, negative effects has been observed in ovulation induction, prenatal survival and genetic correlation to fertility. Many factors influence the production and quality of rabbit semen, management as collection frequency, environment (season or photoperiod, nutrition and genetic. Most of the previous studies have been focused in the effects of selection on the seminal and sperm parameters but, little attention has been paid to the protein seminal plasma or sperm composition and if these changes could be affect the fertility of seminal doses obtained from the paternal males. The aim of this study was to evaluate if selection program by daily gain in fattening period has changed seminal traits, plasma and sperm proteoma and, the fertility of semen when it is used in artificial insemination. To do this we uses two re-derived groups of paternal males obtained from vitrified embryos with a difference of 18 generations between both groups.

Project description:Breeding schemes for meat production in rabbits involved a three-way cross of specialized lines in which a paternal line inseminates maternal crossbred females. Paternal line or terminal sire are selected for growth traits, being the males used for the production of fertile dose at the insemination centres and farms. So high growth rate males must produce, in addition, semen in sufficient quantity and quality to meet the demand of insemination and, nevertheless, several studies have been showed that selection for growth have effects on reproduction performance in female and males. In rabbits, negative effects has been observed in ovulation induction, prenatal survival and genetic correlation to fertility. Many factors influence the production and quality of rabbit semen, management as collection frequency, environment (season or photoperiod, nutrition and genetic. Most of the previous studies have been focused in the effects of selection on the seminal and sperm parameters but, little attention has been paid to the protein seminal plasma or sperm composition and if these changes could be affect the fertility of seminal doses obtained from the paternal males. The aim of this study was to evaluate if selection program by daily gain in fattening period has changed seminal traits, plasma and sperm proteoma and, the fertility of semen when it is used in artificial insemination. To do this we uses two re-derived groups of paternal males obtained from vitrified embryos with a difference of 18 generations between both groups.

Project description:MTD project_description Protamines are testis-specific proteins, which replace the majority of histones during spermiogenesis. This results in a hypercondensation of the sperm DNA, finally causing a conformational change from a nucleosomal chromatin structure into a mainly toroid like structure. This is assumed to protect the paternal genome and to contribute to the formation of a hydrodynamic sperm head shape. In mice and humans, two protamines, Protamine 1 (Prm1) and Protamine 2 (Prm2), are expressed. Impaired sperm protamination has been repeatedly correlated with male subfertility in mice and humans. Apart from defects in DNA condensation and impaired DNA integrity, protamine-deficient human and murine sperm show multiple secondary defects, which cannot be explained by the chromosomal function of protamines. These include impaired sperm motility, decreased viability as well as acrsosomal malformations. In this study, we utilized a Prm2-deficient mouse model to investigate the underlying molecular mechanisms of these defects. Since trancription is silenced upon incorporation of protamines, we used LC-MS in combination with label-free quantification to compare the sperm proteome of Prm2-deficient (Prm2-/-) males with the proteome of wildtype (Prm2+/+) and Prm2 heterozygous (Prm2+/-) males. We show that Prm2 deficient mice display a strongly altered proteomic profile compared to controls. Of note, a significant downregulation of proteins SOD1 and PRDX5, which have a well-known function for the detoxification of reactive oxygen species was observed. Thus, together with a series of additional experiments, we could for the first time show that Prm2-deficiency triggers a reactive oxygen species (ROS) mediated sperm destruction cascade during epididymal sperm maturation, finally causing described secondary sperm defects.

Project description:A greater understanding of the proteins involved in reproduction can benefit animal production. New advances in proteomics are having a major impact on our understanding of how spermatozoa acquire their capacity for fertilization [1]. Sperm proteomics aims at the identification of the proteins that compose the sperm cell and the study of their function [2]. The sperm cell is one of the most highly differentiated cells and is composed of a head with a highly compacted chromatin structure and a large flagellum with midpiece that contains the required machinery for movement and therefore to deliver the paternal genetic and epigenetic content to the oocyte [3]. By being so highly differentiated, spermatozoa are advantageous cells to study proteomics of specific compartments such as the membrane, which basically is the area of major importance for its role in interacting with the surroundings and the oocyte [4]. The fusion of a sperm and an oocyte is a sophisticated process that must be preceded by suitable changes in the sperm's membrane composition [5]. Recent studies of spermatozoa from the proteomic point of view have allowed the identification of different proteins in spermatozoa that are responsible for the regulation of normal/defective sperm functions [6]. While several techniques are available in proteomics, LC-MS based analysis of complex protein/peptide mixtures has turned out to be a mainstream analytical technique for quantitative proteomics [7]. Using this method, detailed proteomic data are now available for human [8], macaque [9,10], mouse [11], rat [12], bull [13-15], stallion [16], fruit fly [17], Caenorhabditis elegans [18], carp [19], rainbow trout [20], mussel [21], ram [22], honeybee [23] and rooster [24] sperm membrane proteins. Rabbit (Oryctolagus cuniculus) is an important mammalian species worldwide, being at the same time of commercial interest and a research model animal. European rabbit meat production is approximately 500 thousand tons, corresponding to a 30% share of world production [25]. Besides, rabbits account for the seventh highest number of animals slaughtered per year in the European Union-27, with 347,603 × 1000 head in 2014 [26]. In a previous work, we identified and quantified rabbit seminal plasma proteins between two different genotypes [27], concluding the clear effect of genotype in the abundance of certain seminal plasma proteins. However, it is unknown at present whether these differences also exist at sperm proteome level. Therefore, the aim of the present study was to characterise rabbit sperm membrane proteins through NanoLC-MS/MS analysis focusing on the influence of the genetic origin.

Project description:PKA signaling plays important functions during mouse spermatogenesis and for the regulation of sperm motility. The efficiency of PKA signaling is regulated partly by its binding protein A-kinase anchoring protein (AKAP) family. Mature mouse sperm contain several AKAPs, of which AKAP3 and AKAP4 are localized in the principal piece of sperm tail and they are sperm-specific. Using gene knock-out mouse models, it was found that both AKAP3 and AKAP4 are essential for the formation of a complete fibrous sheath, the electron-dense sub-cellular structure within sperm flagellum that is important for the motility of sperm and male fertility. Lack of AKAP3 or AKAP4 caused aberrant sperm morphology and inmotility, leading to eventual male sterility. In the present study, we investigated the changes of cellular proteome in the absence of AKAP3 or AKAP4 in mature sperm, using quantitative mass spectrometry. It was found that global changes of sperm proteome occur in the absence of AKAP3 or AKAP4. In Akap3 null sperm, proteins related to flagella structure, PKA signaling and motility regulations are down-regulated, whereas proteins involved in RNA metabolism, protein translation and actin filaments formation are accumulated. Akap4 null sperm also displayed changes of sperm proteome at lesser extends. These results suggest that both AKAP3 and AKAP4 are essential for the formation of sperm sub-cellular structures, proper regulation of PKA activity and motility of sperm, providing new clues to elucidate the molecular pathways that underlie the coordinated synthesis and organization of sperm proteome and sperm morphology

Project description:Breeding schemes for meat production in rabbits involved a three-way cross of specialized lines in which a paternal line inseminates maternal crossbred females. Paternal line or terminal sire are selected for growth traits, being the males used for the production of fertile dose at the insemination centres and farms. So high growth rate males must produce, in addition, semen in sufficient quantity and quality to meet the demand of insemination and, nevertheless, several studies have been showed that selection for growth have effects on reproduction performance in female and males. In rabbits, negative effects has been observed in ovulation induction, prenatal survival and genetic correlation to fertility. Many factors influence the production and quality of rabbit semen, management as collection frequency, environment (season or photoperiod, nutrition and genetic. Most of the previous studies have been focused in the effects of selection on the seminal and sperm parameters but, little attention has been paid to the protein seminal plasma or sperm composition and if these changes could be affect the fertility of seminal doses obtained from the paternal males. The aim of this study was to evaluate if selection program by daily gain in fattening period has changed seminal traits, plasma and sperm proteoma and, the fertility of semen when it is used in artificial insemination. To do this we uses two re-derived groups of paternal males obtained from vitrified embryos with a difference of 18 generations between both groups.