Histone H4 acetylation is dysregulated in active seminiferous tubules adjacent to testicular tumours.

STUDY QUESTION: Is histone H4 acetylation (H4ac) altered in the seminiferous tubules of patients affected by testicular tumours? SUMMARY ANSWER: A considerable dysregulation of H4ac was detected in the cells of the seminiferous tubules adjacent to testicular tumours of different aetiology and prior to any treatment, while no comparable alterations were observed in patients with disrupted spermatogenesis. WHAT IS KNOWN ALREADY: Altered H4ac levels have been associated with a variety of testicular pathological conditions. However, no information has been available regarding potential alterations in the spermatogenic cells adjacent to the neoplasia in testicular tumour patients. STUDY DESIGN, SIZE, DURATION: A retrospective analysis using testicular sections from 33 men aged between 21 and 74 years old was performed. Three study groups were defined and subjected to double-blind evaluation: a control group with normal spermatogenesis (n = 6), patients with testicular tumours (n = 18) and patients with spermatogenic impairments (n = 8). One additional sample with normal spermatogenesis was used as a technical internal control in all evaluations. PARTICIPANTS/MATERIALS, SETTING, METHODS: Immunohistochemistry against H4ac and, when needed, Placental-like alkaline phosphatase and CD117, was performed on testicular sections. The H4ac H-score, based on the percentage of detection and signal intensity, was used as the scoring method for statistical analyses. Protein expression data from the Human Protein Atlas were used to compare the expression levels of predicted secreted proteins from testicular tumours with those present in the normal tissue. MAIN RESULTS AND THE ROLE OF CHANCE: We revealed, for the first time, a dramatic disruption of the spermatogenic H4ac pattern in unaffected seminiferous tubule cells from different testicular tumour patients prior to any antineoplastic treatment, as compared to controls (P < 0.05). Since no similar alterations were associated with spermatogenic impairments and the in silico analysis revealed proteins potentially secreted by the tumour to the testicular stroma, we propose a potential paracrine effect of the neoplasia as a mechanistic hypothesis for this dysregulation. LIMITATIONS, REASONS FOR CAUTION: Statistical analyses were not performed on the hypospermatogenesis and Leydig cell tumour groups due to limited availability of samples. WIDER IMPLICATIONS OF THE FINDINGS: To the best of our knowledge, this is the first report showing an epigenetic alteration in cells from active seminiferous tubules adjacent to tumour cells in testicular tumour patients. Our results suggest that, despite presenting spermatogenic activity, the global epigenetic dysregulation found in the testicular tumour patients could lead to molecular alterations of the male germ cells. Since testicular tumours are normally diagnosed in men at reproductive age, H4ac alterations might have an impact when these testicular tumour patients express a desire for fatherhood. STUDY FUNDING/COMPETING INTEREST(S): This work was supported by the European Union Marie Curie European Training Network actions and by grants to R.O. from the 'Ministerio de Economía y Competividad (Spain)' (fondos FEDER 'una manera de hacer Europa', PI13/00699, PI16/00346 and PI20/00936) and from EU-FP7-PEOPLE-2011-ITN289880. J.C. was supported by the Sara Borrell Postdoctoral Fellowship, Acción Estratégica en Salud, CD17/00109. J.C. is a Serra Húnter fellow (Universitat de Barcelona, Generalitat de Catalunya). F.B. has received grants from the Ministerio de Educación, Cultura y Deporte para la Formación de Profesorado Universitario (Spain) (FPU15/02306). A.d.l.I. is supported by a fellowship of the Ministerio de Economía, Industria y Competitividad (Spain) (PFIS, FI17/00224). M.J. is supported by the Government of Catalonia (Generalitat de Catalunya, pla estratègic de recerca i innovació en salut, PERIS 2016-2020, SLT002/16/00337). The authors have no conflicts of interest to declare. TRIAL REGISTRATION NUMBER: N/A.

The Role of Testosterone in Spermatogenesis: Lessons From Proteome Profiling of Human Spermatozoa in Testosterone Deficiency.

Testosterone is essential to maintain qualitative spermatogenesis. Nonetheless, no studies have been yet performed in humans to analyze the testosterone-mediated expression of sperm proteins and their importance in reproduction. Thus, this study aimed to identify sperm protein alterations in male hypogonadism using proteomic profiling. We have performed a comparative proteomic analysis comparing sperm from fertile controls (a pool of 5 normogonadic normozoospermic fertile men) versus sperm from patients with secondary hypogonadism (a pool of 5 oligozoospermic hypogonadic patients due to isolated LH deficiency). Sperm protein composition was analyzed, after peptide labelling with Isobaric Tags, via liquid chromatography followed by tandem mass spectrometry (LC-MS/MS) on an LTQ Velos-Orbitrap mass spectrometer. LC-MS/MS data were analyzed using Proteome Discoverer. Criteria used to accept protein identification included a false discovery rate (FDR) of 1% and at least 1 peptide match per protein. Up to 986 proteins were identified and, of those, 43 proteins were differentially expressed: 32 proteins were under-expressed and 11 were over-expressed in the pool of hypogonadic patients compared to the controls. Bioinformatic analyses were performed using UniProt Knowledgebase, and the Gene Ontology Consortium database based on PANTHER. Notably, 13 of these 43 differentially expressed proteins have been previously reported to be related to sperm function and spermatogenesis. Western blot analyses for A-Kinase Anchoring Protein 3 (AKAP3) and the Prolactin Inducible Protein (PIP) were used to confirm the proteomics data. In summary, a high-resolution mass spectrometry-based proteomic approach was used for the first time to describe alterations of the sperm proteome in secondary male hypogonadism. Some of the differential sperm proteins described in this study, which include Prosaposin, SMOC-1, SERPINA5, SPANXB1, GSG1, ELSPBP1, fibronectin, 5-oxoprolinase, AKAP3, AKAP4, HYDIN, ROPN1B, ß-Microseminoprotein and Protein S100-A8, could represent new targets for the design of infertility treatments due to androgen deficiency.

Protamine Characterization by Top-Down Proteomics: Boosting Proteoform Identification with DBSCAN.

Protamines replace histones as the main nuclear protein in the sperm cells of many species and play a crucial role in compacting the paternal genome. Human spermatozoa contain protamine 1 (P1) and the family of protamine 2 (P2) proteins. Alterations in protamine PTMs or the P1/P2 ratio may be associated with male infertility. Top-down proteomics enables large-scale analysis of intact proteoforms derived from alternative splicing, missense or nonsense genetic variants or PTMs. In contrast to current gold standard techniques, top-down proteomics permits a more in-depth analysis of protamine PTMs and proteoforms, thereby opening up new perspectives to unravel their impact on male fertility. We report on the analysis of two normozoospermic semen samples by top-down proteomics. We discuss the difficulties encountered with the data analysis and propose solutions as this step is one of the current bottlenecks in top-down proteomics with the bioinformatics tools currently available. Our strategy for the data analysis combines two software packages, ProSight PD (PS) and TopPIC suite (TP), with a clustering algorithm to decipher protamine proteoforms. We identified up to 32 protamine proteoforms at different levels of characterization. This in-depth analysis of the protamine proteoform landscape of normozoospermic individuals represents the first step towards the future study of sperm pathological conditions opening up the potential personalized diagnosis of male infertility.

Altered mitochondrial function in spermatozoa from patients with repetitive fertilization failure after ICSI revealed by proteomics.

BACKGROUND: Unexplained fertilization failure (FF), occurring in 1-3% of intracytoplasmic sperm injection (ICSI) cycles, results in both psychological and financial burden for the patients. However, the molecular causes behind FF remain largely unknown. Mass spectrometry is a powerful technique to identify and quantify proteins across samples; however, no study so far has used it to dissect the proteomic signature of spermatozoa with FF after ICSI. OBJECTIVE: To investigate whether sperm samples from patients suffering repetitive FF after ICSI display alterations in their protein content. MATERIAL AND METHODS: Seventeen infertile men were included: 5 patients presented FF in ≥3 consecutive ICSI cycles, while 12 patients had a fertilization rate >75% (controls). Individual sperm samples were subjected to 2D-LC-MS/MS. Both conventional and novel statistical approaches were used to identify differentially abundant proteins. Additionally, analysis of mitochondrial and proteasomal abundance and activity were performed, using Western blot, FACS analysis of JC-1 staining and AMC-peptide fluorometric assay. RESULTS: Four proteins presented lower abundance (FMR1NB, FAM209B, RAB2B, and PSMA1) in the FF group compared to controls, while five mitochondrial proteins presented higher abundance in FF (DLAT, ATP5H, SLC25A3, SLC25A6, and FH) (p < 0.05). The altered abundance of mitochondrial DLAT and proteasomal PSMA1 was corroborated by Western blot. Of relevance, novel stable-protein pair analysis identified 73 correlations comprising 28 proteins within controls, while different mitochondrial proteins (ie, PDHA2, PHB2, and ATP5F1D) lost >50% of these correlations in specific FF samples pointing out specific mitochondrial deregulations. DISCUSSION: This is the first proteomic analysis of spermatozoa from patients who resulted in fertilization failure after ICSI. The altered proteins, most of them related to mitochondrial function, could help to identify diagnostic/prognostic markers of fertilization failure and could further dissect the molecular paternal contribution to reach successful fertilization. CONCLUSION: Sperm samples from patients with FF after ICSI present altered abundance of different proteins, including mainly mitochondrial proteins.

Sperm proteomic changes associated with early embryo quality after ICSI.

RESEARCH QUESTION: Do alterations of human sperm protein profile affect embryo quality? DESIGN: Sperm proteins from 27 infertile couples undergoing intracytoplasmic sperm injection (ICSI) were extracted and digested. The resulting peptides were labelled using tandem mass tags, separated by two-dimensional liquid chromatography, and identified and quantified using tandem mass spectrometry. Subsequently, sperm protein and peptide abundance were statistically analysed for correlation with ICSI-derived embryo quality in the subset of idiopathic infertile couples. Detected correlations were further assessed in the subset of infertile patients with a known factor. RESULTS: The abundance of 18 individual sperm proteins was found to correlate with embryo quality after ICSI. Of note, a high percentage of poor-quality ICSI-derived embryos was associated with alterations in several components of the eight-membered chaperonin-containing T-complex, which plays an important role in the folding of many essential proteins. Additionally, the abundance of sperm proteins with known functions in embryogenesis, such as RUBVL1, also correlated with early embryo quality (r = -0.547; P = 0.028). Some of the correlations found in this study were validated using either proteomic data from infertile patients with a known factor or data from similar published studies. Analysis at the peptide level revealed the association of some correlations with specific post-translational modifications or isoforms. CONCLUSIONS: Our results support the hypothesis that the sperm proteome plays a role in early embryogenesis. Moreover, several sperm proteins have emerged as potential biomarkers that could predict the outcome of in-vitro assisted reproductive technologies, leading to the possibility of improved diagnosis of couples with idiopathic infertility.

Characterization of Human Sperm Protamine Proteoforms through a Combination of Top-Down and Bottom-Up Mass Spectrometry Approaches.

Protamine 1 (P1) and protamine 2 (P2) family are extremely basic, sperm-specific proteins, packing 85-95% of the paternal DNA. P1 is synthesized as a mature form, whereas P2 components (HP2, HP3, and HP4) arise from the proteolysis of the precursor (pre-P2). Due to the particular protamine physical-chemical properties, their identification by standardized bottom-up mass spectrometry (MS) strategies is not straightforward. Therefore, the aim of this study was to identify the sperm protamine proteoforms profile, including their post-translational modifications, in normozoospermic individuals using two complementary strategies, a top-down MS approach and a proteinase-K-digestion-based bottom-up MS approach. By top-down MS, described and novel truncated P1 and pre-P2 proteoforms were identified. Intact P1, pre-P2, and P2 mature proteoforms and their phosphorylation pattern were also detected. Additionally, a +61 Da modification in different proteoforms was observed. By the bottom-up MS approach, phosphorylated residues for pre-P2, as well as the new P2 isoform 2, which is not annotated in the UniProtKB database, were revealed. Implementing these strategies in comparative studies of different infertile phenotypes, together with the evaluation of P1/P2 and pre-P2/P2 MS-derived ratios, would permit determining specific alterations in the protamine proteoforms and elucidate the role of phosphorylation/dephosphorylation dynamics in male fertility.

Stable-protein Pair Analysis as A Novel Strategy to Identify Proteomic Signatures: Application To Seminal Plasma From Infertile Patients.

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: (1) the conventional approach based on standard statistical analyses of relative protein quantification values; and (2) 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 because of 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, whereas 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.

Mammalian Sperm Protamine Extraction and Analysis: A Step-By-Step Detailed Protocol and Brief Review of Protamine Alterations.

BACKGROUND: Protamines are the most abundant sperm nuclear proteins and pack approximately the 92-98% of the mammalian sperm DNA. In mammals, two types of protamines have been described, the Protamine 1 (P1) and the Protamine 2 (P2) family. The deregulation of the relative P1/P2 ratio has been correlated to DNA damage, alterations in seminal parameters, and low success rate of assisted reproduction techniques. Additionally, the extraction and analysis of protamines have been important to understand the fundamental aspects of the sperm chromatin structure and function, protamine sequence conservation among species, and sperm chromatin alterations present in infertile males. However, protamines show a particular chemical nature due to its special amino acid sequence, extremely rich in arginine and cysteine residues. Because of these peculiar characteristics of protamines, their extraction and analysis is not as straightforward as the analysis of other chromatin-associated proteins, for which many detailed protocols are already available. CONCLUSION: A step-by-step protocol was needed to facilitate protamine analysis to researchers interested in their implementation. Therefore, in order to contribute to fulfill this need, here we provide a detailed protocol, which should be useful to research teams and laboratories interested in the protamine field. In addition, we also briefly review the different studies published so far on protamine alterations and male infertility.

Semen proteomics and male infertility.

Semen is a complex body fluid containing an admixture of spermatozoa suspended in secretions from the testes and epididymis which are mixed at the time of ejaculation with secretions from other accessory sex glands such as the prostate and seminal vesicles. High-throughput technologies have revealed that, contrary to the idea that sperm cells are simply a silent delivery vehicle of the male genome to the oocyte, the sperm cells in fact provide both a specific epigenetically marked DNA together with a complex population of proteins and RNAs crucial for embryogenesis. Similarly, -omic technologies have also enlightened that seminal fluid seems to play a much greater role than simply being a medium to carry the spermatozoa through the female reproductive tract. In the present review, we briefly overview the sperm cell biology, consider the key issues in sperm and seminal fluid sample preparation for high-throughput proteomic studies, describe the current state of the sperm and seminal fluid proteomes generated by high-throughput proteomic technologies and provide new insights into the potential communication between sperm and seminal fluid. In addition, comparative proteomic studies open a window to explore the potential pathogenic mechanisms of infertility and the discovery of potential biomarkers with clinical significance. SIGNIFICANCE: The review updates the numerous proteomics studies performed on semen, including spermatozoa and seminal fluid. In addition, an integrative analysis of the testes, sperm and seminal fluid proteomes is also included providing insights into the molecular mechanisms that regulate the generation, maturation and transit of spermatozoa. Furthermore, the compilation of several differential proteomic studies focused on male infertility reveals potential pathways disturbed in specific subtypes of male infertility and points out towards future research directions in the field.