Meritxell Jodar

Differential RNAs in the sperm cells of asthenozoospermic patients

BACKGROUND Alterations in RNAs present in sperm have been identified using microarrays in teratozoospermic patients and in other types of infertile patients. However, so far, there have been no reports on using microarrays to determine the RNA content of sperm from asthenozoospermic patients. METHODS We started the present project with the goal of characterizing the RNA abundance in the sperm cells of asthenozoospermic patients when compared with controls. To reach this objective, we initially selected four normal fertile donors and four asthenozoospermic infertile patients. Equal amounts of RNA were extracted from the sperm samples, subjected to different quality controls and hybridized to the Affymetrix U133 Plus version 2 arrays. RESULTS Several transcripts were identified that were present in different abundance in patients compared with controls. Subsequently, we validated the differential expression of three of the detected transcripts (ANXA2, BRD2 and OAZ3), using real-time PCR in a larger set of samples. A positive correlation between the expression of these transcripts and progressive motility was observed. CONCLUSIONS The sperm cells of asthenozoospermic patients contain an altered amount of some RNAs as detected using microarray analysis and subsequently validated using real-time PCR. These results open up the possibility to investigate the implication of these genes in the pathogenic mechanisms in asthenozoospermia and to consider their potential utility as infertility biomarkers.

The small RNA content of human sperm reveals pseudogene-derived piRNAs complementary to protein-coding genes

At the end of mammalian sperm development, sperm cells expel most of their cytoplasm and dispose of the majority of their RNA. Yet, hundreds of RNA molecules remain in mature sperm. The biological significance of the vast majority of these molecules is unclear. To better understand the processes that generate sperm small RNAs and what roles they may have, we sequenced and characterized the small RNA content of sperm samples from two human fertile individuals. We detected 182 microRNAs, some of which are highly abundant. The most abundant microRNA in sperm is miR-1246 with predicted targets among sperm-specific genes. The most abundant class of small noncoding RNAs in sperm are PIWI-interacting RNAs (piRNAs). Surprisingly, we found that human sperm cells contain piRNAs processed from pseudogenes. Clusters of piRNAs from human testes contain pseudogenes transcribed in the antisense strand and processed into small RNAs. Several human protein-coding genes contain antisense predicted targets of pseudogene-derived piRNAs in the male germline and these piRNAs are still found in mature sperm. Our study provides the most extensive data set and annotation of human sperm small RNAs to date and is a resource for further functional studies on the roles of sperm small RNAs. In addition, we propose that some of the pseudogene-derived human piRNAs may regulate expression of their parent gene in the male germline.

Polymorphisms, haplotypes and mutations in the protamine 1 and 2 genes

Protamines are the most abundant nuclear proteins and alterations in their expression have been described in infertile patients. Also, protamine haplo-insufficient mice have been described as infertile. Therefore, the protamine 1 and 2 genes have been considered important candidates in different mutational studies. In this article, we review all published articles related to protamine gene mutations and report new data on mutations from patients and controls drawn from the Spanish and Swedish populations. Sequencing of the protamine 1 and 2 genes in a total of 209 infertile patients and 152 fertility-proven controls from the Spanish and Swedish populations identified two novel and rare non-pathogenic missense mutations (R17C and R38M) in the protamine 1 gene and several additional polymorphisms. Furthermore, we have identified and we report for the first time five novel rare haplotypes encompassing the protamine 1 and 2 genes. A review of all available protamine gene mutational studies indicates that none of the reported missense mutations can be considered of proven pathogenicity. However, it is interesting to note that rare protamine 1 promoter variants have been reported only in infertile patients, but not in fertile control groups. Pathogenic high penetrance protamine gene missense mutations, if any, must be extremely rare. However, the detected presence of rare variants and haplotypes in infertile patients deserves further investigation.

Protamine Alterations in Human Spermatozoa

Protamines are the major nuclear proteins in sperm cells, having a crucial role in the correct packaging of the paternal DNA. The fact that protamine haploinsufficiency in mice resulted in abnormal chromatin packaging and male infertility suggested that the protamines could also be important candidates in explaining some of the idiopathic male infertility cases in humans. The first clinical studies focused on analyzing protamines at the protein level. Various studies have found the presence of an altered amount of protamines in some infertile patients, in contrast to the normal situation in fertile individuals where the two protamines, protamine 1 and protamine 2, are both present in approximately equal quantities. Subsequently, the protamine genes were the subject of various mutational genetic screening studies in search of variants that could be associated with deregulation in the protamine expression observed. The results of these protamine mutational studies showed that the presence of high penetrant mutations is a very rare cause of male infertility. However, some variants and some haplotypes described may behave as risk factors for male infertility. More recently, the presence of RNA in the mature sperm cell has also been investigated. The present chapter will introduce the basic aspects of protamine evolution and function and review the various articles published to date on the relationship between the protamines studied at the DNA, RNA, and protein levels 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.

Sperm Nucleoproteins (Histones and Protamines)

Sperm nuclear architecture is unique, since sperm chromatin is packaged in many species by protamines, which are more basic and smaller than histones. The multistep procedure of histone exchange and its replacement by protamines during the late steps of spermatogenesis in mammals is a complex controlled process that requires the contribution of histone variants, histone posttranslational modifications (PTMs), transition proteins, remodeling machinery, and protamines. In the mature human sperm, while 85–95% of the mature sperm chromatin is bound to protamines, a small percentage of the chromatin (5–15%) remains bound to histones. An altered protamine ratio or an altered histone content or distribution in sperm indicates an abnormal chromatin packaging that can lead to male infertility through an increased susceptibility to DNA damage or abnormal epigenetic marking. However, little is known about how the differential distribution of genes in the sperm chromatin (nucleohistone and nucleoprotamine complexes) could impact in the early embryo development. It is suggested that histone variants and its PTMs and, perhaps, in conjunction with protamine PTMs, all together maintained in the mature sperm, could be involved in gene expression in early embryogenesis and transgenerational epigenetic inheritance.

Identification of a complex population of chromatin-associated proteins in the European sea bass (Dicentrarchus labrax) sperm

ABSTRACT A very common conception about the function of the spermatozoon is that its unique role is to transmit the paternal genome to the next generation. Most of the sperm genome is known to be condensed in many species by protamines, which are small and extremely positively charged proteins (50–70% arginine) with the functions of streamlining the sperm cell and protecting its DNA. However, more recently, it has been shown in mammals that 2–10% of its mature sperm chromatin is also associated to a complex population of histones and chromatin-associated proteins differentially distributed in the genome. These proteins are transferred to the oocyte upon fertilization and may be involved in the epigenetic marking of the paternal genome. However, little information is so far available on the additional potential sperm chromatin proteins present in other protamine-containing non-mammalian vertebrates detected through high-throughput mass spectrometry. Thus, we started the present work with the goal of characterizing the mature sperm proteome of the European sea bass, with a particular focus on the sperm chromatin, chosen as a representative of non-mammalian vertebrate protamine-containing species. Proteins were isolated by acidic extraction from purified sperm cells and from purified sperm nuclei, digested with trypsin, and subsequently the peptides were separated using liquid chromatography and identified through tandem mass spectrometry. A total of 296 proteins were identified. Of interest, the presence of 94 histones and other chromatin-associated proteins was detected, in addition to the protamines. These results provide phylogenetically strategic information, indicating that the coexistence of histones, additional chromatin proteins, and protamines in sperm is not exclusive of mammals, but is also present in other protamine-containing vertebrates. Thus, it indicates that the epigenetic marking of the sperm chromatin, first demonstrated in mammals, could be more fundamental and conserved than previously thought. Abbreviations: AU-PAGE: acetic acid–urea polyacrylamide gel electrophoresis; CPC: chromosomal passenger complex; DTT: dithiothreitol; EGA: embryonic genome activation; FDR: false discovery rate; GO: Gene Ontology; IAA: iodoacetamide; LC: liquid chromatography; LC-MS/MS: liquid chromatography coupled to tandem mass spectrometry; MS: mass spectrometry; MS/MS: tandem mass spectrometry; MW: molecular weight; PAGE: polyacrylamide gel electrophoresis; PBS: phosphate buffered saline; SDS: sodium dodecyl sulfate; SDS-PAGE: sodium dodecyl sulfate polyacrylamide gel electrophoresis; TCA: trichloroacetic acid.

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.

The contribution of human sperm proteins to the development and epigenome of the preimplantation embryo.

BACKGROUND Knowledge of the proteomic composition of the gametes is essential to understand reproductive functions. Most of the sperm proteins are related to spermatogenesis and sperm function, but less abundant protein groups with potential post-fertilization roles have also been detected. The current data are challenging our understanding of sperm biology and functionality, demanding an integrated analysis of the proteomic and RNA-seq datasets available for spermatozoa, oocytes and early embryos, in order to unravel the impact of the male gamete on the generation of the new individual. OBJECTIVE AND RATIONALE The aim of this review is to compile human sperm proteins and to identify and infer their origin and discuss their relevance during oocyte fecundation, preimplantation embryogenesis and epigenetic inheritance. SEARCH METHODS The scientific literature was comprehensively searched for proteomic studies on human sperm, oocytes, embryos, and additional reproductive cells and fluids. Proteins were compiled and functionally classified according to Gene Ontology annotations and the mouse phenotypes integrated into the Mouse Genome Informatics database. High-throughput RNA datasets were used to decipher the origin of embryo proteins. The tissue origin of sperm proteins was inferred on the basis of RNA-seq and protein data available in the Human Protein Atlas database. OUTCOMES So far, 6871 proteins have been identified and reported in sperm, 1376 in the oocyte and 1300 in blastocyst. With a deeper analysis of the sperm proteome, 103 proteins with known roles in the processes of fertilization and 93 with roles in early embryo development have been identified. Additionally, 560 sperm proteins have been found to be involved in modulating gene expression by regulation of transcription, DNA methylation, histone post-translational modifications and non-coding RNA biogenesis. Some of these proteins may be critical for gene expression regulation after embryo genome activation, and therefore, may be potentially involved in epigenetic transmission of altered phenotypes. Furthermore, the integrative analysis of the sperm, oocyte and blastocyst proteomes and transcriptomes revealed a set of embryo proteins with an exclusive paternal origin, some of which are crucial for correct embryogenesis and, possibly, for modulation of the offspring phenotype. The analysis of the expression of sperm proteins, at both RNA and protein levels, in tissues not only from the male reproductive tract but also from peripheral organs, has suggested a putative extra-testicular origin for some sperm proteins. These proteins could be imported into sperm from the accessory sex glands and other tissues, most likely through exosomes. WIDER IMPLICATIONS These integrative proteome and transcriptome analyses focused on specific groups of proteins, rather than on enriched pathways, identified important sperm proteins which may be involved in early embryogenesis and provided evidence which could support the hypothesis of paternal epigenetic inheritance. The putative extra-testicular origin of some sperm proteins suggests not only the involvement of accessory sex glands in fertilization and epigenetic information transmission, but also that some proteins from additional organs could possibly contribute information to the offspring phenotype. These findings should stimulate further research in the field.

Estudio mutacional del gen HSPA2 en pacientes estériles y en controles

Mutational study of the HSPA2 gene in infertile patients and controls Objectives: We started the present work to perform a mutational study on the HSPA2 gene in different types of infertile patients. The rationale for this work is based on the results of previous studies which suggest that the HSPA2 gene may be a candidate gene to explain some of the cases of infertility.