Biology of spermatozoa maturation: an overview with an introduction to this issue

Mammalian spermatozoa undergo morphological, biochemical, and physiological modifications initially in the testis (testicular maturation) and later in the epididymis (epididymal maturation). These maturational changes are commensurate with the functional events that occur in developing germ cells and maturing spermatozoa. This special issue reviews the recent, relevant topics dealing with spermatozoa maturation and focuses on the events that occur in internal components such as the nucleus, the acrosome, the perinuclear theca, the fibrous sheath, and the cytoplasmic droplet as well as the plasma membrane. These structures/elements and the constituent proteins of which they are comprised undergo a variety of sequential modifications starting from their origination in developing germ cells up to epididymal maturation. Several steps of the maturation processes on the sperm plasma membrane are mediated by external enzymes and secretions derived from the epithelium lining of the genital tract. Degradation of some of the constituent proteins and the elimination of defective spermatozoa are controlled by the degradation/recycling system, the ubiquitin system. These maturational modifications are necessary for spermatozoa to become fertilization-competent cells and to be stored safely in the male.     

Structural modification of the hamster sperm acrosome during posttesticular development in the epididymis

The acrosome of the mature spermatozoon functions as a regulated secretory vesicle which performs several critical functions in mammalian fertilization. Acrosome assembly occurs throughout spermiogenesis and continues during posttesticular sperm maturation in the epididymis, resulting in a structurally polarized membrane-bounded organelle that contains an assortment of hydrolases and a stable infrastructure termed the acrosomal matrix. The role of stable acrosomal matrix assemblies in acrosomal biogenesis and function are poorly understood. This article presents ultrastructural, immunocytochemical, and biochemical data on the remodeling of the hamster acrosomal matrix during spermiogenesis and posttesticular sperm maturation in the epididymis. Specific posttranslational modifications of the major acrosomal matrix protein are evident in late, step 16, spermatids and matrix protein processing continues within specific acrosomal subdomains of caput epididymal spermatozoa. At the completion of sperm maturation, the acrosomal matrix consists of two structurally distinct domains which are adherent to the outer acrosomal membrane and exhibit a localized distribution pattern. Coincident with acrosomal matrix differentiation, a paracrystalline cytoskeletal complex is assembled onto the outer acrosomal membrane of epididymal spermatozoa. This cytoskeletal network appears to establish transmembrane structural interactions with the acrosomal matrix and may maintain attachment of the acrosomal cap to the sperm head during the early steps of the acrosome reaction.     

Protein detection in spermatids and spermatozoa of the butterfly Euptoieta hegesia (Lepidoptera).

This study was undertaken to detect protein components in both sperm types of the butterfly Euptoieta hegesia. These spermatozoa possess complex extracellular structures for which the composition and functional significance are still unclear. In the apyrene sperm head, the proteic cap presented an external ring and an internal dense content; basic proteins were detected only in external portions. In the tail, the paracrystalline core of mitochondrial derivatives and the axoneme are rich in proteins. The extratesticular spermatozoa are covered by a proteic coat, which presented two distinct layers. In eupyrene spermatozoa, acrosome and nucleus were negatively stained, probably because of their high compaction. In the tail, there is no paracrystalline core and the axoneme presented a very specific reaction for basic proteins. The lacinate and reticular appendages are composed of cylindrical sub-units and presented a light reaction to E-PTA and a strong reaction to tannic acid. A complex proteic coat also covers the extratesticular spermatozoa. We found similarities between both extratesticular coats, indicating a possible common origin. Both spermatozoon types are rich in proteins, especially the eupyrene appendages and the extratesticular coats. We believe that both coats are related to the sperm maturation and capacitation processes.     

Interactions of sperm perinuclear theca with the oocyte: implications for oocyte activation,anti-polyspermy defense,and assisted reproduction

Perinuclear theca (PT) is the cytoskeletal coat of mammalian sperm nucleus that is removed from the sperm head at fertilization. PT harbors the sperm borne, oocyte-activating factor (SOAF), a yet-to-be-characterized substance responsible for triggering the signaling cascade of oocyte activation, thought to be dependent on intra-oocyte calcium release. The present article reviews the current knowledge on the biogenesis and molecular composition of sperm PT. Possible functions of sperm PT during natural and assisted fertilization, and in the initiation of embryonic development are discussed. Furthermore, evidence is provided that SOAF is transferred from the sperm PT to oocyte cytoplasm through the internalization and rapid solubilization of the post-acrosomal PT. It is shown that during natural fertilization the sperm PT dissolves in the oocyte cytoplasm concomitantly with sperm nuclear decondensation and the initiation of pronuclear development. SOAF activity is preserved in the differentially extracted sperm heads only if the integrity of PT is maintained. After intracytoplasmic sperm injection (ICSI), activation occurs only in those oocytes in which the injected spermatozoon displays complete or partial dissolution of PT. In the latter case, the residual PT of the sub-acrosomal and/or post-acrosomal sperm region may persist on the apical surface of the sperm nucleus/male pronucleus and may cause a delay or arrest of zygotic development. We propose that the sperm PT harbors SOAF in the post-acrosomal sheath, as this is the first part of the sperm cytosol to enter the oocyte cytoplasm and its disassembly appears sufficient to initiate the early events of oocyte activation. Dissolution of the sub-acrosomal part of the PT, on the other hand, appears necessary to insure complete DNA decondensation in the internalized sperm nucleus and initiate DNA synthesis of both pronuclei. The release of the SOAF from the sperm head into oocyte cytoplasm at fertilization ultimately leads to the activation of oocyte mechanism including the completion of the meiotic cell cycle, pronuclear development and anti-polyspermy defense.     

In vitro fertilization and polyspermy in the pig: factors affecting fertilization rates and cytoskeletal reorganization of the oocyte

Polyspermy is a common phenomenon in the pig. Extensive information has become available from in vitro studies on not only the quality of oocytes but also the quality of spermatozoa. However, little information is available on the relative penetration rates of fresh and frozen spermatozoa from the same ejaculate from boars of different breeds. The present results, based on a total of 15 boars of three different breeds, revealed that the inter-breed variation in fertilization and polyspermic rates is larger than intra-breed variation. It was also shown that the incidence of polyspermy as well as penetration rate was greatly decreased by freezing and thawing, even if a higher number of sperm was coincubated with cumulus-free oocytes for a longer period compared to fresh sperm of the same ejaculate. This study focuses on the cytoskeletal organization of the oocyte with respect to the status of cumulus investment, and monospermic and polyspermic fertilization. The status of cumulus cells correlated with the density of transzonal cumulus-cell processes and with the maturation rate of oocytes and, to some degrees, the incidence of polyspermy. Polyspermic zygotes formed multiple microtubule domains in association with individual male pronuclei (PN), but in a high degree of polyspermy (more than trispermy), the pronuclear apposition did not proceed. The effect of multiple PN of paternal and maternal origin on the cytoskeletal reorganization is also discussed.     

Glycan modifying enzymes in luminal fluid of rat epididymis: are they involved in altering sperm surface glycoproteins during maturation?

Testicular spermatozoa undergo morphological and biochemical alterations, collectively termed epididymal maturation, in the intraluminal environment of epididymis. As a result of these modifications, the spermatozoon becomes a motile and functionally competent cell capable of undergoing capacitation and binding to the zona pellucida, the extracellular coat that surrounds the mammalian oocyte. Although details of all the changes are not fully known, several studies provide evidence suggesting that sperm plasma membrane undergoes extensive biochemical changes, including organization and modification of surface glycoproteins as spermatozoa transit from the proximal to the distal epididymis. In this article, I have attempted to summarize results with two sets of glycoprotein (glycan)-modifying enzymes, namely, glycohydrolases (hydrolytic enzymes) and glycosyltransferases (synthetic enzymes) present in the epididymal luminal fluid (LF). The in vitro experimental approaches described in this report demonstrate that: 1) a PNA-positive glycoprotein(s) (containing O-linked glycan) of 135-150 kDa subunit molecular mass which is present on the surface of caput (but not the cauda) spermatozoa can be degalactosylated by the enzymatic digestion with LF beta-D-galactosidase; and 2) an N-linked glycan chain(s) which is present on a sperm surface glycoprotein (apparent subunit molecular mass of 86 kDa) can be fucosylated in vitro when distal caput sperm (or sperm plasma membrane-rich fractions) are incubated in the presence of a nucleotide sugar (GDP[(14)C]fucose). Combined, these results strongly suggest a role for the glycan-modifying enzymes in degalactosylation and fucosylation of sperm surface glycoproteins during epididymal transit.     

Organization and modifications of sperm acrosomal molecules during spermatogenesis and epididymal maturation

The mammalian acrosome is a highly specialized organelle overlying the anterior part of the sperm nucleus and contains a variety of proteins, including hydrolytic enzymes and matrix molecules. Functionally, the anterior acrosome is involved in the acrosome reaction or sperm-zona pellucida interaction, while the equatorial segment (posterior acrosome) is involved in sperm-egg fusion. The acrosome is formed during spermiogenesis, during which associated molecules are transported from the Golgi apparatus and organized. Many of the molecules thus arranged gradually become compartmentalized during sperm passage through the epididymis. Some of them are further modified during the fertilization process. The findings indicate that acrosomal molecules are not only restricted to a specific region (domain) of the acrosome but also undergo ongoing relocation in a stage-specific manner during sperm maturation in the testis and epididymis. Such maturation-associated modifications are considered essential for sperm molecules to reach the correct or final site before fertilization. This review focuses on the organization and modifications of the acrosomal molecules as well as their compartmentalization within the acrosome.     

A new method for the treatment of sperm samples for ultrastructural study based on the use of animal tissues as biological containers

The study of the ultrastructure of spematozoa by means of transmission electron microscopy often presents with problems of interpretation according to the method employed, depending on whether samples are either centrifuged previously to the fixation or immersed in viscous gels. The major problems of interpretation are: changes in the location of vesicles originated during the maturation process and modifications in the adsorption of seminal plasma proteins to the sperm membrane surface. The aim of our study is to communicate an original new method for the treatment of spermatozoa for ultrastructural study. Our method is based on the use of animal tissues as biological containers, inside which the spermatic suspensions are included. We developed this method using fresh sperm samples taken from mature Rasa aragonesa rams. As biological container, we used 2.5-cm long segments of the intestine of 1-week-old chickens (Gallus gallus) (diameter around 4 mm). To avoid any influence of digestive enzymes of the mucosa on the sperm surface, we put each intestine fragment inside out by means of microdissection forceps under bifocal optical microscope and cold light. One of the edges was tied with thin suture silk. The sperm suspension was injected in the optimal experimental condition and amount. Finally, the still open edge of the intestine segment was tied with silk in the same way as the other segment edge. By using this technique, we can perform a suitable morphological study at an ultrastructural level. In addition, the functional relationship of the ultrastructural components of the target cells is correctly preserved.     

New method for the treatment of sperm samples for ultrastructural study based on the use of animal tissues as biological containers

The study of the ultrastructure of spematozoa by means of transmission electron microscopy (TEM) often presents with problems of interpretation according to the method employed, depending on whether samples are either centrifuged previously to the fixation or immersed in viscous gels. The major problems of interpretation are changes in the location of vesicles originated during the maturation process and modifications in the adsorption of seminal plasma proteins to the sperm membrane surface. The aim of our study is to communicate an original new method for the treatment of spermatozoa for ultrastructural study. Our method is based on the use of animal tissues as biological containers, inside which the spermatic suspensions are included. We developed this method using fresh sperm samples taken from mature Rasa Aragonesa rams. As biological container, we used 2.5-cm long segments of the intestine of 1-week-old chickens (Gallus gallus) (diameter around 4 mm). In order to avoid any influence of digestive enzymes of the mucosa on the sperm surface, we put each intestine fragment inside out by means of microdissection forceps under a bifocal optical microscope and cold light. One of the edges was tied with thin suture silk. The sperm suspension was injected in the optimal experimental condition and amount. Finally, the still-open edge of the intestine segment was tied with silk in the same way as the other segment edge. By using this technique, we can perform a suitable morphological study at an ultrastructural level. In addition, the functional relationship of the ultrastructural components of the target cells is correctly preserved.     

Cytoskeletal elements in mammalian spermiogenesis and spermatozoa.

Identification of the cytoskeletal elements and their role in the formation as well as the maintenance of head membrane compartmentalization is a much debated issue in mammalian spermatozoa. Data which have emerged during the last ten years are summarized. Those which have converged in a common opinion, such as the distribution of actin in mammalian spermiogenesis, are distinguished from those which have to be confirmed, such as the role of actin related proteins and actin in mature spermatozoa.     

Freeze-substitution: a method for the rapid arrest and chemical fixation of spermatozoa

A procedure for the freeze-substitution fixation of spermatozoa has been developed. Physical fixation of the motile cells is effected very rapidly by immersing the sperm in Freon-22 at ?146°C. Chemical fixation, with glutaraldehyde, is then imposed on the immobilized sperm after substitution of the ice matrix at ?50°C. The substitution is achieved with the solvent ethylene glycol in the manner described by Pease (1967). (Subsidiary experiments confirm that substitution of ice does occur at ?50°C and that chemical fixation by glutaraldehyde occurs at temperatures at least as low as ?20°C.) The spermatozoa are then embedded in Epon and examined as thin sections. Other techniques—substitution in acetone containing osmium tetroxide, the inclusion of formaldehyde with ethylene glycol as a chemical fixative, and the inclusion of agar in the diluent used to suspend the spermatozoa—have been tried but were unsatisfactory. Freezing stops the movement very rapidly and, as little subsequent disturbance occurs, it should be possible to preserve transient changes in the fine structure of the flagellum which might be related to a mechanism for the generation of bends. The observations in this paper are confined to the behaviour of the proximal part of the midpiece of the rat spermatozoon. It is demonstrated that bending of this part of the flagellum is restricted, to a remarkable degree, to one plane, the plane in which the sperm nucleus is flattened. This plane is almost exactly perpendicular to the plane containing the two central tubules of the axoneme. It has been confirmed that the axonemal complex has a straight course through the midpiece during those beats of the flagellum which are not accompanied by rotation of the entire cell. Lastly, it appears that the nine dense fibres do not undergo transient displacements as the flagellum bends.     

Seasonal variations in the heterologous binding of viscacha spermatozoa. A scanning electron microscope study.

Seasonal changes in the reproductive activity of the adult male viscacha (Lagostomus maximus maximus) were investigated during the annual reproductive cycle. Assays of heterologous in vitro binding between compatible gametes were used to evaluate the ability of viscacha spermatozoa to achieve primary binding during its annual reproductive cycle. Sperm were collected by mincing cauda epididymis in HECM-3 medium and the sperm concentration and motility were evaluated. Cumulus-free and zona-free oocytes obtained from superovulated hamsters were inseminated in vitro with capacitated sperm suspensions, incubated at 37 degrees C, 5% CO2 for 3 h, and then processed for studies by scanning electronic microscopy. Statistical analysis was used to compare the quantitative differences. The number of spermatozoa significantly decreases during the regression period, while sperm motility was progressive speed in both periods. During the active period elevated sperm binding to cumulus-free and zona-free oocytes was observed, while the binding during the regression period decreased drastically. In both periods, oocyte microvilli covered sperm heads and tails. These results suggest that the ability of viscacha spermatozoa to participate in gamete recognition is profoundly affected. This would likely be related to different functional stages of the spermatozoa and their epididymal microenvironment during the annual reproductive cycle of viscacha.     

Spatial distribution of actin and tubulin in human sperm nuclear matrix-intermediate filament whole mounts-a new paradigm

Sperm is a highly differentiated cell streamlined for fertilization. The function is thus heavily dependent on the cytoskeletal organization. Conventional methods limit the appreciation and correlation of this intricate cytoskeletal filament network in the context of an entire sperm. Our recent successful localization of nonmuscle myosin IIA on sperm nuclear matrix-intermediate filament (NM-IF) preparations from fertile men by embedment-free electron microscopy (EF-EM), prompted us to investigate the antigenic distribution of two major cytoskeletal proteins-actin and tubulin. The NM-IF preparations were subjected to a cocktail of buffered paraformaldehyde (2%) with a low concentration of glutaraldehyde (0.05%). These proteins were localized by indirect immunogold technique using EF-EM on sperm NM-IF whole mounts. Ultrastructure analysis revealed well preserved centrioles, outer dense fibers, axonemal filaments, and submitochondrial reticulum in the sperm NM-IF. Immunoreactive actin was localized along the length of the sperm whereas beta-tubulin was present in the axoneme alone. The spatial distribution of actin and tubulin in normal human sperm NM-IF reported here together with that of myosin on whole mount offers a powerful technique to understand sperm cytoskeletal supramolecular structure.     

Expression of the male reproduction‐related gene in spermatic ducts of the blue swimming crab,Portunus pelagicus,and transfer of modified protein to the sperm acrosome

Expression of a sex‐specific gene in Macrobrachium rosenbergii (Mr‐Mrr), encoding a male reproduction‐related (Mrr) protein, has been identified in the spermatic ducts (SDs) and postulated to be involved in sperm maturation processes. M. rosenbergii is the only decapod that the expression and fate of the Mrr protein has been studied. To determine that this protein was conserved in decapods, we firstly used cloning techniques to identify the Mrr gene in two crabs, Portunus pelagicus (Pp‐Mrr) and Scylla serrata (Ss‐Mrr). We then investigated expression of Pp‐Mrr by in situ hybridization, and immunolocalization, as well as phosphorylation and glycosylation modifications, and the fate of the protein in the male reproductive tract. Pp‐Mrr was shown to have 632 nucleotides, and a deduced protein of 110 amino acids, with an unmodified molecular weight of 11.79 kDa and a mature protein with molecular weight of 9.16 kDa. In situ hybridization showed that Pp‐Mrr is expressed in the epithelium of the proximal, middle, distal SDs, and ejaculatory ducts. In Western blotting, proteins of 10.9 and 17.2 kDa from SDs were all positive using anti‐Mrr, antiphosphoserine/threonine, and antiphosphotyrosine. PAS staining showed they were also glycosylated. Immunolocalization studies showed Pp‐Mrr in the SD epithelium, lumen, and on the acrosomes of spermatozoa. Immunofluorescence staining indicated the acrosome of spermatozoa contained the Mrr protein, which is phosphorylated with serine/threonine and tyrosine, and also glycosylated. The Mrr is likely to be involved in acrosomal activation during fertilization of eggs. Microsc. Res. Tech., 2013. © 2012 Wiley Periodicals, Inc.     

Species-specific localization of actin in mammalian spermatozoa: fact or artifact?

Actin has been characterized and localized in sperm cells of many mammals. Nevertheless, the reported localizations obtained by different methods and/or antibodies varied from species to species and even for the same species. To clarify the question, sperm actin distribution was reinvestigated under uniform technical conditions. Immunogold post-embedding procedures were performed using a polyclonal and two monoclonal antibodies of known specificity to localize actin in spermatids and spermatozoa of rabbit, mouse, rat, monkey, and human. In these species, actin (F-actin) was detected with the three antibodies between the nucleus and the acrosome of round and elongating spermatids. Species-specific changes occurred in maturing spermatids. In the rabbit, actin labeling decreased and disappeared from the tip to the base of the subacrosomal layer. In testicular and epididymal spermatozoa actin was detected only with a monoclonal antibody (Amersham) successively in the neck, postacrosomal area, and subacrosomal bulges. In mouse late spermatids a transitory labeling of the neck was detected only with the polyclonal antiactin. In testicular and epididymal spermatozoa an actin labeling was observed in the principal piece of the tail. In rat, monkey, and human sperm cells actin remained undetected. These results suggest that there is a redistribution of actin in late spermatids and spermatozoa which is a species-specific process but not an artifact of methodological origin. Thus, a function for actin in sperm, if any, remains to be demonstrated.     

Development of a protocol for multiple staining with fluorochromes to assess the functional status of boar spermatozoa

The aim of this study was to design a simple and reliable method for the simultaneous evaluation of the nucleus, the acrosome, and the mitochondrial sheath of boar spermatozoa. Sperm samples coming from healthy and sexually mature Pietrain boars were incubated with two nuclear fluorochromes--bis-benzamide specific for viable cells, and propidium iodide specific for nonviable cells--the fluorochrome Mitotracker Green FM specific for functional mitochondria, and the lectin Trypsin inhibitor from Soybean (SBTI) conjugated with the fluorochrome Alexa Fluor 488 specific for proacrosin. The results obtained from assessing the functional status of the spermatozoa using fluorochromes were compared with the conventional sperm parameters of sperm vitality using the eosin exclusion test (EE test), and sperm motility and morphology using the computer-assisted semen analyzer SCA 2002Producció. Applying the multiple staining test, it was found that the frequency of viable spermatozoa with intact acrosome and intact mitochondria was not different from the frequency of viable spermatozoa obtained with the EE test, and also correlated positively with the frequency of motile spermatozoa and the frequency of mature spermatozoa. Therefore, this technique is useful to characterize the status of boar spermatozoa by assessing the nuclear, acrosomal, and mitochondrial integrity. Moreover, it provides reliable diagnostic information about the fertility potential of boars.     

Ubiquitin-dependent proteolysis in mammalian spermatogenesis,fertilization, and sperm quality control: killing three birds with one stone

Ubiquitin and ubiquitin-like proteins control the degradation of substrates as diverse as cyclins, viral envelope proteins, plasma membrane receptors, and mRNAs. The ubiquitinated substrates are targeted towards the lysosomal or proteasomal degradation sites. The number and position of ubiquitin molecules bound to substrates' lysine residues and the number and position of ubiquitin molecules in polyubiquitin chains determine the astonishing substrate specificity of ubiquitin-mediated proteolysis. Ubiquitin is likely to be expressed in mammalian gametes and embryos at any given developmental step, but the information on ubiquitin dependence of gametogenesis and fertilization is sketchy. Ubiquitin ligases E1, E2, E3, and UBC4 are active in the testis. Ubiquitin and proteasomal subunits can be detected in the human sperm centrosome that undergoes dramatic reduction during spermatid elongation. Spermatid histones are ubiquitinated as they are being transiently replaced by transitional proteins and permanently by protamines. Ubiquitin tagging of the sperm mitochondrial membranes may serve as a death sentence for paternal mitochondria at fertilization, thus promoting the maternal inheritance of mitochondrial DNA (mtDNA) in mammals. The defective spermatozoa become surface-ubiquitinated during sperm descent down the epididymis. Finally, new evidence suggests the involvement of ubiquitin-proteasome pathway in the zona penetration by the acrosome-reacted spermatozoon. Such differential patterns of ubiquitination in the testis and epididymis, and inside the egg, may be necessary for reproductive success in humans and animals. Deciphering and eventually manipulating the ubiquitin-dependent proteolysis in the reproductive system could allow us to redirect the mode of mtDNA inheritance after cloning and ooplasmic transplantation, provide germ line therapy in some cases of male infertility, develop new contraceptives, manage polyspermia during in vitro fertilization, and establish objective markers for infertility diagnostics, semen evaluation, and prediction of future fertility.     

Cyclic nucleotide phosphodiesterase inhibition increases tyrosine phosphorylation and hyper motility in normal and pathological human spermatozoa.

Our objective was to determine the effect of phosphodiesterase (PDE) inhibition on: 1) tyrosine phosphorylation of human spermatozoa at the tail level; and 2) sperm motion parameters and hyperactivated motility. The study was conducted with normozoospermic and asthenozoospermic samples incubated under in vitro capacitating conditions. The main outcome measures were computer-assisted sperm motion analysis and fluorescent immunodetection of phosphotyrosine-containing proteins. Pentoxifylline (PTX) was used as PDE inhibitor because of its wide use in the clinic. PTX-treatment significantly increased sperm velocity, hyperactivated motility and tyrosine-phosphorylation, both in normo and asthenozoospermic samples. Tyrosine-phosphorylation of tail proteins was highly conspicuous in both types of samples, showing no differential pattern after PTX-treatment. Normozoospermic samples treated with pentoxifylline showed an increase in the number of spermatozoa displaying hyperactivated movement and tyrosine-phosphorylation at the tail level. Preliminary data on asthenozoospermic samples exhibiting altered motion characteristics and defective phosphorylation of sperm-tail proteins showed that both defects can be concomitantly overcome by pentoxifylline treatment. Tyrosine-phosphorylation of sperm-tail proteins is underlying the enhancement of hyperactivated motility resulting from PDE inhibition by pentoxifylline.