Sperm Flagellum Volume Determines Freezability in Red Deer Spermatozoa

The factors affecting the inter-individual differences in sperm freezability is a major line of research in spermatology. Poor sperm freezability is mainly characterised by a low sperm velocity, which in turn is associated with low fertility rates in most animal species. Studies concerning the implications of sperm morphometry on freezability are quite limited, and most of them are based on sperm head size regardless of the structural parts of the flagellum, which provides sperm motility. Here, for the first time, we determined the volumes of the flagellum structures in fresh epididymal red deer spermatozoa using a stereological method under phase contrast microscopy. Sperm samples from thirty-three stags were frozen and classified as good freezers (GF) or bad freezers (BF) at two hours post-thawing using three sperm kinetic parameters which are strongly correlated with fertility in this species. Fourteen stags were clearly identified as GF, whereas nineteen were BF. No significant difference in sperm head size between the two groups was found. On the contrary, the GF exhibited a lower principal piece volume than the BF (6.13 µm³ vs 6.61 µm³, respectively, p = 0.006). The volume of the flagellum structures showed a strong negative relationship with post-thawing sperm velocity. For instance, the volume of the sperm principal piece was negatively correlated with sperm velocity at two hours post-thawing (r = −0.60; p<0.001). Our results clearly show that a higher volume of the sperm principal piece results in poor freezability, and highlights the key role of flagellum size in sperm cryopreservation success.     

Changes of elemental concentrations around and on the surface of fowl sperm membrane during maturation in the male reproductive tract and after in vitro storage

X-ray microprobe analysis was performed to investigate the changes of elemental concentrations around or on the membrane of the head, midpiece, and principal piece regions of individual fowl spermatozoa during maturation in the male reproductive tract and after storage in vitro at 4°C. The pattern of change of elemental concentrations during maturation and postejaculation was, in general, similar in the three different subcellular regions; i.e., concentrations of sodium, potassium, chlorine, and calcium decreased gradually during sperm passage through the male reproductive tract and after storage. Phosphorus concentration remained almost constant in the male tract and decreased gradually after storage. In contrast, magnesium, zinc, and copper concentrations showed an interesting pattern: concentrations increased significantly during maturation to a maximum at ejaculation and decreased again after storage. The ratios of sodium to potassium in the midpiece region showed patterns similar to those of magnesium, zinc, and copper concentrations.     

On the fine structure of spermatozoa of Tachypleus gigas (Xiphosura,Merostomata)

Summary

Among the Arthropoda the Xiphosura are the only group whose spermatozoa resemble the so-called ‘primitive type’, although even here there are some differences. The spermatozoa of Tachypleus consist of a sperm head, a middle piece, and a long flagellum. Though principally quite similar to the spermatozoa of Limulus polyphemus some characteristics are noticeably different: the axonemal pattern (9 × 2 + 0), the shape of the acrosomal vacuole, the different position of the acrosomal filament, and the distribution of mitochondria throughout the cytoplasm. In contrast to what is known from Limulus the nuclear envelope is apparently dissolved over wide areas. Consequences for the interpretation of the acrosomal reaction are discussed. Structural conditions are compared with those in other Chelicerata.     

Use of negative staining technique and electron microscopy for the study of structural anomalies of outer dense fibres of human flagellum

Motility disorders due to tail defects are often seen in clinical andrology. Sperm motility should be assessed with regard to the morphology of the flagellum. Since suitable longitudinal sections are rarely obtained by routine transmission electron microscopy (TEM) and in view of the importance of dense fibres in modulating sperm motility and providing tensile strength, a detailed, study of human sperm flagellum by negative staining andTEM was attempted. The study was undertaken in two groups of men (I) fertile and (II) asthenozoospermic. The study revealed that outer dense fibres extend to 50–60% of the principal piece. Normal dense fibres were seen in 83% sperms and 23% sperms in groupsI andII respectively. The characteristics seen were variation in diameter, breakage or degradation with lacking or extended endpiece. The negative staining method provides an easy and useful analytical tool for identifying the defects of dense fibres and quantifying them.     

SpermBlue®: A new universal stain for human and animal sperm which is also amenable to automated sperm morphology analysis

Abstract

Our study was aimed at exploring a simple procedure to stain differentially the acrosome, head, midpiece, and flagellum of human and animal sperm. A further prerequisite was that sperm morphology of the stained samples could be analyzed using automated sperm morphology analysis (ASMA). We developed a new staining process using SpermBlue® fixative and SpermBlue® stain, which are iso-osmotic in relation to semen. The entire fixation and staining processes requires only 25 min. Three main steps are required. First, a routine sperm smear is made by either using semen or sperm in a diluting medium. The smear is allowed to air dry at room temperature. Second, the smear is fixed for 10 min by either placing the slide with the dried smear in a staining tray containing SpermBlue® fixative or by adding 1 ml SpermBlue® fixative to the slide. Third, the fixed smear is stained for 15 min by either immersing the slide in a staining tray containing SpermBlue® stain or adding four drops of SpermBlue® stain to the fixed smear. The stained slide is dipped gently in distilled water followed by air drying and mounting in DPX® or an equivalent medium. The method is simple and suitable for field conditions. Sperm of human, three monkey species, horse, boar, bull, ram, mouse, rat, domestic chicken, fish, and invertebrate species were stained successfully using the SpermBlue® staining process. SpermBlue® stains human and animal sperm different hues or intensities of blue. It is possible to distinguish clearly the acrosome, sperm head, midpiece, principal piece of the tail, and even the short end piece. The Sperm Class Analyzer® ASMA system was used successfully to quantify sperm head and midpiece measurements automatically at either 600 × or 1000 × magnification for most of the species studied.     

Reproduction in the Giant Isopod,Bathynomus giganteus

Summary

Aspects of the reproductive biology of the giant isopod, Bathynomus giganteus (Edwards) resemble those of other isopods. In females, the gonopores are located on the sternal midline of the eighth thoracic somite and the eggs are brooded in a marsupium. The reproductive tract of the males also resembles those of other isopods. The paired vasa deferentia open into two penes located on the sternal midline of the eighth thoracic somite. The vasa deferentia are formed of columnar epithelial cells with basal nuclei. The lumen is filled with seminal products consisting of aggregrates of spermatozoa surrounded by extracellular tubules. The sperm head consists of an acrosome and subacrosomal rod from which a pendant nucleus extends. The tails are composed of an amorphous core consisting of a dark band, two medium bands, two light bands followed by a dark band again. The tails are attached to the heads by a knob which is an extension of the core     

Comparative immunogold analysis of tubulin isoforms in the mouse sperm flagellum: Unique distribution of glutamylated tubulin

The distribution of different tubulin isoforms in the mouse sperm flagellum was studied using four site-directed antibodies to tubulin: DM1A and DM1B general anti α and β-tubulin, 6-11B-1 anti-acetylated α-tubulin, and GT335 anti-glutamylated α and β-tubulin. Quantitative immunogold analyses were performed on five regions of the flagellum: the middle piece, three successive regions of the principal piece, and the terminal piece. A uniform labeling was observed with DM1A and DM1B along the entire flagellum both for peripheral doublets and the central pair. Similar results were obtained with 6-11B-1 directed to acetylated α-tubulin, an N-terminal-modified tubulin isoform. In contrast, the labeling for glutamylated α and β-tubulin, C-terminal modified isoforms, was not uniform. The highest intensity was found in the middle piece and the terminal piece. The labeling which decreased significantly both for peripheral doublets and central pair along the principal piece was considered as a loss of glutamylated tubulin accessibility. From the middle piece to the end of the principal piece, this labeling was predominant in doublets 1-5-6, corresponding to the plane of the flagellar wave. However, the labeling for doublets 2-3-4-7-8-9 was heterogeneous, showing an increasing asymmetry. These results suggest that in the mammalian sperm cell model, the glutamylated tubulin might be involved in a functional heterogeneity among peripheral doublets of the flagellum. © 1996 Wiley-Liss, Inc.     

Ultrastructure of spermiogenesis and spermatozoa in Prorhynchus sp. (Platyhelminthes,Lecithoepitheliata, Prorhynchidae)

Summary

Mature sperm of Prorhynchus sp. have an elongated nucleus, multiple mitochondria and dense bodies, and two free axonemes which are located in grooves of the main shaft for much of their length. The axonemes are subterminally inserted and have the typical 9+ ‘1’ arrangement unique to Platyhelminthes and synapomorphic for taxa of Trepaxonemata. The testis follicles examined had small numbers of developing spermatids and very few mature sperm were present. During spermiogenesis, spermatids remain joined in clusters by distinctive bridges. In each spermatid two centrioles (with an intercentriolar body between them) give rise to free axonemes which grow out in opposite directions from each other. Indistinct ciliary rootlets are present. The axonemes are carried distally from the main spermatid mass on an elongating process and turn back towards the main spermatid mass. Nucleus, mitochondria and dense bodies move into the shaft, and the spermatid elongates before detaching from others in the cluster. This is the first detailed study of sperm and spermiogenesis in Lecithoepitheliata. Mature sperm are distinctly different from those of prolecithophorans, to which they are reputedly related, the latter having aflagellate sperm without dense bodies.     

Sperm volumetric dynamics during in vitro capacitation process in bovine spermatozoa

Previous studies have demonstrated that sperm head morphometry can be used as a potential diagnostic tool for detecting biophysical changes associated with sperm viability in bovine spermatozoa. In this study, sperm head morphometry was used to investigate its value as a biophysical marker for detecting volumetric changes in bovine spermatozoa under in vitro capacitating and non-capacitating incubation conditions. To further test this hypotesis, aliquots of pooled, washed bovine sperm were incubated in either Tyrode’s complete medium with heparin (TCMH; a capacitating medium containing Ca²⁺, NaHCO₃ and heparin), Tyrode’s complete medium heparin-free (TCM; a medium containing just Ca²⁺ and NaHCO₃) or Tyrode’s basal medium (TBM; a non-capacitating medium free of Ca²⁺, NaHCO₃ and heparin, used as control). Aliquots of sperm were processed for morphometric analysis at different incubation-time intervals (0, 3 and 6 h at 38°C), and the chlortetracycline assay was used simultaneously to confirm the ability of the sperm to undergo capacitation (B pattern) and the acrosome reaction (AR pattern) status in each medium. After 3 h of incubation under TCMH conditions, a significant increase was observed in the percentage of B and AR patterns and a significant decrease was found in all sperm morphometric parameters (P<0.01). Interestingly, after 6 h of incubation in TCMH, the percentage of B and AR patterns increased drastically over time and marked differences were found in the dimensional and shape parameters, which were significantly smaller compared with TBM or TCM media (P<0.001). Significant correlations were observed between sperm size and AR pattern (r=−0.875, P<0.01). In conclusion, sperm head morphometry can be used as a potential biophysical marker for detecting volumetric changes during capacitation process in bovine spermatozoa.     

Kinematics of hamster sperm during penetration of the cumulus cell matrix

During capacitation, mammalian spermatozoa gain the ability to penetrate the cumulus cell matrix (CCM). The role of hyperactivated motility for this capacity is uncertain. In the present study, hamster sperm were observed during penetration and progression through the CCM, and flagellar beat patterns were quantitated by characterization of the underlying flagellar bends. Small numbers of sperm were added to cumulus masses slightly compressed on a slide (150 μm depth), and penetration was videorecorded using interference contrast optics. During penetration of the cumulus surface, sperm did not generate the large flagellar bends and asymmetric beats that are hallmarks of hyperactivation in low viscosity media. Instead, they entered slowly using high-frequency, low-amplitude sinusoidal flagellar motions. Within the CCM, sperm continued to move slowly, and they exhibited three distinct patterns of motility. The first was sinusoidal, produced by alternating, propagated bends: principal bends (PB) moved the head away from the beat midline, with the convex edge of the head leading, and reverse bends (RB) had the opposite curvature. The second pattern was asymmetric and sinusoidal: an extreme RB developed in the distal flagellum, was propagated distally, and was followed by a PB of less curvature. The third motility pattern was a hatchet-like stroke of the sperm head which resulted when an extreme, nonpropagated PB developed slowly in the proximal midpiece, and was released rapidly. In this mode there were no reverse bends, and sperm did not progress. There were subpopulations of capacitating sperm in free-swimming medium which had these same bend types and motility patterns, suggesting that qualitative flagellar movement may not change during CCM penetration. Sperm velocity in the CCM was not strongly correlated with flagellar beat kinematics, suggesting local heterogeneity in cumulus mechanical resistance and/or differences in interaction of the matrix with the surfaces of individual sperm. An effective viscosity of the cumulus near its border was estimated to be of the order of 1–4 P.     

Cloning,sequencing, and characterization of LDH-C4 from a fox testis cDNA library

A full-length cDNA encoding the sperm-specific enzyme lactate dehydrogenase-C₄ was isolated from a fox testis cDNA expression library and sequenced. The deduced translated protein sequence was shown to be 86% identical to that of human LDH-C₄. In the fox testis, mRNA encoding LDH-C₄ was first detected in pachytene spermatocytes. The LDH-C₄ protein monomer was identified in Western blots of sperm membrane extracts as having a molecular weight of approximately 35,000, consistent with the monomeric size of this subunit previously identified in sperm from other species. The LDH-C₄ protein is localized on the sperm plasma membrane overlying the principal piece of the tail. Based on the available sequence data, we were able to identify an epitope within the N-terminal region of the LDH-C₄ amino-acid sequence which when administered to female foxes is antigenic and produces antibodies capable of recognizing the native protein. © 1996 Wiley-Liss, Inc.     

Ultrastructural observations on membrane changes associated with cryopreserved spermatozoa of two polychaete species and subsequent mobility induced by quinacine

Summary

A wide range of cryoprotectants and cooling rates have been tested on the spermatozoa of two polychaete species Arenicola marina and Nereis virens. The techniques were more successful with N. virens; with this species active sperm were recovered after immersion in liquid nitrogen following a variety of cooling protocols. Structural damage to the sperm of both species, however, was observed following freezing, and this was more severe in the case of A. marina. Structural damage of the flagellum plasma membrane was most commonly observed. Biologically important changes in the sperm can be induced by the freezing procedures; for example acrosome eversion may be induced in N. virens sperm. Dissociation of the sperm of A. marina can be induced after freezing by the sperm activator quinacrine, but these sperm do not acquire forward motility probably due to flagellum damage.     

Glycoconjugates of the human sperm surface: Distribution and alterations that accompany capacitation in vitro

We have studied changes in the binding of fluoresceinated lectins to human sperm during in vitro capacitation. We first determined the surface labeling pattern of viable sperm obtained by the swim-up procedure. Sperm were labeled with 100 μg/ml FITC-conjugated lectin at 4°C for 30 min. We simultaneously used Hoechst stain 33258 as a supravital stain to help differentiate surface from intracellular lectin labeling. Of 14 lectins studied, six (phytohemagglutinin-E, concanavalin A, Ricinus communis agglutinin-I, and the lectins of wheat germ, Lens culinaris, and Pisum sativum) bound to the entire surface of sperm, sometimes with minor local heterogeneity. Three lectins (from peanut, Maclura pomifera, and soybean) usually bound in a punctate manner, with more label on the tail than on the head. Five lectins (Ulex europaeus, Dolichos biflorus, Helix pomatia, and Vicia villosa lectins, and lectin II of Griffonia simplicifolia) bound very poorly or not at all to the sperm surface. Sperm were also inspected for changes in surface lectin binding patterns after 0, 5, and 23 hr of incubation in a capacitating medium. Two lectins showed reproducible changes. The labeling by Maclura pomifera agglutinin decreased by 5 hr in eight of ten experiments, and among sperm labeled with concanavalin A, the incidence of sperm with a highly fluorescent anterior margin of the sperm head increased by about 3.5-fold between 0 and 5 hr. The labeling pattern of the other lectins did not change.     

Changes in the rat sperm head during epididymal transit

Morphological changes in sperm are one aspect of a maturation process during epididymal transit in marnrnals. The literature mentions only, for different strains of rats, a remodeling and decrease in size of the acrosome. In the present work, the sperm were obtained from caput, corpus, and cauda epididymis of the albino rat. Samples were processed for scanning electron microscopy, with routine techniques, and for light microscopy and video microscopy. It appeared, with these techniques, that the acrosomal curvature and the whole head surface area of the rat sperm decrease during the epididymal transit. To measure these changes, a geometrical method was designed, and surface measurements were made using a computer program. It was found that the caput sperm head has the greatest surface area and a sharper acrosome bend than the cauda sperm. In an attempt to explain the above-mentioned changes, the suggestion is offered that some compactation of the nucleus and acrosomal material could be related to the decrease of the surface area.     

Sperm ultrastructure in representatives of six bivalve families from Peter the Great Bay, Sea of Japan

The ultrastructure of sperm in seven species of bivalves, the representatives of six families, Arcidae (Anadara broughtonii, Arca boucardi), Anomiidae (Pododesmus macrochisma), Tellinidae (Macoma tokyoensis), Ostreidae (Crassostrea gigas), Myidae (Mya japonica) and Trapezidae (Trapezium liratum) is described. All the studied sperm were typical tail sperm, adapted to external insemination, which, however, had a specific structure. Differences were revealed in the form of head, acrosome structure and number of mitochondria. The studied species of the above families had their specific morphology, the Arcidae species had a bullet- or barrel-shaped head with four or five mitochondria in the middle part; the Anomiidae had conic head, the acrosome with periacrosome material and four mitochondria (a basic feature of sperm is the axial core entering periacrosome material and consisting of bundle of actin filaments); the Myidae had a curved conic head and four mitochondria; in the Tellinidae the head was bullet-shaped, the periacrosome material contained a fibril component and four mitochondria; the Trapezidae had sperm of a conic form with spherical acrosome. The spherical sperm of C. gigas were similar to sperm of Saccostrea commercialis and Crassostrea virginica, but with some distinctions in the acrosome substructure. The morphology of sperm testified to the correct attribution of the Crassostreidae family as a synonym to the Ostreidae family.     

The spermatozoon of the Old Endemic Australo‐Papuan and Philippine rodents – its morphological diversity and evolution

Breed, W.G. and Leigh, C.M. 2010. The spermatozoon of the Old Endemic Australo‐Papuan and Philippine rodents – its morphological diversity and evolution.—Acta Zoologica (Stockholm) 91 : 279–294 The spermatozoon of most murine rodents contains a head in which there is a characteristic apical hook, whereas most old endemic Australian murines, which are part of a broader group of species that also occur in New Guinea and the Philippines, have a far more complex sperm form with two additional ventral processes. Here we ask the question: what is the sperm morphology of the New Guinea and Philippines species and what are the trends in evolutionary changes of sperm form within this group? The results show that, within New Guinea, most species have a highly complex sperm morphology like the Australian rodents, but within the Pogonomys Division some species have a simpler sperm morphology with no ventral processes. Amongst the Philippines species, many have a sperm head with a single apical hook, but in three Apomys species the sperm head contains two additional small ventral processes, with two others having cockle‐shaped sperm heads. When these findings are plotted on a molecular phylogeny, the results suggest that independent and convergent evolution of highly complex sperm heads containing two ventral processes has evolved in several separate lineages. These accessory structures may support the sperm head apical hook during egg coat penetration.     

Interspecific variation of sperm morphology in the Australian rodent genus Zyzomys

The sperm head morphology and tail length of two species of Australian rock rats, Zyzomys argurus and Zyzomys pedunculatus, are presented. In Z. argurus the sperm head has an apical hook together with two ventral processes extending from the upper concave surface that are largely composed of cytoskeletal material, and the sperm tail is about 135 µm in length. By contrast, in Z. pedunculatus the sperm head is paddle‐shaped with the nucleus capped by an acrosome that has a large apical segment and is surrounded by a thin layer of cytoskeletal material, and the sperm tail is only around 85 µm in length. Since the structure of the spermatozoon of Z. argurus is similar to that of most of the old endemic Australian rodents it is presumed to be the ancestral condition within the Zyzomys genus with that of Z. pedunculatus being highly derived and showing convergence with the sperm structure in some other orders of mammals.     

On mammalian sperm dimensions

Data on linear sperm dimensions in mammals are presented. There is information on a total of 284 species, representing 6.2% of all species; 17.2% of all genera and 49.2% of all families have some representation, with quantitative information missing only from the orders Dermoptera, Pholidota, Sirenia and Tubulidentata. In general, sperm size is inverse to body mass (except for the Chiroptera), so that the smallest known spermatozoa are amongst those of artiodactyls and the largest are amongst those of marsupials. Most variations are due to differences in the lengths of midpiece and principal piece, with head lengths relatively uniform throughout the mammals.