Nuclear and mitochondrial DNA-dependent RNA polymerases in bovine spermatozoa

DNA-dependent RNA polymerases have been solubilized from separated head and tail fractions from normal bovine spermatozoa and from spermatozoa carrying the 'decapitated sperm defect'. When enzyme extracts from separated heads and tails were chromatographed on DEAE-Sephadex, the head fraction was resolved into 2 distinguishable peaks eluting at about 0.11 and 0.15 M-(NH4)2SO4 while the tail fraction yielded 4 distinct peaks eluting at about 0.11, 0.15, 0.255 and 0.35 M-(NH4)2SO4. Results indentical to those observed for sperm tails were obtained with extracts prepared from highly purified mitochondria from bovine or murine heart or liver. Optimization of reaction parameters and inhibitor studies with alpha-amanitin and rifampicin revealed strong similarities between eucaryotic nuclear RNA polymerases 1 and 2 and the 2 RNA polymerases associated with sperm heads. Similar experiments comparing the RNA polymerases from somatic mitochondria and sperm tails suggested the sperm tail enzymes were mitochondrial in origin.     

Distribution of intramembranous particles and filipin-sterol complexes in mouse sperm membranes: polyene antibiotic filipin treatment

The distribution of intramembranous particles (IMPs) and membrane filipin-sterol complexes (FSC) was examined ultrastructurally in mouse spermatozoa from the male reproductive tract and ejaculates. IMPs were qualitatively analyzed on freeze-fracture replicas of glutaraldehyde-fixed tissue, while membrane FSC were quantitatively analyzed on replicas of filipin-treated cells. The distribution pattern of IMPs of mouse spermatozoa was fundamentally similar to that of other mammalian spermatozoa. 1) In the head, the plasma membrane had a heterogeneous population density, e.g., few IMPs on the acrosomal region, particularly few on the marginal segment, and somewhat regularly arranged IMPs on the postacrosomal region. The acrosomal membrane had many IMPs in hexagonal arrays. The nuclear membrane had many IMPs on the P-face, few IMPs on the variegated E-face, and an intense population density on the P-face of the basal plate. 2) In the neck, the plasma membrane had many IMPs with square arrangements of small IMPs in some areas on the P-face; the redundant nuclear membrane had a few IMPs on both P- and E-faces. 3) In the tail, the plasma membrane had diagonal rows of IMPs in some areas amongst larger IMPs on the middle piece, while it had "zippers" composed of IMPs running parallel to the axis on the principal piece. The distribution of sperm membrane FSC may be summarized as follows: 1) In the head, the acrosomal plasma membrane, which was heavily labeled with filipin, had much more FSC in the equatorial segment than in the marginal segment throughout the study. The postacrosomal plasma membrane generally had no FSC, but some sperm in ejaculates were slightly positive to filipin. The acrosomal membranes (both outer and inner) had no FSC. The nuclear membrane in the main part of the head had less FSC in vas deferens and ejaculated sperm than in the epididymal sperm. The nuclear membrane on the basal plate had no FSC. 2) In the neck, the plasma membrane had little FSC. The redundant nuclear envelope had scattered FSC with a higher incidence in the epididymal sperm than in those from the vas deferens and ejaculates. The membrane scroll, which was elongated from the extreme caudal end of the redundant nuclear envelope, had abundant FSC in the vas deferens and ejaculated sperm. 3) The tail plasma membrane (both middle and principal piece), which was weakly labeled with filipin, had less FSC in sperm from the vas deferens and ejaculates than in those from the epididymis. The limiting membrane covering the mitochondria had no FSC.     

New data on aberrant spermatozoa in the ejaculate of Sus domesticus

This paper describes 16 new types of aberrant spermatozoa observed by scanning electron microscopy in the ejaculate of two healthy, sexually mature Landrace boars. The new anomalies observed were 1) spermatozoa with folded tail and abnormal head; 2) tailless spermatozoa with an abnormal connecting piece; 3) immature spermatozoa with two tails of the same length, fused and coiled; 4) spermatozoa with two tails of the same length, fused and coiled, and a small, rounded head; 5) spermatozoa with two fused tails and a wide head; 6) spermatozoa with three tails of the same length, fused and coiled; 7) immature spermatozoa with two heads and two fused tails; 8) spermatozoa with two heads, one at each tip of the tail; 9) spermatozoa with a short, folded tail and a triangular head; 10) spermatozoa with a short tail lacking the intermediate piece; 11) spermatozoa with a short tail, without the main piece and with a long intermediate piece; 12) spermatozoa with a short tail, without the main piece and with a rough head; 13) spermatozoa with small, rounded head; 14) spermatozoa with small, aberrant heads; 15) spermatozoa with small, bacillary heads; and 16) immature spermatozoa with tapering heads.     

Factors maintaining normal sperm tail structure during epididymal maturation studied in Gopc-/- mice

Gopc (Golgi-associated PDZ- and coiled-coil motif-containing protein)(-/-) mice are infertile, showing globozoospermia, coiled tails, and a stratified mitochondrial sheath. Transmission electron microscope (TEM) images of the spermatozoa were studied quantitatively to analyze disorganization processes during epididymal passage. Factors maintaining straight tail and normal mitochondrial sheath were also studied by TEM and immunofluorescent microscopy. Sperm tails retained a normal appearance in the proximal caput epididymidis. Tail disorganization started between the proximal and the middle caput epididymidis, and the latter is the major site for it. The tail moved up through the defective posterior ring and coiled around the nucleus to various degrees. Tail coiling occurred in the caput epididymidis suggesting it was triggered by cytoplasmic droplet migration. SPATA19/spergen-1, a candidate mitochondrial adhesion protein, remained on the stratified mitochondria, while GPX4/PHGPx, a major element of the mitochondrial capsule, was unevenly distributed on them. From these findings, we speculate GPX4 is necessary to maintain normal sheath structure, and SPATA19 prevents dispersal of mitochondria, resulting in a stratified mitochondrial sheath formation in Gopc(-/-) spermatozoa. The epididymal epithelium was normal in structure and LRP8/apoER2 expression suggesting that tail abnormality is due to intrinsic sperm factors. Three cell structures are discussed as requisite factors for maintaining a straight tail during epididymal maturation: 1) a complete posterior ring to prevent invasion of the tail into the head compartment, 2) stable attachment of the connecting piece to the implantation fossa, and 3) a normal mitochondrial sheath supported by SPATA19 and supplied with sufficient and normally distributed GPX4.     

Sperm malformations throughout the boar epididymal duct

Taking into account the importance of the sperm epididymal maturation process, and the consequential changes in the spermatozoa, we studied eight different sperm malformations in the caput, corpus, and cauda regions of the epididymis of healthy and sexually mature Landrace boars in order to determine the origin of these sperm abnormalities. Epididymal sperm characteristics were examined using light microscopy, scanning and transmission electron microscopy. The incidence of each type of malformation investigated was established after counts of 10 000 spermatozoa in each of the three epididymal regions. The different sperm malformations studied were: (1) spermatozoa with tail folded at the connecting piece; (2) spermatozoa with tail folded at the midpiece; (3) spermatozoa with tail folded at the Jensen's ring; (4) spermatozoa with tail folded at the principal piece; (5) coiled tail spermatozoa; (6) spermatozoa with two fused tails; (7) macrocephaly; and (8) microcephaly. The count performed in each epididymal region indicated that, whereas significant differences (P ≤ 0.01) existed between the frequencies of some types of sperm malformations and the epididymal region from where the sperm originate, other sperm malformations were more uniformly distributed along the epididymal duct. Among the eight different sperm malformations studied, three were found to be of secondary origin: spermatozoa with tail folded at the Jensen's ring (originated in the epididymal cauda); spermatozoa with coiled tail; and spermatozoa with two fused tails (originated in the epididymal corpus). Knowing the origin of spermatozoa abnormalities will assist research into the study of infertility and reproductive pathology.     

Immunocytochemical localization of phospholipase A2 in hamster spermatozoa.

Antibodies raised against porcine pancreatic phospholipase A2 (PLA2) react in immunoblottings with both the antigen as well as with one protein band of about 14 kDa from hamster spermatozoa extracts. Immunoblottings of proteins extracted from spermatozoon head and tail fractions also show similar results. Anti-PLA2 purified IgGs were employed for light and electron microscopic immunocytochemistry in order to detect PLA2 in hamster cauda epididymal spermatozoa. When whole mount spread spermatozoa were used under light (employing the PAP complex) or electron microscopy (using anti-rabbit gold conjugated), the acrosomal area of the gametes shows a noticeable labelling; a characteristic which is not observed in samples treated with the pre-immune serum. Immunocytochemistry undertaken in ultrathin sections from spermatozoon samples embedded in Lowicryl, demonstrates that the antigen appears preferentially distributed in the acrosome. Besides, sperm tails showed a scattered distribution of gold granules in the mitochondria of the midpiece. Results suggest that the antibody used recognizes a PLA2 which is preferentially located in the acrosome and mitochondria. On the other hand, the presence of a surface PLA2 in the plasma membrane covering the acrosome is suggested. This surface PLA2 would be probably related to the acrosome reaction phenomenon that occurs in the spermatozoon before penetrating the oocyte.     

Immunocytochemical localization of phospholipase A2 in hamster spermatozoa

Summary Antibodies raised against porcine pancreatic phospholipase A2 (PLA2) react in immunoblottings with both the antigen as well as with one protein band of about 14 kDa from hamster spermatozoa extracts. Immunoblottings of proteins extracted from spermatozoon head and tail fractions also show similar results. Anti-PLA2 purified IgGs were employed for light and electron microscopic immunocytochemistry in order to detect PLA2 in hamster cauda epididymal spermatozoa. When whole mount spread spermatozoa were used under light (employing the PAP complex) or electron microscopy (using anti-rabbit gold conjugated), the acrosomal area of the gametes shows a noticeable labelling; a characteristic which is not observed in samples treated with the pre-immune serum. Immunocytochemistry undertaken in ultrathin sections from spermatozoon samples embedded in Lowicryl, demonstrates that the antigen appears preferentially distributed in the acrosome. Besides, sperm tails showed a scattered distribution of gold granules in the mitochondria of the midpiece. Results suggest that the antibody used recognizes a PLA2 which is preferentially located in the acrosome and mitochondria. On the other hand, the presence of a surface PLA2 in the plasma membrane covering the acrosome is suggested. This surface PLA2 would be probably related to the acrosome reaction phenomenon that occurs in the spermatozoon before penetrating the oocyte.     

A new technique for the precise location of lactate and malate dehydrogenases in goat, boar and water buffalo spermatozoa using gel incubation film.

Gel incubation film, which contained gelatin to prevent the diffusion of enzyme during chemical reaction and phenazine methosulfate to operate as a hydrogen acceptor between NADH and tetrazolium, was used and light microscopy revealed that lactate dehydrogenase was located in the head and tail of the spermatozoa as well as in the midpiece, whereas malate dehydrogenase was confined to the midpiece in spermatozoa of the animals examined. In goat spermatozoa, lactate dehydrogenase was associated mainly with the inner acrosomal membrane in the head, the mitochondrial matrix in the midpiece and with flagellar fibrils in the tail, whereas malate dehydrogenase was present only in the mitochondrial matrix.     

Sources of variation in the morphological characteristics of sperm subpopulations assessed objectively by a novel automated sperm morphology analysis system

There is evidence that the mammalian ejaculate contains distinct subpopulations of spermatozoa and that the variability among these subpopulations may have adaptive and functional significance. This study investigated the precision, reproducibility and operating characteristics of a novel automated sperm morphology analysis system, the Hobson Morphology package, establishing protocols to investigate boar sperm characteristics. Five ejaculates were collected from each of three boars from different genetic lines: Landrace-Meishan introgression, Sireline Large White and Damline Large White. Five semen smears per ejaculate were stained with haematoxylin and eosin. Two hundred spermatozoa per slide were analysed. No significant differences among slides within an ejaculate were detected for sperm tail length (P = 0.770), head width (P = 0.736) and head length (P = 0.615), indicating that both staining and morphology analysis were precise and reproducible. Among the boars, variability in tail length was detected (P = 0.001), but head width (P = 0.114) and length (P = 0.069) did not differ significantly. Multivariate pattern analysis (PATN computer package) highlighted three sub-populations of spermatozoa objectively on the basis of tail length (10.0-22.0 microns, 22.1-73.0 microns and 73.1-130.0 microns). The Landrace-Meishan introgression boar possessed more spermatozoa (P < 0.0001) with tails 73.1-130 microns long. Subsequent analysis of morphology parameters in a pure-bred Meishan boar showed similar measurements for tail length (mean +/- SD; 66.36 +/- 24.70 microns) to the Landrace-Meishan introgression boar (mean +/- SD; 67.09 +/- 21.80 microns). Sperm subpopulations originate during spermatogenesis, when heterogeneous genotypic effects determine the structural features of spermatozoa. The findings of this study confirm that tail length differs between boars and that subpopulations of spermatozoa can be detected within a single ejaculate.     

CHEMICAL DISSECTION OF MAMMALIAN SPERMATOZOA

Spermatozoa from several mammalian species have been dissected by chemical methods to yield free heads, tails with attached midpieces, and tails from which the mitochondrial components of the midpiece were removed. Mouse and rat spermatozoa were cleaved by brief treatment with trypsin to yield free heads and tails, while human, guinea pig, and rabbit spermatozoa were cleaved by trypsin only after incubation with 2-mercaptoethanol or dithiothreitol. Spermatozoa were also cleaved at the junction of the head and the tail by treatment with acid and base. Mitochondria were removed from intact spermatozoa or isolated tails by mechanical shear after treatment with 2-mercaptoethanol or dithiothreitol. The dissected components of spermatozoa were fractionated with good yield and high purity by density gradient centrifugation. Ultrastructural analysis indicates that proteolytic cleavage to yield separated heads and tails occurs at a specific location in the neck of the spermatozoon, leaving the basal plate attached to the head of the cell. In contrast, after acid cleavage the basal plate remains with the midpiece. Proteolytic treatment has no apparent effect on any other spermatozoan structures, whereas acid or base treatment results in damage to the plasma membrane, the acrosome, and other structures. The specificity of the proteolytic cleavage suggests that a particular protein or group of proteins may be responsible for the linkage between the sperm head and tail.     

Bovine spermatozoal head size variation and evaluation of a separation technique based on this size

The objectives of this study were to determine the variation of head areas of normal spermatozoa attributable to breed, individual bull and ejaculate and to verify separation of X and Y chromosome-bearing spermatozoa and separation effectiveness. Spermatozoa were evaluated using video enhanced contrast microscopy combined with video intensified fluorescent microscopy and the polymerase chain reaction (PCR). In Experiment 1, spermatozoal head areas were measured from 2 ejaculates collected from bulls of 3 beef and 2 dairy breeds. No differences in head areas were found between breeds or between bulls within breeds; variation was observed among ejaculates from individual bulls across breeds. In Experiment 2, spermatozoa from 5 ejaculates were separated on individual SEPDEVICEs (Patented). Head area, fluorescent intensity and PCR of spermatozoa retained in the SEPDEVICEs suggested a separation based on size in 1 of 5 samples. Ejaculate variation in head areas affected separation efficiency.     

Spermiogenic,epididymal, and spermatozoal damage induced by a peritesticular injection of ethylene dibromide to rams

The effects of a peritesticular injection of ethylene dibromide (EDB) on the germ cells, epididymis, and spermatozoa of rams was examined by removing each injected testis and epididymis at different times after treatment and by monitoring the seminal characteristics of ejaculates.A high incidence of abnormal elongating and elongated spermatids was observed in the testes of treated rams 48 h after injection. At this time the epithelium of the corpus and cauda epididymidis was damaged in the majority of observed rams, and the spermatozoa in these segments were abnormal, mainly with acrosomal defects, denuded forms and denuded tailless forms. Apparent phagocytosis of spermatozoa was also observed in these portions of the epididymal duct. Ejaculates collected as early as 48 h after injection had a very low sperm density and large percentages of spermatozoa with acrosomal and tail abnormalities. A dose-reponse effect was obtained, and the reversibility of the effect of a low dose of EDB on sperm morphology was demonstrated in the rams by semen examination.     

蓝尾石龙子精子的超微结构

蓝尾石龙子(Eumeces elegans)附睾以2．5％戊二醛和1％锇酸双重固定,按常规制作超薄切片,用H-600透射电镜研究观察精子的超微结构。精子由头部和尾组成,头部由顶体复合体和核组成,尾由颈段、中段、主段和末段组成。头部的顶体囊前部扁平,分为皮质和髓质,顶体下锥由类结晶状的顶体下物质组成,穿孔器顶端尖,、穿孔器基板塞子状,细胞核延长,核内小管缺,核伸展部前端具一电子透明区,核肩圆,核陷窝锥形。颈段具片层结构,近端中心粒和远端中心粒的长轴呈直角,9束外周致密纤维与远端中心粒相应的9束三联微管相联,向后与轴丝相应的9束双联微管相联,中央纤维与2个中央单微管相联。中段短,含有线状嵴的柱状线粒体,由连续的规则小卵状或小梯形致密体组成线粒体间的环状结构,纤维鞘伸入中段,终环紧贴于细胞膜的内表面。线粒体与环状结构的模式为：rs1／mi1,rs2／mi2,rs3／mi3,rs4／mi4,横切面上每圈线粒体数目为10个。主段前面部分具薄的细胞质颗粒区。纤维3和8至主段前端消失。轴丝复合体呈“9 2”型。蓝尾石龙子精子超微结构与已描述的石龙子科种类比较发现,与蜓蜥群和胎生群的石龙子相似;但没有发现石龙子科精子的独征。     

Gametes and fertilization in the Chinese hamster

Freshly ovulated eggs are each surrounded by a compact cumulus oophorus. The overall diameter of the normal egg (including the zona pellucida) is about 100 μm. Cumulus cells, particularly those near the egg, are arranged redially in a viscous noncellular matrix. The spermatozoon is about 250 μm in length. The head a large acrosome, changes in which can be readily examined with the light (phase- contrast) microsope. When exposed to physiological salt solutions, testicular spermatozoa either were motionless or flexed the posterior half of their tails slowly. Spermatozoa from the caput epididymis were highly motile, flexing the entire tail. A few of them moved progressively. Mature spermatozoa from the vas deferens were highly motile and moved either straightforward or in a circle. They vibrated their tails stiffly without flexing them. In normally mated females, fertilization began sometime between 2 and 3 h after ovulation and was completed within the next 4 to 5 h. Spermatozoa swimming in the ampullary fluid or within the cumulus oophorus about the time of fertilization flexed the anterior half (which roughly corresponds to the midpieac region) of their tails. This peculiar movement may be homologous to the so-called “hyperactivation” of spermatozoa as reported in several other mammalian species. Actively motile spermatozoa within the cumulus or no the zona pellucida had either modified (“collapsed”) or no acrosomal caps. The sperm head usually passed verticually or nearly through the zona, but the path was oblique in some instances. In 54% of the recently fertilized eggs examined, the entire length of the sperm tail was within the perivitelline space; in the other 46% of the eggs varying lenghts of the tail remined the perivitelline space, the tails were extruded from the vitellus of many eggs even before the eggs began their first cleavage. When unfertilized eggs in the cumulus oophorus were inseminated with vas deferens spermatozoa in a modified Tyrode's solution (m-TALP), about 80% of them were ferrtilized by 4–6 h after insemination. The vast majority were monospermic. When eggs were freed from the cumulus prior to insemination, none were fertilized, suggesting that the cumulus cells or their matrix assisted capacitation and/or the acrosome reaction of the spermatozoa under the in vitro conditions employed. No eggs were fertilized by the testicular or caput epididymal spermatozoa regardless of the presence or absence of cumulus oophorus around the eggs at the time of insemination.     

Morphology and motility of spermatozoa from different regions of the epididymal duct in the domestic cat

Spermatozoa undergo important maturational changes as they pass through the epididymal duct. Some domestic cats and many species of wild felids have high proportions of abnormal spermatozoa in their ejaculates. The epididymis has been shown to be able to remove certain abnormal sperm forms in some species while other sperm abnormalities originate in the epididymis. So far, it has not been shown how the epididymis affects sperm morphology in the domestic cat. Therefore, motility and sperm morphology were studied in spermatozoa from the efferent ducts and from the 6 regions of the epididymal duct. There were significant decreases in the proportions of spermatozoa with abnormalities of the sperm head, acrosomal defects, acrosomal abnormalities and in the proportion of midpiece abnormalities. In contrast, there was a small but significant increase in the proportion of spermatozoa with abnormalities of the tail. Spermatozoa acquired the capacity for motility in Region 4, where the cytoplasmic droplet also moved from a proximal to a distal position, indicating that important maturational changes take place in this region. The results of this study demonstrate that the proportions of sperm abnormalities originating in the testes decrease during epididymal transport, while some sperm tail abnormalities may actually originate in the epididymis.     

Assessment of equine sperm mitochondrial function using JC-1

The fluorescent carbocyanine dye, JC-1, labels mitochondria with high membrane potential orange and mitochondria with low membrane potential green. Evaluation of mitochondrial membrane potential with JC-1 has been used in a variety of cell types, including bull spermatozoa; however, JC-1 staining has not yet been reported for equine spermatozoa. The aim of this study was to apply JC-1 staining and assessment by flow cytometry or a fluorescence microplate reader for evaluation of mitochondrial function of equine spermatozoa. Six ejaculates from four stallions were collected and centrifuged through a Percoll gradient (PERC). Spermatozoa were resuspended to 25 x 10(6) cells/mL, samples were split, and one sample was repeatedly flash frozen (FF) in LN2 and thawed. The following gradients of PERC:FF were prepared: 100:0 (100), 75:25(75), 50:50 (50), 25:75 (25) and 0:100 (0). Samples were stained with 2.0 microM JC-1 and assessed for staining by flow cytometry and by a fluorescence microplate reader. A total of 10,000 gated events was analyzed per sample with flow cytometry. The mean percentage of cells staining orange for the 100, 75, 50, 25 and 0 treatments was 92.5, 72.8, 53.4, 27.3 and 7.3, respectively. The expected percentage of spermatozoa forming JC-1 aggregates was correlated with the actual percentage of orange labeled sperm cells determined by flow cytometry (r2=0.98). Conversely, JC-1 monomer formation was negatively correlated with expected mitochondrial membrane potential (r2=-0.98). The blank corrected orange fluorescence, assessed by microplate assay, was significantly (P<0.0001) correlated with the expected (r2=0.49) and with the flow cytometric (r2=0.50) determination of percentage of spermatozoa with mitochondria of high membrane potential. Total orange and orange:green fluorescence was also correlated with mitochondrial function. These results indicate that JC-1 staining can accurately detect changes in mitochondrial membrane potential of equine spermatozoa. The relative fluorescence of JC-1 labeling patterns of equine spermatozoa can be accurately and objectively determined by flow cytometry and by a fluorescence microplate reader assay.     

The assessment of human sperm morphology in surface replica preparations for transmission electron microscopy

Human spermatozoa were treated with the detergents Hyamine 2389, Triton X-100, or sodium dodecyl sulphate (SDS) and surface replica preparations and Papanicolaou-stained smears made. From the ultrastructural studies it was found that Hyamine caused a dissolution of the plasmalemma to reveal the outer acrosomal membrane that was often absent over the anterior cap region; whereas Triton, in addition, caused severe damage to the entire acrosome. Treatment with SDS rapidly cleaved the tails from the majority of the spermatozoa, stripped the plasmalemma from both the head and tail regions of the cells, and also removed the whole of the outer acrosomal membrane plus most of the acrosomal contents. However, when viewed in the Papanicolaou-stained preparations, the spermatozoa were all of apparently normal morphology. These studies make it clear that some caution must be used when interpreting human sperm morphology assessments made under the light microscope. While it is not suggested that the more involved technique of surface replication should be used in routine semen analyses, it does represent a valuable technique for use with research material.     

Structural peculiarities associated with multiflagellate sperm in the emu, Dromaius novaehollandiae

Multiflagellate sperm represent a rare defect in mammals and also in the emu where an incidence of only 1% multiflagellate sperm was recorded in semen samples from 15 birds. Biflagellate sperm were the most frequent form of the defect observed, but 3- to 5-tailed sperm were also noted. An association was apparent between multiple tails and macrocephalic sperm, which accounted for 0.6% of multiflagellate sperm. Structural features of the defect were generally similar to those seen in mammals. The duplicated tails shared a single midpiece, which housed supernumerary centriolar complexes, each surrounded by a mitochondrial sheath. A single row of mitochondria separated adjacent centriolar complexes. Elements of the connecting piece (segmented columns, capitellum) appeared normal. The nuclear base appeared flat, staggered, or scalloped depending on the number and depth of additional implantation fossae. Multiflagellate emu sperm of normal head dimensions displayed a widened nuclear base (in the form of an attenuated peripheral nuclear extension) to accommodate the attachment of the additional centriolar complexes. Defective mammalian sperm do not show this modification of the nuclear base as the inherently wider sperm head is able to accommodate the supernumerary centrioles. Although often spiraled around each other, the duplicated principal pieces of the tail were generally separated and free. However, in some cells the proximal parts were collectively bound within the plasmalemma. Multiflagellate sperm appear to have a dual origin with some defective cells originating from incomplete cytokinesis and others as a result of abnormal centriolar duplication.     

Interrelationships among fluorometric analyses of spermatozoal function, classical semen quality parameters and the fertility of frozen-thawed bovine spermatozoa

Cryopreserved spermatozoa from 8 bulls were used to examine the interrelationships among flow cytometric spermatozoal quality assessments and classical semen quality parameters and nonreturn rate estimates of fertility. The integrity of the sperm cell membrane and the functional capacity of the mitochondria were quantified by flow cytometry after concurrent staining with carboxydimethylfluorescein diacetate (CDMFDA), propidium iodide (PI), and rhodamine 123 (R123). For each sample a total of 10,000 stained spermatozoa were simultaneously quantified for the intensity of their green and red fluorescence. Three straws from each bull were each examined initially and following incubation at 37 degrees C for 3 hours to assess the rate of senescence. The proportion of spermatozoa retaining membrane integrity and having functional mitochondria, as determined by CDMFDA and R123 staining, were compared with classical semen quality assessments (sperm motility, acrosomal status, cellular and head morphology, presence of vacuoles/craters and cytoplasmic droplets) and with fertility (nonreturn to estrus rates). For individual ejaculates nonreturn rates, the range was from 61.8 to 78.8%, whereas the cumulative rates of several ejaculates for each bull ranged from 71.3 to 83.5%. The proportion of spermatozoa with functional membranes and mitochondria were positively correlated with the percentage of spermatozoa with normal morphology (r=0.82; P=0.01) and motility after 4 hours of incubation (r=0.78; P=0.02), but not with the estimates of fertility. The actual number of spermatozoa per straw staining with CDMFDA and R123 after 4 hours of incubation at 37 degrees C was correlated with the percentage of spermatozoa with normal morphology (r=0.73; P=0.04). Multiple regression equations indicated that combinations of semen quality measurements could be useful in estimating fertilizing potential.     

Ultrastructural localization of labeled acrosomal glycoproteins during in vivo fertilization in the rabbit

Rabbit spermatozoa were labeled predominantely in their acrosomal glycoproteins by 1-³H-glucosamine during spermiogenesis. Ova fertilized in vivo by spermatozoa labeled 22 days earlier were analyzed by fine-structure autoradiography for the localization of the label. The latter was found associated with 1) the fused membranes of the acrosomal cap remaining on the zona pellucida surface, 2) the material released on the zona surface after the acrosome reaction and possibly detectable after tannic acid fixation, 3) the equatorial segment of the sperm head and the preequatorial swellings, and 4) other sperm components, eg, the sperm tail. No labeling, on the other hand, was detected on the denuded leading edge of spermatozoa found either in the penetration slit or in the perivitelline space. Our observations suggest the involvement of acrosomal glycoproteins in different mechanisms of sperm/zona pellucida interaction but are not in favor of a major role of (enzymatic) glycoproteins bound to the inner acrosomal membrane during the penetration of the zona pellucida.