Incidence and ultrastructure of “crater” defect of bovine spermatozoa

Analysis of inter-examination differences in sperm nuclear vacuoles among male patients with infertility

We analyzed the inter-examination differences in sperm nuclear vacuoles among male patients with infertility. We enrolled 56 male patients with infertility who underwent multiple semen analyses and high-magnification observation of the sperm head. A total of 162 ejaculates were evaluated. The average patient age was 34.5 years. Following the conventional semen analysis, the nuclear vacuoles in motile spermatozoa were evaluated at 3700-6150 × magnification on an inverted microscope equipped with differential interference contrast optics. A large sperm nuclear vacuole (LNV) was defined as one or more vacuoles with a maximum diameter exhibiting > 50% width of the sperm head. We compared the differences in the proportion of spermatozoa with LNVs between two consecutive semen samples before treatment. Treatment-related differences in the number of LNVs were also analyzed. Student's t-test was used to perform the statistical analyses. No differences were observed in any semen parameters between the first and second ejaculates. On high-magnification microscopy, the proportion of spermatozoa with LNVs was 23.5% and 29.4% (p = 0.0220) in the first and second ejaculates, respectively in 33 patients. Among the 18 patients who underwent varicocele repair using a microsurgical subinguinal approach, the proportion of spermatozoa with LNVs at baseline, three, and six months after surgery was 27.7%, 12.0% (p = 0.0132 versus baseline), and 10.3% (p = 0.0226 versus baseline), respectively. After three months of medical treatment for male infertility in 28 patients, the proportion of spermatozoa with LNVs slightly decreased from 33.3% to 28.6% (p = 0.1276); however, it was not statistically significant. In conclusion, when multiple ejaculates were obtained, in the subset of male patients with infertility, the proportion of spermatozoa with LNVs could be different. The number of LNVs decreased following varicocele repair.

Ultrastructural abnormalities of boar spermatozoa

Described here are the main ultrastructural malformations observed in spermatozoa of ejaculates collected from healthy, adult Landrace boars following 2 days of sexual abstinence. Previously semen had been collected 3 times per week. Sperm concentration in the cell-rich fraction of ejaculates was approximately 700,000 sperm/mm(3). The aberrant gamete forms did not exceed 2% of the total number of spermatozoa. Ultrastructural anomalies of spermatozoa were classified into 2 groups: head malformations and tail malformations. These consisted of: 1) spermatozoa with expanded and vacuolated acrosomes, 2) spermatozoa with myelin figures within the perinuclear space, 3) macrocephalic spermatozoa with 2 nuclei and a deformed acrosomal vesicle, 4) spermatozoa with an expanded acrosomal apex, 5) spermatozoa with nuclear vacuoles, 6) macrocephalic spermatozoa with a roundish head, 7) spermatozoa with swollen mitochondria, 8) spermatozoa with additional mitochondria over the mitochondrial sheath, 9) spermatozoa without the central microtubular pair, 10) spermatozoa without some peripheral doublets, 11) spermatozoa with 1 or 2 coiled tails, 12) spermatozoa with a folded tail and a disorganized connecting piece, 13) spermatozoa with a vesiculated tail, and 14) spermatozoa with 2 tails fused by their respective mitochondrial sheaths.

The search for viruses in bovine semen, a review

Viruses reported in bovine semen include those of foot and mouth disease, bluetongue, bovine leukemia, infectious bovine rhinotracheitis, bovine viral diarrhea, ephemeral fever, and lumpyskin disease. Bovine enteroviruses, a parapoxvirus (paravaccinia), and several uncharacterized viruses have also been isolated. Their presence in semen has been recognized by a variety of animal inoculation and cell culture techniques. The prevalence of viruses in semen and the attendant impact on fertility is largely unknown. The widespread distribution of frozen semen, an ideal system for preserving viral infectivity, indicates this product could serve as an important vehicle for transmission of viruses to uninfected herds or areas. This concern has placed restrictions on international movement of semen. Improved methods for detecting viruses in semen are necessary to assess the importance of the problem and to develop realistic precautionary measures.

Relationship of seminal traits and insemination time to fertilization rate and embryo quality

The nature of subfertility due to the male or inseminate is as complex as that of the female. Fertilization failure or failure in embryogenesis are both documented to be of seminal origin. Males also differ in the numbers of sperm required to reach their maximum fertilization rate. Males requiring more sperm would be considered to have compensable seminal deficiencies. These include a number of known (viability and morphology) and unknown factors (functional or molecular traits) precluding sperm access to the ovum or ability to engage the ovum sufficiently to initiate fertilization and the block to polyspermy. Differences in fertility among males or inseminates independent of sperm dosage are considered uncompensable. These deficiencies would be associated with fertilizing sperm that are incompetent to maintain the fertilization process or subsequent embryogenesis once initiated, with most failures occurring prior to maternal recognition of pregnancy. Such sperm would preempt fertilization by competent sperm. Chromatin aberrations in morphologically normal or near normal spermatozoa from abnormal semen samples appear to be the best candidates for the uncompensable deficiency. However, recognition of uncompensable or incompetent fertilizing sperm has not been achieved. Six-day-old non-surgically recovered bovine ova/embryos have been used to evaluate compensable and uncompensable seminal deficiencies as well as to test reproductive strategies. These ova/embryos provide information on fertilization status and embryo quality as well as quantitative and qualitative data regarding associated accessory sperm. Thus, they permit the separation of reproductive failure by fertilization from that by embryonic development. Accessory sperm number is positively associated with both fertilization rate and embryonic quality. Early insemination results in low fertilization rates (low accessory sperm number), but good embryo quality, whereas, late insemination results in high fertilization rates (high accessory sperm number), but poor embryo quality. Additional studies will be necessary to substantiate this model; however, if true, future research designed to improve results to artificial insemination should be tested by breeding early in estrus where sperm viability is most limiting and embryo quality is best.

Bull sperm surface "craters" and other aspects of semen quality

Semen from 200 Holstein bulls in an artificial insemination center was examined for the frequency of craters on the surface of sperm heads, as visualized with the aid of differential interference contrast microscopy. Semen from 100 of these bulls was examined in more detail in 2 experiments by staining with eosin-aniline blue to determine the relationship of unstained spermatozoa, and spermatozoa with normal acrosomes with apical ridges to the incidence of craters and fertility. Only 3 of 100 bulls had a substantial incidence of craters (15 to 23%), whereas the average of the other 97 bulls in 2 experiments was 1 to 3%. The percentage of sperm cells with craters was correlated (P < 0.05) with the percentage of unstained spermatozoa (r = -0.29 and sperm cells with normal acrosomes (r = -0.52) but was not significantly correlated (r = -0.24) with the nonreturn rate. One bull with many sperm cells with craters was slaughtered, and the epididymal spermatozoa were examined. The high incidence of sperm cells with craters was limited to one side, with the testis on that side having 2 Sertoli cell tumors. The remaining 2 bulls as well as one other that produced 16% of sperm cells with craters did so only temporarily. Within a few months crater sperm production had decreased and semen quality increased. The condition usually appears to be transitory, presumably due to temporary stress.

Can spermatozoa with abnormal heads gain access to the ovum in artificially inseminated super- and single-ovulating cattle?

The collective efficiency of barriers in the female tract against spermatozoa with abnormal heads was studied. In Experiment 1, Day 6 ova/embryos were recovered nonsurgically from superovulated (n = 24) and single-ovulating (n = 44) cows following artificial insemination with semen of bulls selected for normal spermatozoal motility (> or = 50%) and high content (> 30%) of spermatozoa with misshapen heads, random nuclear vacuoles or the diadem defect. To assess characteristics of spermatozoa capable of traversing barriers in the female tract, accessory spermatozoa were classified morphologically (x 1250) and compared with those of the inseminate. Superovulated cows proved inadequate for assessment of accessory spermatozoa due to evidence of poor sperm retention in the zona pellucida; thus, only single-ovulating cows were used. Accessory spermatozoa (n = 479) from 31 ova/embryos recovered from 44 cows were more normal in head shape than those in the inseminate (76 vs 62%; P < 0.05). Spermatozoa with normal head shape, but with nuclear vacuoles appeared as accessory spermatozoa at the same frequency as they were found in the inseminate (20 vs 17%, respectively). Only sperm cells with subtly misshapen heads appeared as accessory spermatozoa. In Experiment 2, semen pooled from 4 bulls having large numbers of spermatozoa exhibiting a gradation from severely asymmetrically misshapen heads to subtly misshapen heads was evaluated. Again, the accessory sperm population (960 sperm cells recovered from 64 ova/embryos) was enriched with spermatozoa of normal head shape relative to the inseminate (53 vs 26%, respectively; P < 0.05). Sperm cells with only nuclear vacuoles and those with subtly misshapen heads were not different between the accessory and inseminate populations (11 vs 8%, and 20 vs 25%, respectively). We conclude that morphologically abnormal spermatozoa are excluded from the accessory sperm population based upon severity of head shape distortion.

Diadem/crater defects in spermatozoa from two related angus bulls

The diadem/crater defect was studied over several months in two related 20-month-old Angus bulls. In bull 1, diadem/crater defects were present in 2-99% of ejaculated spermatozoa at various times during the evaluation period. In bull 2, affected cells varied from 20% to 94%, with other abnormalities (head and acrosome defects, coiled tails, proximal cytoplasmic droplets) also common. Single sire mating trials conducted over 26 days during an apparent recovery phase showed normal fertility (approximately 50% pregnancies per estrus exposed). Both resting and gonadotropin-releasing hormone (GnRH)-stimulated testosterone values were within nor-mal limits. Histopathological evaluation of testes showed no obvious hypoplastic, inflammatory, or degenerative condition. Electron microscopy of ejaculated spermatozoa demonstrated the characteristic diadem pattern of craters in the equatorial region of the head. Many cells from bull 2 contained large craters in other regions of the nucleus. Electron microscopy of testicular tissue demonstrated nuclear invaginations lined by a single unit membrane in round spermatids. Lesions in elongated spermatids were more pronounced, with curling of the nucleus and large membrane-filled cavities in the chromatin occurring in addition to craters in the equatorial region of the nucleus.

Crater defect in human spermatozoa

This report describes the "crater defect" in human spermatozoa, a malformation that consists of a nuclear and acrosomal invagination present in 100% of the cells, whereas tail structure and motility are fairly normal. The defect occurs during spermiogenesis. A possible concomitance with abnormalities in the microtubular apparatus involved in the sperm molding is discussed.

Ultrastructure of fresh and frozen-thawed spermatozoa of high and low fertility lines of chickens

Level of damage caused by freezing and thawing to four spermatozoal organelles (individual mitochondrion, midpiece, nucleus, and perforatorium) and the relationships of the integrity of these organelles in fresh and frozen-thawed semen with fertility were examined. Semen sample from 10th generation males of a line of chickens selected for increased duration of fertility of frozen-thawed semen and the corresponding randombred control line were used. In both the selected and control lines, the freeze-thaw process caused significant (P less than .05) detrimental damage to the ultrastructure of the mitochondria, midpiece, and perforatorium but not to the nucleus. Types of damage were identical in both lines. Granulated nuclei were observed in both frozen-thawed and freshly ejaculated spermatozoa and were referred to as a nuclear defect. This nuclear defect was associated with reduced fertility, the effect being more severe with frozen-thawed semen. Where the incidence of the nuclear defect was greater than 2% in frozen-thawed semen, fertility was found to be very low or nil regardless of the degree of structural integrity of the mitochondria, midpiece and perforatorium. Highly significant (P less than .01) positive correlation coefficients were observed for percentage fertility 2 to 8 days postinsemination and duration of fertility in days with percentages of normal mitochondria (.80 and .92), midpiece (.79 and .87), nucleus (.86 and .94), and perforatorium (.84 and .97) for fresh semen. With frozen-thawed semen, the positive correlation coefficients were significant (P less than .05) for midpiece (.64 and .69) and nucleus (.63 and .71) and nonsignificant for mitochondria (.52 and .50) and perforatium (.20 and .30).(ABSTRACT TRUNCATED AT 250 WORDS)

Acrosomo-nuclear syndrome in canine sperm

An acrosomo-nuclear syndrome in sperm of an infertile semicryptorchid dog is described. Based on an EM study of developing and mature sperm the syndrome is defined by simultaneous occurrence of these symptoms: 1) intranuclear inclusions of acrosomal origin, 2) maldifferentiated apical segment of acrosome, 3) intraacrosomal inclusions of Sertoli cell origin, 4) characteristic change of nuclear shape and 5) retained cytoplasmic droplet. The cause of the syndrome and possibility of a transfer of somatic factors are discussed.