Two hundred and sixty-five unfertilized human metaphase II (M II) oocytes from an in vitro fertilization program were studied cytogenetically using our chromosomal technique, a gradual fixation-air drying method. Of the 265 oocytes, 185 (70%) were successfully karyotyped. There were 21 aneuploids (11.4%) consisting of 8 hyperhaploids (4.3%), 11 hypohaploids (5.9%) and 2 complex cases (1.1%). There were also 9 structural anomalies (4.9%) and 18 diploids (9.7%). In aneuploidy, the loss or gain of dyads (so-called nondisjunction) occurred more frequently than the loss or gain of monads (so-called predivision). The frequency of abnormally behaved chromosomes (segregation errors) due to nondisjunction, anaphase lag and predivision was studied among the seven chromosomal groups (A-G) and compared with the frequency expected from an equal probability of segregation errors in each of the 23 chromosomes. The observed frequency was somewhat higher than the expected frequency in groups E and G but the difference was not statistically significant in either group. These results were discussed in relation to previous studies on human M II oocyte chromosomes.
Chinese hamster spermatozoa gain their ability to move when they descend from the testis to the distal part of the caput epididymis, but it is not until they enter the corpus epididymis that they become capable of fertilizing eggs. The maturation of the spermatozoa proceeds as they further descend the tract and perhaps continues even in the vas deferens. During transit between the distal caput and proximal cauda epididymides, small membrane-limited vesicles (and tubules) appear on the plasma membrane over the acrosomes of the spermatozoa. The number of vesicles appearing on the sperm brane reaches a maximum when the spermatozoa are in the proximal cauda epididymis. It declines sharply in the distal cauda epididymis. Spermatozoa in the vas deferens are free of the vesicles. The origin, chemical nature, and functional role of the vesicles that appear on the sperm surface during epididymal transit must be the subject of further investigation.
We have developed an improved method for analyzing human sperm chromosome, using zona-free hamster ova. Our main improvements of methodology are as follows: (1) Fertilization rate of hamster oocytes by human spermatozoa was markedly raised by successive treatments of the spermatozoa with 5-15 piM ionophore A23 187 solutions and a capacitation medium (BWW medium) containing 3.5% HSA. The HSA most effective in inducing capacitation was selected from several kinds of HSA products commercially available. (2) Monospermic fertilization was ensured by inseminating oocytes with highly capacitated spermatozoa at a low concentration for a short time. (3) TC medium 199 was used for postinsemination culture of the eggs. (4) A medium containing podophyllotoxin and vinblastine (0.04 jig/ml each) was used to block karyogamy and first-cleavage spindle formation. (5) Chromosome slides were prepared with our gradual fixation-air-dry method instead of Tarkowski's method. Ninety-two to 177 spermatozoa corresponding in number to 43%-79% (mean: 62%) of the inseminated oocytes were successfully karyotyped in each experiment. In spite of above-mentioned quantitative improvements, quality of Q-banding was not necessarily satisfactory in our slides. Improvement of banding technique is an important problem to be solved in our method. Spontaneous incidence of chromosome aberrations was studied in a total of 1,091 spermatozoa obtained from nine semen samples from four donors. Incidences of aneuploidy and structural anomaly were 0.9% (hyperhaploidy, 0.45%; hypohaploidy, 0.45%) and 13.0%, respectively. Structural aberrations included breaks (45.1%), fragments
We have developed an improved method for analyzing human sperm chromosome, using zona-free hamster ova. Our main improvements of methodology are as follows: (1) Fertilization rate of hamster oocytes by human spermatozoa was markedly raised by successive treatments of the spermatozoa with 5-15 piM ionophore A23 187 solutions and a capacitation medium (BWW medium) containing 3.5% HSA. The HSA most effective in inducing capacitation was selected from several kinds of HSA products commercially available. (2) Monospermic fertilization was ensured by inseminating oocytes with highly capacitated spermatozoa at a low concentration for a short time. (3) TC medium 199 was used for postinsemination culture of the eggs. (4) A medium containing podophyllotoxin and vinblastine (0.04 jig/ml each) was used to block karyogamy and first-cleavage spindle formation. (5) Chromosome slides were prepared with our gradual fixation-air-dry method instead of Tarkowski's method. Ninety-two to 177 spermatozoa corresponding in number to 43%-79% (mean: 62%) of the inseminated oocytes were successfully karyotyped in each experiment. In spite of above-mentioned quantitative improvements, quality of Q-banding was not necessarily satisfactory in our slides. Improvement of banding technique is an important problem to be solved in our method.Spontaneous incidence of chromosome aberrations was studied in a total of 1,091 spermatozoa obtained from nine semen samples from four donors. Incidences of aneuploidy and structural anomaly were 0.9% (hyperhaploidy, 0.45%; hypohaploidy, 0.45%) and 13.0%, respectively. Structural aberrations included breaks (45.1%), fragments
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.
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