Sperm FISH analysis of a 44,X,der(Y),t(Y;15)(q12;q10)pat,rob(13;14)(q10;q10)mat complex chromosome rearrangement.

Complex chromosome rearrangements (CCR) with two independent chromosome rearrangements are rare. Although CCRs lead to high unbalanced gamete rates, data on meiotic segregation in this context are scarce. A male patient was referred to our clinic as part of a family screening programme prompted by the observation of a 44,X,der(Y),t(Y;15)(q12;q10)pat,rob(13;14)(q10;q10)mat karyotype in his brother. Karyotyping identified the same CCR. Sperm FISH (with locus-specific probes for the segments involved in the translocations and nine chromosomes not involved in both rearrangements) was used to investigate the rearrangements meiotic segregation products and establish whether or not an inter-chromosomal effect was present. Sperm nuclear DNA fragmentation was also evaluated. For rob(13;14) and der(Y), the proportions of unbalanced products were, respectively, 26.4% and 60.6%. Overall, 70.3% of the meiotic segregation products were unbalanced. No evidence of an inter-chromosomal effect was found, and the sperm nuclear DNA fragmentation rate was similar to our laboratory's normal cut-off value. In view of previously published sperm FISH analyses of Robertsonian translocations (and even though the mechanism is still unknown), we hypothesise that cosegregation of der(Y) and rob(13;14) could modify rob(13;14) meiotic segregation.

A genome-wide DNA methylation study in azoospermia.

The objective of this study was to assess genome-wide DNA methylation in testicular tissue from azoospermic patients. A total of 94 azoospermic patients were recruited and classified into three groups: 29 patients presented obstructive azoospermia (OA), 26 displayed non-obstructive azoospermia (NOA) and successful retrieval of spermatozoa by testicular sperm extraction (TESE+) and 39 displayed NOA and failure to retrieve spermatozoa by TESE (TESE-). An Illumina Infinium Human Methylation27 BeadChip DNA methylation array was used to establish a testicular DNA methylation pattern for each type of azoospermic patient. The OA and NOA groups were compared in terms of the relative M-value (the log2 ratio between methylated and non-methylated probe intensities) for each CpG site. We observed significantly different DNA methylation profiles for the NOA and OA groups, with differences at over 9000 of the 27 578 CpG sites; 212 CpG sites had a relative M-value >3. The results highlighted 14 testis-specific genes. Patient clustering with respect to these 212 CpG sites corresponded closely to the clinical classification. The DNA methylation patterns showed that in the NOA group, 78 of the 212 CpG sites were hypomethylated and 134 were hypermethylated (relative to the OA group). On the basis of these DNA methylation profiles, azoospermic patients could be classified as OA or NOA by considering the 212 CpG sites with the greatest methylation differences. Furthermore, we identified genes that may provide insight into the mechanism of idiopathic NOA.

Small human sperm vacuoles observed under high magnification are pocket-like nuclear concavities linked to chromatin condensation failure.

Since an embryo's ability to grow to the blastocyst stage and implant can be improved by selection of a normal spermatozoon with a vacuole-free head, this study set out to determine the nature of small sperm vacuoles observed under high magnification (>×6300). For 15 infertile men with various sperm profiles, high-magnification microscopy was used to select motile, morphometrically normal spermatozoa with no vacuoles (n=450) or more than two small vacuoles (each of which occupied less than 4% of the head's area; n=450). Spermatozoa acrosome reaction status and degree of chromatin condensation were analysed. Three-dimensional deconvolution microscopy was used to accurately image the nucleus and acrosome at all depths in all spermatozoa. In all 450 spermatozoa with small vacuoles, the latter were seen to be abnormal, DNA-free nuclear concavities. Spermatozoa with small vacuoles were significantly more likely than vacuole-free spermatozoa to have noncondensed chromatin (39.8% versus 9.3%, respectively; P<0.0001). There was no significant difference between the two groups of spermatozoa in terms of acrosome reaction status. No association between chromatin condensation and acrosome reaction status was observed. Small human sperm vacuoles observed under high magnification are pocket-like nuclear concavities related to failure of chromatin condensation.

Selection of normal spermatozoa with a vacuole-free head (x6300) improves selection of spermatozoa with intact DNA in patients with high sperm DNA fragmentation rates.

Intracytoplasmic morphologically selected sperm injection (IMSI, 6300× magnification with Nomarski contrast) of a normal spermatozoon with a vacuole-free head could improve the embryo's ability to grow to the blastocyst stage and then implant. However, the most relevant indications for IMSI remain to be determined. To evaluate the potential value of IMSI for patients with a high degree of sperm DNA fragmentation (n = 8), different types of spermatozoa were analysed in terms of DNA fragmentation. Motile normal spermatozoa with a vacuole-free head selected at 6300× magnification had a significantly lower mean DNA fragmentation rate (4.1 ± 1.1%, n = 191) than all other types of spermatozoa: non-selected spermatozoa (n = 8000; 26.1 ± 1.5% versus 4.1 ± 1.1%; P < 0.005), motile spermatozoa (n = 444; 20.8 ± 2.7% versus 4.1 ± 1.1%; P < 0.001) and motile, normal spermatozoa selected at 200× magnification (n = 370; 18.7 ± 2.7% versus 4.1 ± 1.1%; P < 0.001) and then motile, morphometrically normal spermatozoa with anterior vacuoles (n = 368; 15.9 ± 2.9% versus 4.1 ± 1.1%; P < 0.05) or posterior vacuoles (n = 402; 22.5 ± 3.6% versus 4.1 ± 1.1%; P < 0.001) selected at 6300× magnification. For patients with high sperm DNA fragmentation rates, selection of normal spermatozoa with a vacuole-free head (6300×) yields the greatest likelihood of obtaining spermatozoa with non-fragmented DNA.

Inverse correlation between chromatin condensation and sperm head size in a case of enlarged sperm heads.

Among sperm morphology abnormalities, macrocephalic and large-headed spermatozoa are commonly associated with a low chance of pregnancy, mainly in relation to meiotic abnormalities during spermatogenesis. Here is reported the case of a patient with 98% of spermatozoa showing abnormal morphology, many having enlarged heads (47%). Sperm-head measurement, sperm fluorescent in situ hybridization analysis, sperm chromatin decondensation and molecular biology were performed. Fifty-six percent of the sperm displayed a large head (length >4.7 µm and width >3.2 µm), and the mean sperm-head area was 15.8±3.8 µm(2) (9.7±1.5 µm(2) and 9.3±1.4 µm(2) for two controls). Normal chromosomal content was found in 97% of the cells and no aurea kinase C-gene mutation was found. Mean sperm chromatin decondensation rate was 46%, 64% for large-head forms and 10% for other forms. This is, as far as is known, one of the first cases of semen with enlarged-head spermatozoa linked to sperm chromatin condensation dysfunction with no major meiotic dysfunction. The study centre advised the couple to undergo intracytoplasmic sperm injection with the patient's spermatozoa.

Large human sperm vacuoles observed in motile spermatozoa under high magnification: nuclear thumbprints linked to failure of chromatin condensation.

BACKGROUND: An embryo's ability to grow and implant can be improved by selection of a normal spermatozoon with a vacuole-free head. However, large vacuoles in spermatozoa have yet to be fully characterized. The present study aimed to determine whether these vacuoles are of nuclear, membrane and/or acrosomal origin. METHODS: We studied 15 infertile patients with differing sperm profiles. For each sperm sample, we used high-magnification (×10 000) contrast microscopy to select and assess 30 normal 'top' spermatozoa and 30 spermatozoa with a large sperm-head vacuole (≥ 25% of the head's cross-sectional area). We subsequently analysed the spermatozoa's degree of chromatin condensation (aniline blue staining), DNA fragmentation (terminal deoxyribonucleotidyl transferase-mediated dUTP nick-end labelling assay) and chromosome content (fluorescence in situ hybridization X,Y,18). Atomic force microscopy enabled us to map the plasma sperm membrane in detail. Three-dimensional deconvolution microscopy enabled us to reconstruct images of the nucleus and acrosome in 'top' and 'vacuolated' spermatozoa. RESULTS: We studied a total of 450 'top' spermatozoa and 450 vacuolated spermatozoa. The rate of non-condensed chromatin was higher for 'vacuolated' spermatozoa than for 'top' spermatozoa (36.2 ± 1.9 versus 7.6 ± 1.3%, respectively; P < 0.0001). 'Top' and 'vacuolated' spermatozoa did not differ significantly in terms of DNA fragmentation (0.7 ± 0.4 versus 1.3 ± 0.4% respectively; P = 0.25) or aneuploidy (1.1 ± 0.5 versus 2.2 ± 0.7% respectively; P = 0.21). The majority of aneuploid spermatozoa (9 out of 15) lacked chromatin condensation. In all vacuolated spermatozoa, the acrosome was intact, the plasma membrane was sunken but intact and the large vacuole was identified as an abnormal, 'thumbprint'-like nuclear concavity covered by acrosomal and plasmic membranes. CONCLUSIONS: The large vacuole appears to be a nuclear 'thumbprint' linked to failure of chromatin condensation.