J. Gosálvez

DNA breakage detection-FISH (DBD-FISH) in human spermatozoa: technical variants evidence different structural features

Non-irradiated and X-irradiated (80 Gy) human spermatozoa were processed for in situ DNA breakage detection-FISH (DBD-FISH) of the whole genome, following two alternative variations of the basic technique. In the first, cells were initially incubated in the alkaline unwinding solution for transformation of DNA breaks into single-stranded DNA (ssDNA) to be hybridized, followed by the lysing solutions for protein removal. In the second, incubation in the lysing solutions was carried out before the denaturation step. The first approach yielded two subpopulations. While most sperm nuclei were faintly labeled and had chromocenters, a small subpopulation was strongly and homogeneously labeled, due to extensive DNA breakage. X-ray exposure increased the surface and mean fluorescence intensity. Otherwise, when the denaturation step was performed after protein extraction, all sperm nuclei yielded strong and dispersed FISH signals. Protein removal allows access of the unwinding solution to the DNA, which has abundant alkali-labile sites, and thus gives rise to large areas of ssDNA that are labeled by FISH. X-ray exposure increased the dispersion of FISH signals but decreased their mean fluorescence intensity. A linear dose-response was generated using the second experimental variant, being 30 Gy the lowest dose for detecting induction of damage by X-rays in mature sperm chromatin. These results indicate that DBD-FISH is not only useful for in situ detection of DNA breakage but also for revealing structural features of chromatin.

Dynamics of sperm DNA fragmentation in domestic animals III. Ram.

From a biological viewpoint spermatozoa are ejaculated by the male and received into the female while maintaining roughly constant temperature, which in most mammals is below the temperature of the soma. When ejaculated spermatozoa are used for artificial reproductive purposes a temperature excursion episode is produced, because the spermatozoa are often stored as frozen or chilled samples and the biological temperature is only recovered after insemination. In this study we have analyzed the effects of cooling (to 15 degrees C) and freezing ram spermatozoa on the subsequent sperm DNA fragmentation index (sDFI) during a varying period of storage at 37 degrees C. The aim was to emulate in vivo processes that cooled or frozen-thawed spermatozoa experience after insemination. The study was performed using commercial semen samples derived from rams regularly used for reproductive purposes. Semen samples were studied after a cooling or cryopreservation episode followed by biological temperature recovery and incubation up to 48 h. The results indicated that when spermatozoa experience a severe (frozen) or mild (cooled) temperature excursion episode, major effects on sperm viability and DNA fragmentation are induced and cause the subsequent rapid decline of ram sperm quality. This effect could be detected just at the onset of the biological temperature recovery. Sperm DNA damage in cooled samples was observed after 5 h of incubation at 37 degrees C, while this time was reduced to less than 60 min in frozen-thaw samples. The dynamics of sDFI in different animals, analyzed under the same experimental conditions, was different from one sample to another, regardless of the method used for storage. Sperm viability was better preserved in cooled rather than in frozen samples. While for the frozen-thawed samples sperm viability was almost abolished after 5 h of incubation, a stable proportion of viable spermatozoa (ranging from 20% to 60%) was observed in the cooled samples at the corresponding time points. Finally, with respect to the prevalence of sDFI in ram, the level commonly found was lower than 5% at the onset of the experiment. However, sDFI was higher than 5% in 25% of the samples and in 15% of rams this index exceeded 10%.

Sex-sorted bovine spermatozoa and DNA damage: I. Static features

This study examined the static response of Spermatozoa DNA Fragmentation (SDF) after sex selection in bulls using a MoFlo(®) SX (Beckman Coulter, Miami FL) spermatozoa sorter to produce three different subpopulations: 1) Spermatozoa bearing X- chromosomes with a purity of 95%, 2) Spermatozoa bearing Y-chromosomes with a purity of 95%, and 3) non-viable spermatozoa. The static response of SDF refers to the baseline values observed for DNA damage when analyzed pre- and post sex-sorting. Results showed that while the baseline level SDF in pre-sorted bull spermatozoa samples ranged from 5.3% to 11% with an average of 7.9% ± 2.1%, the level of SDF obtained in X- and Y-chromosome sorted samples was much lower (3.1% ± 1.9%) and statistical differences were obtained after comparing both groups (P < 0.01). Spermatozoa containing a fragmented DNA molecule tend to be accumulated in the non-viable subpopulation. The baseline SDF level in X- and Y-chromosome sorted subpopulations is reduced, by 63% on average when compared to the values obtained in the neat semen sample. Different bulls exhibit unique SDF reduction efficiencies via the X- and Y-chromosome sex selection process.

DNA fragmentation in frozen sperm of Equus asinus: Zamorano-Leonés, a breed at risk of extinction.

The dynamics of sperm DNA fragmentation (sDF) and sperm viability were analyzed in frozen-thawed sperm samples of Equus asinus (Zamorano-Leonés), a breed at risk of extinction. Sperm DNA fragmentation was assessed using an adaptation of the sperm chromatin dispersion test developed for stallions in five different frozen samples. Sperm were thawed and incubated at different temperatures (37 degrees C, 25 degrees C, and 4 degrees C) and sDF was assessed at different times and compared. The mean sDF after thawing at the beginning of the experiment was 18.20+/-14.77% and did not differ significantly from the results of a neutral comet assay (22.0+/-19.34%). The tendency in the sDF of all donkeys indicated that sperm DNA is more sensitive to breakage when incubated at 37 degrees C than when incubated at 25 degrees C or 4 degrees C. Interestingly, the tendency was not the same when different animals were compared, and differences in sDF dynamics were established among individuals. sDF correlated negatively with sperm viability in some individuals but not in others. From a conservation perspective, sDF analysis may offer a new way to assess sperm quality in endangered breeds in order to identify and select the best semen samples for artificial reproduction purposes. In particular, we recommend for artificial insemination the use of semen samples with a slow increase in sDF with time after thawing.

Effects of oral antioxidant treatment upon the dynamics of human sperm DNA fragmentation and subpopulations of sperm with highly degraded DNA

The primary aim of this study was to determine the effect of oral antioxidant treatment (1500 mg of l‐Carnitine; 60 mg of vitamin C; 20 mg of coenzyme Q10; 10 mg of vitamin E; 10 mg of zinc; 200 μg of vitamin B9; 50 μg of selenium; 1 μg of vitamin B12) during a time period of 3 months upon the dynamics of sperm DNA fragmentation following varying periods of sperm storage (0 h, 2 h, 6 h, 8 h and 24 h) at 37 °C in a cohort of 20 infertile patients diagnosed with asthenoteratozoospermia. A secondary objective was to use the sperm chromatin dispersion test (SCD) to study antioxidant effects upon a specific subpopulation of highly DNA degraded sperm (DDS). Semen parameters and pregnancy rate (PR) were also determined. Results showed a significant improvement of DNA integrity at all incubation points (P < 0.01). The proportion of DDS was also significantly reduced (P < 0.05). Semen analysis data showed a significant increase in concentration, motility, vitality and morphology parameters. Our results suggest that antioxidant treatment improves sperm quality not only in terms of key seminal parameters and basal DNA damage, but also helps to maintain DNA integrity. Prior administration of antioxidants could therefore promote better outcomes following assisted reproductive techniques.

Application of FISH for in situ detection and quantification of DNA breakage.

We describe a simple procedure that allows the use of fluorescence in situ hybridization (FISH) for in situ detection of DNA strand breaks in single cells (DBD-FISH: DNA Breakage Detection-FISH). After trapping within an agarose microgel, cells are incubated in an unwinding alkaline solution, deproteinized and dehydrated. Areas of single-stranded DNA are generated by the alkaline solution in proportion to the degree of DNA strand breakage. These then act as targets for FISH of whole genomic or region-specific probes (telomeric, human chromosome 8 painting, human alphoid DXZ1 locus, and human c-erbB-2 cosmid probes). Measurement of the amount and surface of FISH signals provides information on the breakage level in probed areas, permitting the assessment of possible intragenomic differences in sensitivity as well as intercellular heterogeneity in DNA damage induction or repair.

Dynamics of sperm DNA damage in fresh versus frozen–thawed and gradient processed ejaculates in human donors

The rate of increase of sperm DNA fragmentation (rsDF) in fresh and frozen–thawed and processed sperm samples after a density gradient for sperm selection was analysed after 0, 0.5, 1.5, 4.5, 6, 24, 48 and 72 h of incubation at 37 °C, in five donors with proven fertility. The results showed that: (i) sperm DNA fragmentation (sDF) at baseline in fresh samples (14.3 ± 3.3) was lower than that obtained after freeze‐thawing and selection (19.4 ± 4.1), significant differences; (ii) After 6 h of incubation the mean sDF in fresh samples (24.2 ± 10.2) was significantly lower than that in frozen–thawed samples (45.3 ± 7.1); (iii) Subsequently, the rsDF in fresh semen samples was 1.6% per h after 6 h of incubation, while after thawing and selection the rsDF was 4.3% per h; The tendency to increase in sDF showed high R2 values (R2 = 0.90) for exponential functions in case of fresh samples, whereas R2 values for linear functions were higher after sperm selection (R2 = 0.97). These results indicate that differences in sperm DNA fragmentation dynamics before and after storage are an important issue that must be considered for storage of sperm to be used for artificial reproduction techniques.

Dynamics of sperm DNA fragmentation in the swine: Ejaculate and temperature effects

The dynamics of sperm DNA fragmentation was examined in 16 boar ejaculates using the sperm chromatin dispersion (SCD) test and a two-tail comet assay. The net sperm rich fraction was preserved at two different temperatures (Trial 1: 15 degrees C, n=10; Trial 2: 37 degrees C, n=6) and sub-samples were taken every day until a sperm motility of zero. Significant differences in the dynamics of DNA fragmentation were observed among the different ejaculates and also according to the storage temperature. After analyzing the dynamic response of the sperm DNA damage, when the sperm samples are incubated at 15 or 37 degrees C, each ejaculate could be classified and a considerable variation among individuals for an increase in DNA damage was observed. Thus, while in some ejaculates no rise in DNA fragmentation was observed, in others, the sperm DNA fragmentation process was triggered during the initial days of the experiment. In general, sperm incubation at 37 degrees C diminished sperm DNA quality. The two-tail comet assay indicated that at time zero existing DNA damage mainly consisted of double stranded DNA breakage. During storage, DNA damage affected one of the DNA strands until a second wave of DNA damage, in which there was both single and double stranded DNA damage.

Frozen-thawed rhinoceros sperm exhibit DNA damage shortly after thawing when assessed by the sperm chromatin dispersion assay

This study reports on the successful validation (via in situ nick translation and neutral comet assay) of the equine Sperm-Halomax kit as an appropriate methodology for the assessment of sperm DNA fragmentation in three species of rhinoceros. Rhinoceros sperm nuclei with fragmented DNA (validated using in situ nick translation) were evident as large halos with dispersed DNA fragments, whereas those with nonfragmented DNA displayed small halos of nondispersed DNA within the microgel. There was a high correlation (r) of 0.974 (R(2) value=0.949; P<0.01; n=16) between the respective assessments of the Sperm Chromatin Dispersion test (SCDt) and the neutral comet assay. Application of the SCDt to determine the DNA fragmentation dynamics of rhinoceros (n=6) sperm frozen in liquid nitrogen vapor and incubated postthaw at 37 degrees C for up to 48 h to mimic in vitro conditions in the female reproductive tract, revealed an increase (P=0.001) in DNA damage, as soon as 4h after the start of incubation. Linear regression equations were calculated for all six rhinoceroses over the first 6h of incubation and revealed individual animal variation. Freshly collected and incubated (37 degrees C) rhinoceros (n=3) sperm had no increase in the basal level of DNA fragmentation for up to 48 h, indicating that the cryopreservation of rhinoceros sperm in liquid nitrogen vapor, as used in this study, appeared to result in freeze-thaw DNA damage.

Bacteria in bovine semen can increase sperm DNA fragmentation rates: A kinetic experimental approach

Cryopreserved straws of semen (n=228) from Holstein bulls (n=47) were examined for bacterial presence and sperm DNA fragmentation (SDF) dynamics. Commercial semen doses (representing six ejaculates per individual) were randomly selected from a bull stud in Spain. The dynamics of SDF were assessed after thawing (T0) and at 4, 24, 48, 72 and 96h of incubation at 37°C, using the commercial variant of the sperm chromatin dispersion test for Bovine (Halomax®). One group of bulls showed a bacterial presence in semen samples between 0 and 96h of incubation (n=23, group A) while the other did not (n=24, group B). Immediate post-thaw differences in SDF were not observed when both groups were compared. However, the rate of increase in SDF (rSDF) over time, considered as an estimate of the kinetic behaviour of sperm DNA survival, was significantly higher (P<0.05) in semen samples from group A (0.7% per hour) versus group B (0.05% per hour). Polymerase Chain Reaction (PCR) assay was used for DNA amplification using primers designed for specific regions of the bacterial gene that codifies for 16S rRNA. Different species within the phyla Bacteroidetes, Firmicutes, Proteobacteria, Cyanobacteria, Fusobacteria and Actinobacteria were identified. The results show that (1) SDF at baseline (T0) may not be affected by the presence of bacteria but the rSDF can increase due to bacterial growth during incubation, (2) the increase in the rSDF is characteristic of some bulls but not for others, and (3) certain bacterial strains are repeatedly found in separate ejaculates from the same bull.