Maria Oliver-Bonet

Segregation of chromosomes in sperm of reciprocal translocation carriers: a review.

Reciprocal translocations, the most frequent structural aberration in humans, are mainly transmitted by one of the parents. In order to analyze the chromosomal content of the spermatozoa from carriers of chromosomal reorganizations, two methods have been used, karyotyping of sperm chromosomes by the human-hamster system and fluorescence in situ hybridization (FISH) in decondensed sperm nuclei. In this work, we review 92 sperm chromosome segregation studies from 85 different reciprocal translocation carriers, including a triple translocation carrier. Using the human-hamster method, a total of 5,818 spermatozoa from 44 reciprocal translocation carriers have been analyzed, 43 of them carrying a single reciprocal translocation and one was a carrier of a double reciprocal translocation. A segregation analysis in a carrier of a t(2;22;11) has been also reported. Carrying out FISH in sperm nuclei, a total of 237,042 spermatozoa from 46 reciprocal translocation carriers have been analyzed. Six of these were also analyzed by the human-hamster system. Taking into account both methods, a total of 76 different reciprocal translocations have been studied. In 74 of these 76 translocations, the reorganization occurs between autosomes, and in the other two, the Y chromosome is involved. Although along general lines, there are similarities between the results obtained by the two methods of analysis, variations are observed when the distribution of the different types of segregations that produce imbalances is compared. As a general rule reciprocal translocation carriers produce more unbalanced sperm than normal or balanced sperm. The results reported also corroborate that the proportion of unbalanced forms depends on the characteristics of the reorganization and that it varies widely. Thus the importance of performing a detailed meiotic behavior analysis for each particular translocation in order to obtain enough information to give adequate genetic counseling is stressed. Aspects as to the possible overestimation of 3:1 segregations or the presence of interchromosomal effects still need to be elucidated.

Meiotic abnormalities in infertile males

Meiotic anomalies, as reviewed here, are synaptic chromosome abnormalities, limited to germ cells that cannot be detected through the study of the karyotype. Although the importance of synaptic errors has been underestimated for many years, their presence is related to many cases of human male infertility. Synaptic anomalies can be studied by immunostaining of synaptonemal complexes (SCs), but in this case their frequency is probably underestimated due to the phenomenon of synaptic adjustment. They can also be studied in classic meiotic preparations, which, from a clinical point of view, is still the best approach, especially if multiplex fluorescence in situ hybridization is at hand to solve difficult cases. Sperm chromosome FISH studies also provide indirect evidence of their presence. Synaptic anomalies can affect the rate of recombination of all bivalents, produce achiasmate small univalents, partially achiasmate medium-sized or large bivalents, or affect all bivalents in the cell. The frequency is variable, interindividually and intraindividually. The baseline incidence of synaptic anomalies is 6–8%, which may be increased to 17.6% in males with a severe oligozoospermia, and to 27% in normozoospermic males with one or more previous IVF failures. The clinical consequences are the production of abnormal spermatozoa that will produce a higher number of chromosomally abnormal embryos. The indications for a meiotic study in testicular biopsy are provided.

DNA fragmentation and meiotic segregation in sperm of carriers of a chromosomal structural abnormality

OBJECTIVE To determine the meiotic segregation and DNA fragmentation in spermatozoa of carriers of a chromosomal structural abnormality. DESIGN Case series. SETTING University hospital. PATIENT(S) Thirty-seven male carriers of a chromosomal structural abnormality (21 with a balanced reciprocal translocation, 7 with a robertsonian translocation, 9 with a pericentric inversion). INTERVENTION(S) Meiotic segregation was analyzed by the human sperm-hamster oocyte fusion technique or by fluorescent in situ hybridization, and DNA fragmentation was detected by terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling assay. MAIN OUTCOME MEASURE(S) Relationships between abnormal sperm parameters, DNA fragmentation, and meiotic mechanisms. RESULT(S) The average rates of chromosomally unbalanced spermatozoa were 55.22%, 14.09%, and 18.43% for reciprocal translocation, robertsonian translocation, and pericentric inversion carriers, respectively. The rates of DNA fragmentation were significantly higher in the whole group of carriers of a chromosomal structural abnormality and in each specific group than in the control group. No correlations between sperm DNA fragmentation and parameters of spermogram, age, or percentage of unbalanced chromosomal gametes were found. CONCLUSION(S) The DNA fragmentation rate depends solely on the presence of a chromosomal structural abnormality, and, therefore, a chromosomal structural abnormality predicts DNA fragmentation. Both meiotic segregation and DNA fragmentation studies should be integrated in the genetic exploration of male carriers of a chromosomal structural abnormality.

Meiotic segregation analysis in a t(4;8) carrier: comparison of FISH methods on sperm chromosome metaphases and interphase sperm nuclei

Meiotic segregation of a t(4;8)(q28;p23) translocation carrier was determined by two different methods to compare the final results. A total of 352 sperm chromosome complements, obtained after human-hamster in vitro fertilisation, were analysed by whole chromosome painting, and 6590 sperm heads were studied by fluorescence in situ hybridisation (FISH). Frequencies of alternate, adjacent I, adjacent II and 3 : 1 segregations were, for sperm chromosomes, 35.5, 33.2, 19.9 and 11.3% respectively. For sperm head analysis, results were 30.5, 28.5, 20.5 and 19.5% respectively. There were no statistically significant differences between the two methods with respect to the observed frequencies of sperm with balanced and unbalanced chromosome constitutions. Among unbalanced gametes, the methods differed only in the frequency of 3 : 1 segregation (χ2, P<0.0001). Different factors that could explain this result are discussed. To determine possible interchromosomal effects, multicolour FISH was used on sperm heads. Disomy rates of sex and 18 chromosomes were higher in the translocation carrier than in the control. The differences observed were statistically significant (P<0.0001 for chromosomes X and 18, and P=0.0091 for chromosome Y).

Evolution of recombination in eutherian mammals: insights into mechanisms that affect recombination rates and crossover interference

Recombination allows faithful chromosomal segregation during meiosis and contributes to the production of new heritable allelic variants that are essential for the maintenance of genetic diversity. Therefore, an appreciation of how this variation is created and maintained is of critical importance to our understanding of biodiversity and evolutionary change. Here, we analysed the recombination features from species representing the major eutherian taxonomic groups Afrotheria, Rodentia, Primates and Carnivora to better understand the dynamics of mammalian recombination. Our results suggest a phylogenetic component in recombination rates (RRs), which appears to be directional, strongly punctuated and subject to selection. Species that diversified earlier in the evolutionary tree have lower RRs than those from more derived phylogenetic branches. Furthermore, chromosome-specific recombination maps in distantly related taxa show that crossover interference is especially weak in the species with highest RRs detected thus far, the tiger. This is the first example of a mammalian species exhibiting such low levels of crossover interference, highlighting the uniqueness of this species and its relevance for the study of the mechanisms controlling crossover formation, distribution and resolution.

Birth of a healthy boy after a double factor PGD in a couple carrying a genetic disease and at risk for aneuploidy: Case Report

Preimplantation genetic diagnosis (PGD) for monogenic diseases is widely applied, allowing the transfer to the uterus of healthy embryos. PGD is also employed for the detection of chromosome abnormalities for couples at high risk of producing aneuploid embryos, such as advanced maternal (>35 years). A significant number of patients requesting PGD for monogenic diseases are also indicated for chromosome testing. We optimized and clinically applied a PGD protocol permitting both cytogenetic and molecular genetic analysis. A couple, carriers of two cystic fibrosis (CF) mutations (c.3849 + 10 KbC > T and c.3408C > A) with a maternal age of 38 years and two previously failed IVF-PGD cycles, was enrolled in the study. After ovarian stimulation, six oocytes were obtained. To detect abnormalities for all 23 chromosomes of the oocyte, the first polar body (1PB) was biopsied from five of the oocytes and analyzed using comparative genomic hybridization (CGH). CGH analysis showed that 1PB 1 and 1PB 4 were aneuploid (22X,-9,-13,+19 and 22X,-6, respectively), while 1PB 2, 1PB 3 and 1PB 6 were euploid. Blastomere biopsy was only applicable on embryos formed from Oocyte 3 and Oocyte 6. After whole-genome amplification with multiple displacement amplification, a multiplex PCR, amplifying informative short tandem repeats (D7S1799; D7S1817) and DNA fragments encompassing the mutation sites, was performed. MiniSequencing was applied to directly detect each mutation. Genetic diagnosis showed that Embryo 6 was affected by CF and Embryo 3 carried only the c.3849 + 10 KbC > T mutation. Embryo 3 was transferred achieving pregnancy and a healthy boy was born. This strategy may lead to increased pregnancy rates by allowing preferential transfer of euploid embryos.

Reliability of short comparative genomic hybridization in fibroblasts and blastomeres for a comprehensive aneuploidy screening: first clinical application

BACKGROUND Comparative genomic hybridization (CGH) is a valuable alternative to fluorescence in situ hybridization (FISH) for preimplantation genetic screening (PGS) because it allows full karyotype analysis. However, this approach requires the cryopreservation of biopsied embryos until results are available. The aim of this study is to reduce the hybridization period of CGH, in order to make this short-CGH technique suitable for PGS of Day-3 embryos, avoiding the cryopreservation step. METHODS Thirty-two fibroblasts from six aneuploid cell lines (Coriell) and 48 blastomeres from 10 Day-4 embryos, discarded after PGS by FISH with 9 probes (9-chr-FISH), were analysed by short-CGH. A reanalysis by the standard 72 h-CGH and FISH using telomeric probes was performed when no concordant results between short-CGH and FISH diagnosis were observed. The short-CGH was subsequently applied in a clinical case of advanced maternal age. RESULTS In 100% of the fibroblasts analysed, the characteristic aneuploidies of each cell line were detected by short-CGH. The results of the 48 blastomeres screened by short-CGH were supported by both 72 h-CGH results and FISH reanalysis. The chromosomes most frequently involved in aneuploidy were 22 and 16, but aneuploidies for the other chromosomes, excepting 1, 10 and 13, were also detected. Forty-one of the 94 aneuploid events observed (43.6%) corresponded to chromosomes which are not analysed by 9-chr-FISH. CONCLUSIONS We have performed a preliminary validation of the short-CGH technique, including one clinical case, suggesting this approach may be applied to Day-3 aneuploidy analysis, thereby avoiding embryo cryopreservation and perhaps helping to improve implantation rate after PGS.

Outcome of twin babies free of Von Hippel-Lindau disease after a double-factor preimplantation genetic diagnosis: monogenetic mutation analysis and comprehensive aneuploidy screening

OBJECTIVE To increase the embryo implantation rate, a double-factor preimplantation genetic diagnosis (DF-PGD) was performed, selecting for transfer potentially euploid evolved embryos free of the mutation responsible for Von Hippel-Lindau syndrome (VHL). DESIGN Case report. SETTINGS Medical university center and a private IVF center. PATIENT(S) A patient carrier of the R161Q mutation on the VHL gene. INTERVENTION(S) After first polar body (1PB) biopsy, it was analyzed using comparative genomic hybridization (1PB-CGH). On day +3, mutation detection using minisequencing and short tandem repeat analysis was performed in multiple displacement amplification products of a single blastomere per embryo. MAIN OUTCOME MEASURE(S) Transfering embryos free of the disease and originating from euploid oocytes. RESULT(S) Nine of the twelve oocytes obtained were successfully analyzed using 1PB-CGH. One of them was aneuploid (1PB #1: 29XX,+2,+10,+12,+17,+19), and the rest were euploid. All of the oocytes were fertilized and became evolved embryos. Six of the embryos were VHL unaffected and had good quality. Five (83%) of them were potentially euploid. According to cytogenetic results, two of the evolved and healthy embryos were transfered, achieving the birth of healthy twin babies. CONCLUSION(S) The DF-PGD can be a useful tool to increase implantation of transfered embryos in PGD for monogenic diseases.

Genetic recombination variation in wild Robertsonian mice: on the role of chromosomal fusions and Prdm9 allelic background

Despite the existence of formal models to explain how chromosomal rearrangements can be fixed in a population in the presence of gene flow, few empirical data are available regarding the mechanisms by which genome shuffling contributes to speciation, especially in mammals. In order to shed light on this intriguing evolutionary process, here we present a detailed empirical study that shows how Robertsonian (Rb) fusions alter the chromosomal distribution of recombination events during the formation of the germline in a Rb system of the western house mouse (Mus musculus domesticus). Our results indicate that both the total number of meiotic crossovers and the chromosomal distribution of recombination events are reduced in mice with Rb fusions and that this can be related to alterations in epigenetic signatures for heterochromatinization. Furthermore, we detected novel house mouse Prdm9 allelic variants in the Rb system. Remarkably, mean recombination rates were positively correlated with a decrease in the number of ZnF domains in the Prdm9 gene. The suggestion that recombination can be modulated by both chromosomal reorganizations and genetic determinants that control the formation of double-stranded breaks during meiosis opens new avenues for understanding the role of recombination in chromosomal speciation.

Differential Clustering of Sperm Subpopulations in Infertile Males With Clinical Varicocele and Carriers of Rearranged Genomes

Some methods for determining sperm DNA fragmentation, such as the sperm chromatin structure assay (SCSA) and the sperm chromatin dispersion test (SCD), provide additional information about particular subgroups of spermatozoa with specific irregularities. Thus, SCSA recognizes a specific sperm subpopulation, the high-DNA stainability sperm subpopulation (HDS), and SCD recognizes the so-called DNA-degraded sperm (DDS) subpopulation. Although some studies associate the presence of these subpopulations with specific aspects related to infertility, the relationship between both sperm subpopulations and their preponderance in specific clinical groups of infertile males has not been extensively investigated. In this study, HDS and DDS subpopulations were determined in a total of 37 human males: 8 males with proven fertility, 9 infertile males with asthenoteratozoospermia, 10 carriers of chromosomal reorganizations, and 10 infertile males with clinical varicocele. Results showed a significant increase of the DDS subpopulation (P < .001) in both the varicocele patient (16.85 ± 7.24) and carrier of rearranged genome (11.6 ± 5.23) groups, but not in patients with asthenoteratozoospermia (3.88 ± 1.55) or fertile donors (2.62 ± 1.68). No statistical differences were detected for the HDS subpopulation (P = .542), but the highest values were found in the varicocele and rearranged-genome groups. However, no correlation between the HDS and DDS subpopulations were found (r = 0.196; P = .244), suggesting that both represent a different class of sperm subpopulation in the ejaculate. A significant increase in HDS, and especially DDS, can be associated with the presence of varicocele or the rearrangement of chromosomes. Specific diagnostic tests to confirm the diagnosis must be performed in patients with increased DDS and HDS values.