Balanced complex chromosome rearrangement in male infertility: case report and literature review.

Complex chromosome rearrangements (CCRs) are structural rearrangements involving at least three chromosomes and three or more chromosome breakpoints. Generally, balanced CCR carriers have a normal phenotype but they are at a higher reproductive risk. Azoospermia was discovered in the male partner of a couple with primary infertility. Conventional cytogenetics identified a CCR refined by fluorescent in situ hybridisation. The CCR involved three chromosomes, four breakpoints and an insertion. A literature search identified 43 phenotypically normal males referred for reproductive problems presenting a CCR. More males were ascertained because of spermatogenesis failure or disturbances than because of repeated abortions and/or birth of a malformed child. Male carriers of CCR produce a high frequency of chromosomally abnormal spermatozoa due to the aberrant segregation of the rearranged chromosomes. The number of chromosomes and breakpoints involved in the rearrangement, the position of breakpoints, the relative size of the resultant chromosomes and the presence or absence of recombination inside the paired-rearranged segments are presumed to affect the fertility of the carrier. Testicular biopsy should not be performed in males with azoospermia. Intracytoplasmic sperm injection should not be proposed as a procedure for treating the infertility of CCR male carriers as a successful result is unlikely.

Aneuploidy and DNA fragmentation in sperm of carriers of a constitutional chromosomal abnormality.

Among various causes responsible for infertility, it has been admitted for a long time that male infertility can be due to impaired spermatogenesis and/or balanced structural chromosomal abnormalities. Sperm DNA fragmentation is also considered as another cause of infertility. Most of the studies on male infertility have concerned either aneuploidy in the sperm of carriers of constitutional chromosomal abnormalities or sperm DNA fragmentation. This review is aimed at analyzing these 2 parameters in the same patients. Furthermore, we present work on the study of these 2 parameters in the same gametes of 4 carriers of a balanced chromosomal abnormality. Meiotic segregation was analyzed by fluorescent in situ hybridization and DNA fragmentation was detected by terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling assay. It was shown that aneuploidy and DNA fragmentation were increased in the sperm of carriers of a balanced chromosomal abnormality. For all 4 carriers of a balanced structural abnormality, there was a 2-5 times higher proportion of spermatozoa with unbalanced chromosomal content and fragmented DNA than among those with normal/balanced content. Moreover, we found a non-random distribution with more gametes with DNA fragmentation when these arose from a particular segregation mode. The mechanism which would tend to explain our results is abortive apoptosis. In conclusion, both meiotic segregation and DNA fragmentation studies should be integrated in the genetic exploration of male carriers of a chromosomal structural abnormality.

Fluorescence in situ hybridization characterization of ider(20q) in myelodysplastic syndrome.

Isochromosome of the long arm of chromosome 20 with loss of interstitial material [ider(20q)] is a variant of deletion of chromosome 20q and a rare abnormality in myelodysplastic syndrome (MDS). We studied seven cases with an ider(20q) in MDS. Fluorescence in situ hybridization (FISH) studies showed all proximal breakpoints to be consistently located in 20q11.21 band whereas distal breakpoints were variable. Amplification of HCK, TNFRSF6B and DIDO1 genes included in retained regions associated with loss of tumour suppressor genes in deleted regions could explain cell tumour progression and possibly the less favourable prognosis of ider(20q) compared with del(20q).

[Strategies to identify supernumerary chromosomal markers in constitutional cytogenetics]. / Stratégies d'identification des marqueurs chromosomiques surnuméraires en cytogénétique constitutionnelle.

Supernumerary marker chromosomes (SMCs) are defined as extrastructurally abnormal chromosomes which origin and composition cannot be determined by conventional cytogenetics. SMCs are an heterogeneous group of abnormalities concerning all chromosomes with variable structure and size and are associated with phenotypic heterogeneity. The characterisation of SMCs is of utmost importance for genetic counselling. Different molecular techniques are used to identify chromosomal material present in markers such as 24-colour FISH (MFISH, SKY), centromere specific multicolour FISH (cenMFISH) and derivatives (acroMFISH, subcenMFISH), comparative genomic hybridisation (CGH), arrayCGH, and targeted FISH techniques (banding techniques, whole chromosome painting...). Based on the morphology of SMC with conventional cytogenetic and clinical data, we tried to set up different molecular strategies with all available techniques.