Exceptional complex chromosomal rearrangement and microdeletions at the 4q22.3q23 and 14q31.1q31.3 regions in a patient with azoospermia

In this report we describe the first patient ever found to have azoospermia in association with both exceptional complex chromosomal rearrangements and microdeletions at two translocation breakpoints. A 36-year-old male who had been suffering from male factor infertility was admitted to our clinic. The patient also displayed mild dysmorphia. An analysis of the patient's semen revealed azoospermia. GTG banding revealed the presence of an exceptional complex chromosomal rearrangement involving chromosomes 1, 4, 10 and 14. Using subtelomeric FISH analysis, the patient's karyotype was designated as 46,XY,t(1;10)(q43q44;q21q26.1)(CEB108/T7+,D1S3738-;10PTEL006+,D10S2290+, D1S3738+), ins(14;4) (q31.3;q23q33)(D14S1420+; D4S3359+, D4S2930+). Array-CGH analysis revealed two microdeletions at the 4q22.3q23 and 14q31.1q31.3 chromosomal regions. We suggest that microdeletions at the 4q22.3q23 and 14q31.1q31.3 chromosomal regions associated with both an exceptional complex chromosomal rearrangement and the Homo sapiens chromosome 4 open reading frame 37 (C4orf37) gene located at the 4q22.3q23 region might be associated with male factor infertility.     

Characterization of the first adult de novo case of 46,X,der(Y)t(X;Y)(p22.3;q11.2)

Herein, we describe a case of an infertile man detected in postnatal diagnosis with FISH characterization and array-CGH used for genome-wide screening which allowed the identification of a complex rearrangement involving sex chromosomes, apparently without severe phenotypic consequences. The deletion detected in our patient has been compared with previously reported cases leading us to propose a hypothetical diagnostic algorithm that would be useful in similar clinical situations, with imperative multi disciplinary approach integrated with genetic counseling. Our patient, uniquely of reproductive age, is one of six reported cases of duplication of Xp22.3 (~ 8.4 Mb) segment and contemporary deletion of Yq (~ 42.9 Mb) with final karyotype as follows:

46,X,der(Y),t(X;Y)(Ypter → Yq11.221::Xp22.33 → Xpter).ish der(Y) (Yptel+,Ycen+,RP11-529I21+,RP11-506M9-Yqtel −,Xptel +). arrXp22.33p22.31(702–8,395,963, 8,408,289x1), Yq11.221q12 (14,569,317x1, 14,587,321–57,440,839x0)     

Molecular Genetic Analysis of Y-Chromosome Microdeletions in Men with Severe Spermatogenetic Defects

Microdeletions of the Y-chromosomal AZF loci were revealed in 10 (12%) of 82 patients with severe idiopathic spermatogenetic defects. Deletions involved AZFc in six patients, AZFa in one patient, AZFb+c in two patients, and AZFa+b+c in one patient. Microdeletion analysis employed multiplex PCR with 22 pairs of primers directed to Y-specific STS of deletion intervals 5, 6, and 7 (Yq11). Spermatogenesis in men with AZF microdeletions was assessed with semen analysis, microscopic examination of testicular aspirate, and quantitative karyotypic analysis of immature germline cells in ejaculate or aspirate. The character of spermatogenetic defects was correlated with the size and location of microdeletions in order to study the genotype–phenotype relationship.     

Idiopathic cases of male infertility from a region in India show low incidence of Y-chromosome microdeletion

Chromosomal and Y-chromosomal microdeletion analysis has been done in cases of idiopathic infertility with the objective of evaluating the frequency of chromosomal and molecular anomaly as the causal factor of infertility. Barring a few cases of Klinefelter syndrome (XXY or XY/XXY mosaics), no chromosomal anomaly was encountered. Y-microdeletion was analysed by PCR-screening of STSs from different regions of the AZF (AZFa, AZFb, AZFc) on the long arm of the Y, as well as by using DNA probes of the genes RBM, DAZ (Yq), DAZLA (an autosomal homologue of DAZ) and SRY (Yp; sex determining gene). Out of 177 cases examined, 9 (azoospermia -8 and oligoasthenospermia -1) showed partial deletion of AZF. The size of deletion varied among patients but AZFc was either totally or partially removed in all of them. In contrast, no deletion was detected in AZFa. Testis biopsy done on a limited number of cases (50) showed diverse stages of spermatogenic arrest with no specific correlation with the genotype. The frequency of Y-chromosome microdeletion in our samples (∼ 5%) is much lower than the frequency (∼ 10%) reported globally and the two previous reports from India. We contend that the frequency may be affected by population structures in different geographical regions.     

Deletion of CDY1b copy of Y chromosome CDY1 gene is a risk factor of male infertility in Tunisian men

The relationship between male infertility and microdeletions in the Y chromosome that remove multiple genes varies among countries and populations. The aim of this study was to investigate the different types of Chromodomain protein, Y-linked 1 (CDY1) gene deletions and their effect on male infertility and spermatogenesis in Tunisian men. A total of 241 infertile men with different spermatogenic impairments and 115 fertile men were included in this study. We determined the prevalence of CDY1a and CDY1b copy deletions by PCR-RFLP using PvuII as restriction endonuclease. Results: Among the 356 Tunisian individuals, 93.25% had the two copies (CDY1a and CDY1b) of CDY gene (91.2% in infertile patients and 97.3% in fertile men). We also found that deletion of CDY1b was significantly more frequent in infertile patients (azoo/oligospermic and normospermic) than in fertile men (7% vs 1.7% respectively; p value = 0.02). However, deletion of CDY1a copy was very rare, and was detected in only one fertile man and four normospermic infertile patients. Our findings showed that deletion of CDY1b copy gene is a significant risk factor for male infertility independent of sperm concentration, whereas deletion of CDY1a gene seems to have no effect on fertility in the Tunisian population.     

Combined deletion of DAZ2 and DAZ4 copies of Y chromosome DAZ gene is associated with male infertility in Tunisian men

The relationship between male infertility and AZFc micro-deletions that remove multiple genes of the Y chromosome varies among countries and populations. The purpose of this study was to analyze the prevalence and the characteristics of different Deleted in azoospermia (DAZ) gene copy deletions and their association with spermatogenic failure and male infertility in Tunisian men. 241 infertile men (30.7% azoospermic (n = 74), 31.5% oligozoospermic (n = 76) and 37.7% normozoospermic (n = 91)) and 115 fertile healthy males who fathered at least one child were included in the study. Three DAZ-specific single nucleotide variant loci and six bi-allelic DAZ-SNVs (I–VI) were analyzed using polymerase chain reaction (PCR)–restriction fragment length polymorphism and PCR. Our findings showed high frequencies of infertile men (73.85%) and controls (78.26%) having only three DAZ gene copies (DAZ1/DAZ2/DAZ3 or DAZ1/DAZ3/DAZ4 variants); so deletion of DAZ2 or DAZ4 were frequent both in infertile (36.5% and 37.3%, respectively) and fertile groups (33.9% and 44.3%, respectively) and removing DAZ4 copy was significantly more frequent in oligospermic than in normospermic men (p = 0.04) in infertile group. We also report for the first time that simultaneous deletion of both DAZ2 and DAZ4 copies was significantly more common in infertile men (12.4%) than in fertile men (4.3%) (p = 0.01). However, deletions of DAZ1/DAZ2 and DAZ3/DAZ4 clusters were very rare. Analysis of DAZ gene copies in Tunisian population, suggested that the simultaneous deletion of DAZ2 and DAZ4 gene copies is associated with male infertility, and that oligospermia seems to be promoted by removing DAZ4 copy.     

Two Y chromosomes with duplication of the distal long arm including the entire AZFc region

Chromosome anomalies/rearrangements of the Y chromosome seldom threaten life and are quite common. The 4.5 Mb AZFc region on Yq11.2 is one of the most polymorphic regions in the human genome. AZFc partial deletion is almost inevitably associated with impaired fertility while the functional significance of AZFc partial duplications remains controversial. In this report, a large Y chromosome with one centromere and two heterochromatic blocks was identified incidentally in two men. The first case was ascertained through surveillance for recurrent miscarriage. The second case was ascertained through amniocytes of a fetus and his father. FISH and array-based comparative genomic hybridization showed duplications of the entire AZFc region as well as Yq euchromatic region. The duplications in Case 1 and Case 2 spanned 4.8 Mb and 6.2 Mb, respectively, of the Yq euchromatic region. These two cases suggest that complete AZFc duplication could be completely benign. It awaits further investigation whether this is a bona fide chromosomal polymorphism.     

Genome-wide screening of severe male factor infertile patients using BAC-array comparative genomic hybridization (CGH)

Male factor infertility is present in up to 50% of infertile couples, making it increasingly important in their treatment. Although most research into the genetics of male infertility has focused on the Y chromosome, male factor infertility may result from other genetic factors. We utilized the whole genome array comparative genomic hybridization (CGH) to identify novel genetic candidate associated with severely impaired spermatogenesis. We enrolled 37 patients with severe male factor infertility, defined as severe nonobstructive type oligozoospermia (≤5×10(6)/ml) or azoospermia, and 10 controls. Routine cytogenetic analyses, Yq microdeletion PCR test and whole genome bacterial artificial chromosome (BAC)-array CGH were performed. Array CGH results showed no specific gains or losses related to impaired spermatogenesis other than Yq microdeletions, and there were no novel candidate genetic abnormalities in the patients with severe male infertility. However, Yq microdeletions were detected in 10 patients. Three showed a deletion in the AZFb-c region and the other 7 had deletions in the AZFc region. Although we could not identify novel genetic regions specifically associated with male infertility, whole genome array CGH analysis with higher resolution including larger numbers of patients may be able to give an opportunity for identifying new genetic markers for male infertility.     

Mapping breakpoints of a familial chromosome insertion (18,7) (q22.1; q36.2q21.11) to DPP6 and CACNA2D1 genes in an azoospermic male

It is widely accepted that the incidence of chromosomal aberration is 10–15.2% in the azoospermic male; however, the exact genetic damages are currently unknown for more than 40% of azoospermia. To elucidate the causative gene defects, we used the next generation sequencing (NGS) to map the breakpoints of a chromosome insertion from an azoospermic male who carries a balanced, maternally inherited karyotype 46, XY, inv ins (18,7) (q22.1; q36.2q21.11). The analysis revealed that the breakage in chromosome 7 disrupts two genes, dipeptidyl aminopeptidase-like protein 6 (DPP6) and contactin-associated protein-like 2 (CACNA2D1), the former participates in regulation of voltage-gated potassium channels, and the latter is one of the components in voltage-gated calcium channels. The deletion and duplication were not identified equal or beyond 100 kb, but 4 homologous DNA elements were verified proximal to the breakpoints. One of the proband's sisters inherited the same aberrant karyotype and experienced recurrent miscarriages and consecutive fetus death, while in contrast, another sister with a normal karyotype experienced normal labor and gave birth to healthy babies. The insertional translocation is confirmed with FISH and the Y-chromosome microdeletions were excluded by genetic testing. This is the first report describing chromosome insertion inv ins (18,7) and attributes DPP6 and CACNA2D1 to azoospermia.     

Pyruvate dehydrogenase complex: mRNA and protein expression patterns of E1α subunit genes in human spermatogenesis

During spermatogenesis, germ cells undergo a complex process of cell differentiation and morphological restructuring, which depends on the coordinated expression of different genes. Some vital examples are those involved in cell energy metabolism, namely the genes encoding the E1α subunit of pyruvate dehydrogenase complex: the somatic PDHA1 (X-linked) and the testis-specific PDHA2 (autosomal). There are no data related to the study at the RNA and protein levels of PDHA genes during human spermatogenesis. The present study aimed to describe the mRNA and protein expression patterns of the human PDHA genes during spermatogenesis. Expression profiles of the PDHA1 and PDHA2 genes were characterized using different human tissues and cells. Diploid and haploid germ cells fractions were obtained from testis tissues. The mRNA profiles were analyzed by quantitative RT-PCR, whereas the protein profiles were evaluated by immunohistochemistry, western blotting and two-dimensional electrophoresis. Expression of the PDHA1 gene was found in all somatic cells, whereas expression of PDHA2 gene was restricted to germ cells. The switch from X-linked to autosomic gene expression occurred in spermatocytes. Data suggest the activation of PDHA2 gene expression is most probably a mechanism to ensure the continued expression of the protein, thus allowing germ cell viability and functionality.