45,X karyotype in an infertile man: how is this possible?

The case was male, 32 years old, with a nonobstructive azoospermia diagnosis and an initial 45,X karyotype. We evaluated by classical cytogenetic methods, C and NOR banding, fluorescent in situ hybridization, and polymerase chain reaction investigations. After investigation, we found the following karyotype: 45,X,dic(Y;22)(q11.223;p11.2). This investigation contributes to our understanding of how chromosome rearrangements can influence fertility processes and how important it is to perform a cytogenetic analysis in infertility cases.

First study of microdeletions in the Y chromosome of Algerian infertile men with idiopathic oligo- or azoospermia.

The human Y chromosome is essential for human sex determination and spermatogenesis. The long arm contains the azoospermia factor (AZF) region. Microdeletions in this region are responsible for male infertility. The objective of this study was to determine the frequency of Y microdeletions in Algerian infertile males with azoospermia and oligoasthenoteratozoospermia syndrome (OATS) and to compare the prevalence of these abnormalities with other countries and regions worldwide. A sample of 80 Algerian infertile males with a low sperm count (1-20 × 10(6) sperms/ml) as well as 20 fertile male controls was screened for Y chromosome microdeletions. 49 men were azoospermic and 31 men had OATS. Genomic DNA was isolated from blood and polymerase chain reaction was carried out with a set of 6 AZFa, AZFb and AZFc STS markers to detect the microdeletions as recommended by the European Academy of Andrology. Among the 80 infertile men screened for microdeletion, 1 subject was found to have microdeletions in the AZFc (sY254 and sY255) region. The deletion was found in azoospermic subjects (1/49, 2%). The overall AZF deletion frequency was low (1/80, 1.3%). AZF microdeletions were observed neither in the OATS group nor in the control group. The frequency of AZF microdeletions in infertile men from Algeria was comparable to those reported in the literature. We suggest analyzing 6 STS in the first step to detect Y microdeletions in our population.

Clinical implications of the detection of Y-chromosome mosaicism in Turner's syndrome: report of 3 cases.

OBJECTIVE: To determine the clinical implications of the presence of a Y chromosome in Turner's syndrome patients with karyotype abnormalities. DESIGN: To investigate the presence of Y-chromosome sequences in different tissue samples. SETTING: Endocrinology outpatient clinic of a federal university in Brazil. PATIENT(S): Five Turner's syndrome patients with karyotype abnormalities such as marker chromosomes, additional material, or ring chromosomes. INTERVENTION(S): Peripheral blood, oral epithelial cells, and hair root samples were collected. MAIN OUTCOME MEASURE(S): The SRY gene and the DYZ3 repeat region were amplified by polymerase chain reaction followed by gel electrophoresis mobility of amplified genomic DNA, and ultraviolet visualization. Prophylactic gonadectomy was offered to the Y-positive patients. RESULT(S): The analysis of the different tissues revealed that three of the five patients studied presented Y-chromosome mosaicism. These three patients underwent prophylactic gonadectomy, and in one of them, the histopathologic study of the gonads disclosed hilus cell hyperplasia and stromal luteoma with contralateral nodular hyperthecosis. CONCLUSION(S): A systematic search for Y-chromosome mosaicism in Turner's syndrome patients is justified by the risk of developing gonadal tumors or androgen-producing lesions.

PGD gender selection for non-Mendelian disorders with unequal sex incidence.

Preimplantation genetic diagnosis (PGD) was originally developed for couples whose potential offspring were at risk of severe Mendelian disorders, but has since been extended to other indications. One possible use of PGD is to perform gender selection for couples whose offspring are at increased risk of disorders that do not follow Mendelian inheritance, but which are substantially more common in one sex than another (unequal sex incidence). Here, we examine the clinical and ethical issues to be considered prior to offering PGD gender selection to reduce the risk of a child being affected by a non-Mendelian condition with unequal sex incidence. Factors to be considered include: the risk that a child of either sex will be affected by the condition; the overall reduction in risk provided by gender selection and the potential harms of the procedure. Consideration should also be given to the interests of the family and the child to be born, the seriousness of the condition and the couple's procreative autonomy. To illustrate these issues we use the example of autism, a non-Mendelian disorder that is considerably more common in males than in females.

Discrepancies in the laws on identifying foetal sex and terminating a pregnancy in India.

Laws that regulate the identification of a foetus and the termination of a pregnancy in India are shaped by their social context. The Medical Termination of Pregnancy Act, 1971, discriminates against unmarried women by not recognising that unwanted pregnancies in unmarried women could result in at least as much anguish and suffering as that experienced by married women. While the MTP Act permits the abortion of foetuses with disabilities, the Pre-conception and Pre-natal Diagnostic Techniques (Prohibition of Sex Selection) Act's ban on identifying the foetus's sex prevents the use of sex-detection to identify foetuses at high risk of sex-linked diseases.