Gene expression patterns in relation to the clinical phenotype in Klinefelter syndrome.

CONTEXT: Klinefelter syndrome (KS) is the most common chromosome disorder in men (47,XXY), exhibiting a phenotype with marked variation and increased morbidity. The pathophysiological link between the supernumerary X chromosome and the clinical phenotype remains unknown. OBJECTIVE: To elucidate whether differential gene expression patterns can be detected in KS patients and whether these are related to inherent clinical features. DESIGN, SETTING, PARTICIPANTS: EXAKT (Epigenetics, X-chromosomal Features and Clinical Applications in Klinefelter Syndrome Trial) is a Münster-based prospective project involving 132 Klinefelter men and their parents. A range of cardiovascular, inflammatory, and metabolic factors, in comparison to age-matched male (n = 50)/female controls (n = 50) and in relation to genetic features, is assessed. MAIN OUTCOMES AND MEASURES: Our predefined hypothesis was that differential gene expression patterns in blood cells exist in KS patients vs male controls and are related to the clinical phenotype. RESULTS: Differential expression of 36 X-chromosomal and autosomal genes put KS patients into a unique genetic setting vs male and female controls. The KS cohort exhibited increased insulin resistance, enhanced inflammatory and procoagulatory status, higher waist circumference, dyslipidemia, and a markedly shorter 12-lead electrocardiogram QTc interval (partly located within the pathological range) vs male controls (all P < .001). Clinical dyshomeostasis was associated with expression patterns of dysregulated genes (all P < .01). Parental origin of the supernumerary X chromosome was a confounder regarding insulin resistance and cardiac phenotype (P < .05). Results are considered preliminary because gene expression was measured in blood cells. CONCLUSIONS: The supernumerary X chromosome contributes to a number of pathologies in KS. The pattern of gene expression is altered in KS, and the degree of differential gene expression is associated with the clinical phenotype.

New approaches to the Klinefelter syndrome.

The Klinefelter syndrome (KS), with an incidence of 1 to 2 per 1000 male neonates, is one of the most frequent congenital chromosome disorders. The 47,XXY karyotype causes infertility, testosterone deficiency and a spectrum of further symptoms and comorbidities. In recent years, significant progress has been made in the elucidation of the pathophysiology and the treatment of the KS. It became clear that, to a large extent, the clinical picture is determined by gene dosage effects of the supernumerary X-chromosome. The origin of the extra X-chromosome from either the father or the mother influences behavioural features of patients with KS. The CAGn polymorphism of the androgen receptor, located on the X-chromosome, has a distinct impact on the KS phenotype. KS predisposes to the metabolic syndrome and its cardiovascular sequelae, contributing to the increased mortality of patients with KS. Neuroimaging studies have correlated anomalies in brain structures with psychosocial problems. The unexpected possibility to produce pregnancies and live birth with either ejaculated sperm--about 8% of KS men have a few sperm in semen--or with sperm extracted from individual tubules obtained by testicular biopsy can be considered a breakthrough. Testosterone substitution requires further optimisation in terms of when to initiate therapy and which preparations and dosages to use. Recently developed animal models help to further elucidation the genetic and pathophysiological basis and may lead to new therapeutic approaches to KS.

Germ cell loss is associated with fading Lin28a expression in a mouse model for Klinefelter's syndrome.

Klinefelter's syndrome is a male sex-chromosomal disorder (47,XXY), causing hypogonadism, cognitive and metabolic deficits. The majority of patients are infertile due to complete germ cell loss after puberty. As the depletion occurs during development, the possibilities to study the underlying causes in humans are limited. In this study, we used the 41,XX(Y*) mouse model to characterise the germ line postnatally. We examined marker expression of testicular cells focusing on the spermatogonial stem cells (SSCs) and found that the number of germ cells was approximately reduced fivefold at day 1pp in the 41,XX(Y*) mice, indicating the loss to start prenatally. Concurrently, immunohistochemical SSC markers LIN28A and PGP9.5 also showed decreased expression on day 1pp in the 41,XX(Y*) mice (48.5 and 38.9% of all germ cells were positive), which dropped to 7.8 and 7.3% on 3dpp, and were no longer detectable on days 5 and 10pp respectively. The differences in PCNA-positive proliferating cells in XY* and XX(Y*) mice dramatically increased towards day 10pp. The mRNA expression of the germ cell markers Lin28a (Lin28), Pou5f1 (Oct4), Utf1, Ddx4 (Vasa), Dazl, and Fapb1 (Sycp3) was reduced and the Lin28a regulating miRNAs were deregulated in the 41,XX(Y*) mice. We suggest a model for the course of germ cell loss starting during the intrauterine period. Neonatally, SSC marker expression by the already lowered number of spermatogonia is reduced and continues fading during the first postnatal week, indicating the surviving cells of the SSC population to be disturbed in their stem cell characteristics. Subsequently, the entire germ line is then generally lost when entering meiosis.

Expression of selected genes escaping from X inactivation in the 41, XX(Y)* mouse model for Klinefelter's syndrome.

AIM: We hypothesized that patients with Klinefelter's syndrome (KS) not only undergo X inactivation, but also that genes escape from inactivation. Their transcripts would constitute a significant difference, as male metabolism is not adapted to a 'female-like' gene dosage. We evaluated the expression of selected X-linked genes in our 41, XX(Y)* male mice to determine whether these genes escape inactivation and whether tissue-specific differences occur. METHODS: Correct X inactivation was identified by Xist expression. Relative expression of X-linked genes was examined in liver, kidney and brain tissue by real-time PCR in adult XX(Y)* and XY* males and XX females. RESULTS: Expression of genes known to escape X inactivation was analysed. Relative mRNA levels of Pgk1 (control, X inactivated), and the genes Eif2s3x, Kdm5c, Ddx3x and Kdm6a escaping from X inactivation were quantified from liver, kidney and brain. Pgk1 mRNA expression showed no difference, confirming correct X inactivation. In kidney and liver, XX(Y)* males resembled the female expression pattern in all four candidate genes and were distinguishable from XY* males. Contrastingly, in brain tissue XX(Y)* males expressed all four genes higher than male and female controls. CONCLUSION: Altered expression of genes escaping X inactivation probably contributes directly to the XX(Y)* phenotype.

Male 41, XXY* mice as a model for klinefelter syndrome: hyperactivation of leydig cells.

Sex chromosome imbalance in males is linked to a supernumerary X chromosome, a condition resulting in Klinefelter syndrome (KS; 47, XXY). KS patients suffer from infertility, hypergonadotropic hypogonadism, and cognitive impairments. Mechanisms of KS pathophysiology are poorly understood and require further exploration using animal models. Therefore, we phenotypically characterized 41, XX(Y)* mice of different ages, evaluated observed germ cell loss, studied X-inactivation, and focused on the previously postulated impaired Leydig cell maturation and function as a possible cause of the underandrogenization seen in KS. Xist methylation analysis revealed normal X-chromosome inactivation similar to that seen in females. Germ cell loss was found to be complete and to occur during the peripubertal phase. Significantly elevated FSH and LH levels were persistent in 41, XX(Y)* mice of different ages. Although Leydig cell hyperplasia was prominent, isolated XX(Y)* Leydig cells showed a mature mRNA expression profile and a significantly higher transcriptional activity compared with controls. Stimulation of XX(Y)* Leydig cells in vitro by human chorionic gonadotropin indicated a mature LH receptor whose maximal response exceeded that of control Leydig cells. The hyperactivity of Leydig cells seen in XX(Y)* mice suggests that the changes in the endocrine milieu observed in KS is not due to impaired Leydig cell function. We suggest that the embedding of Leydig cells into the changed testicular environment in 41 XX(Y)* males as such influences their endocrine function.