54 research outputs found
Is there any clinical relevant difference between non mosaic Klinefelter Syndrome patients with or without Androgen Receptor variations?
Klinefelter Syndrome (KS) is the most common chromosomal disorder in men leading to non-obstructive azoospermia. Spermatozoa can be found by TESE in about 50% of adults with KS despite severe testicular degeneration. We evaluated AR variations and polymorphism length in 135 non-mosaic KS patients, aimed to find possible correlation with clinical features, sex hormones and sperm retrieval. Among 135 KS patients we found AR variations in eight subjects (5.9%). All variations but one caused a single amino acid substitution. Four variations P392S, Q58L, L548F, A475V found in six patients had been previously described to be associated with different degrees of androgen insensitivity. Moreover we observed in two patients Y359F and D732D novel variations representing respectively a missense variation and a synonymous variation not leading to amino acid substitution. All the Klinefelter patients with AR gene variations were azoospermic. Spermatozoa were retrieved with TESE for two men (40%), sperm retrieval was unsuccessful in other 3 patients. This is the only study reporting AR variations in KS patients. Relevant clinical differences not emerged between AR mutated and not AR mutated KS patients, but does each variation play an important role in the trasmission to the offspring obtained by ART in this patients
FRAXA and FRAXE: New Tools for the Diagnosis of Mental Retardation
In the era of prevention and early diagnosis, mental retardation (MR) represents one of the most important challenges to modern medicine. Much needs to be done to restrict the number of different forms of this vast category of chronic handicaps for which accurate diagnoses are not yet available. The goal is to reduce the social burden and provide better care for patients and families.The identification and characterisation of the molecular mechanisms which silence the FMR1 gene and which are responsible, in the majority of cases, for the fragile X syndrome (FRAXA) [1-4], the leading known cause of inherited mental retardation, led to the discovery of an extremely important new class of mutations: “dynamic mutations”. These are highly unstable interspersed repeats, located close to or within genes, which show a strong tendency to expand. This discovery has raised the possibility for direct molecular diagnosis of FRAXA and several other diseases based on the same molecular mechanism, including a different form of MR associated with a fragile site in Xq28, named FRAXE [5].With these tools, we have started to study the structural characteristics and pattern of transmission of these mutations in a population of mentally retarded individuals mainly coming from north-eastern Italy. The aims of our study were (a) to establish the true incidence of FRAXA and FRAXE full mutations as a cause of mental retardation in our population, and (b) to re-evaluate families in which at least one individual had a cytogenetic fra(X) diagnosis, in order to identify mosaicisms and premutations that could not be identified cytogenetically, and to establish the carrier status of relatives of affected individuals.</jats:p
Molecular diagnosis of inherited diseases
The importance of the interaction between basic science and clinical practice has long been known but it has become even more evident in the past few decades with the impressive rate of development in the field of molecular genetics. This short article reviews molecular diagnosis of two different diseases for which scientific progress has immediately been translated into a dramatic improvement of the quality of medical care: the Fragile X Syndrome, paradigm of the new mutational mechanism of the unstable triplet repeats, and von Hippel-Lindau disease, a recent acquisition in the growing number of familial cancer syndromes
Male infertility and androgen receptor gene mutations: clinical features and identification of seven novel mutations
OBJECTIVE:
Androgens and a functioning androgen receptor (AR) are essential for development and maintenance of the male phenotype and spermatogenesis. Consistent with this, mutations in the AR gene cause a variety of defects related to androgen insensitivity, ranging from complete feminization to phenotypic males with infertility. The aim of his study was to analyse the prevalence of AR gene mutations in male infertility and to clarify the genotype-phenotype relation.
DESIGN:
Males with infertility were recruited consecutively at the Centre for Male Gamete Cryopreservation at the University of Padova from January 1996 to January 2005.
PATIENTS:
One thousand five hundred and seventeen men with < 10 million sperm/ml and 310 age-matched normozoospermic controls.
METHODS:
Screening for AR gene mutation was done by DHPLC and sequencing, and reproductive hormone concentrations were measured.
RESULTS:
We found 20 mutations in 26 of 1517 patients (1.7%) and no mutations in controls. A high number of mutations localized in exon 1 of the AR gene coding for the transactivation domain of the protein. Of 20 mutations, 7 represent novel mutations. With respect to men without AR mutations, subjects with AR mutations have lower ejaculate volume, higher testosterone levels, higher oestradiol levels, and higher androgen sensitivity index. However, the ranges for these variables were highly overlapping between men with and without AR gene mutations. Also clinical manifestations of AR mutations are not unique and 22 men had only spermatogenic impairment.
CONCLUSIONS:
AR gene mutations are quite frequent in unselected infertile men but no specific hormonal or clinical data could be used to preselect patients at risk of mutations
Osteoporosis in Klinefelter's syndrome
Hypogonadism represents one of the most important causes of male osteoporosis. Testosterone regulates male bone metabolism both indirectly by aromatization to estrogens and directly through the androgen receptor (AR) on osteoblasts, promoting periosteal bone formation during puberty and reducing bone resorption during adult life. Early onset of testosterone deficiency, as observed in Klinefelter's syndrome (KS), is an important risk factor for precocious osteoporosis. Osteoporosis is present in up to 40% of subjects with KS and has usually been attributed to low testosterone levels. However, reduced bone mass might be present also in KS men with normal testosterone levels and testosterone replacement therapy does not always restore bone density in KS patients. Possible new determinants for osteoporosis in KS might be related to the AR function and insulin-like factor 3 (INSL3) levels. The CAG length and inactivation pattern of the AR in KS have been related to osteoporosis, but definitive proof is lacking. INSL3 has an anabolic role on bone metabolism by acting on osteoblasts and INSL3 levels are low in KS. Therefore, low INSL3 concentrations might represent a possible new pathogenic mechanism for reduced bone mass in KS
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