Adult ; Animals ; Female ; Frameshift Mutation/genetics* ; Genes, sry ; Gonadal Dysgenesis, 46,XY/genetics* ; Humans ; Menarche ; Ovary/pathology* ; Oviducts/pathology* ; Sex-Determining Region Y Protein/genetics*

OBJECTIVE: To explore the pathogenesis of a 46,XY female with sex reversal. METHODS: Peripheral blood lymphocytes of the patient were subjected to G-banding karyotype analysis. Sex chromosomes were analyzed with fluorescence in situ hybridization (FISH). SRY gene was analyzed by Sanger sequencing. The whole exome of the patient was subjected to next generation sequencing. Copy number variations (CNVs) of the NR0B1, SF1, SRY, SOX9 and WNT4 genes were validated by multiplex ligation-dependent probe amplification (MLPA). RESULTS: The patient had a 46,XY karyotype. FISH analysis showed that her sex chromosomes were X and Y. No mutation was found in the SRY gene, and no pathogenic mutation was detected in her exome. However, a duplication spanning approximately 67.31 kb encompassing the MAGEB1, MAGEB3, MAGEB4 and NR0B1 genes at Xp21, was predicted by software analysis. MLPA confirmed duplication of the NR0B1 gene in the patient and her mother. CONCLUSION A duplication fragment of Xp21 encompassing the NR0B1 gene in the 46,XY female with sex reversal is transmitted from her asymptomatic carrier mother. Attention should be paid towards the insidious nature and high morbidity of this duplication.
DAX-1 Orphan Nuclear Receptor ; genetics ; DNA Copy Number Variations ; Female ; Gene Duplication ; Genes, sry ; Gonadal Dysgenesis, 46,XY ; genetics ; Humans ; In Situ Hybridization, Fluorescence

OBJECTIVETo explore the genetic cause of a female case with intellectual development disorder.

METHODSG banding karyotyping was performed for the patient. Following DNA extraction, the coding sequence of SRY gene was amplified with PCR and subjected to Sanger sequencing. qPCR was used to detect the copy numbers of the SRY gene.

RESULTSThe karyotype of the patient was 47,XXY. PCR and qPCR analyses of the SRY gene showed a large deletion with null copy number.

CONCLUSIONThe female phenotype of the patient is probably due to deletion of the SRY gene on the Y chromosome. This is the first report of 47,XXY female case with deletion of the SRY gene in China.

Base Sequence ; Chromosome Banding ; Chromosomes, Human, Y ; genetics ; Female ; Genes, sry ; genetics ; Humans ; Intellectual Disability ; genetics ; Karyotype ; Karyotyping ; Klinefelter Syndrome ; genetics ; Male ; Polymerase Chain Reaction ; Review Literature as Topic ; Sequence Analysis, DNA ; methods ; Sequence Deletion ; Sequence Homology, Nucleic Acid

We report the prenatal diagnosis of an unbalanced translocation between chromosome Y and chromosome 15 in a female fetus. Cytogenetic analysis of parental chromosomes revealed that the mother had a normal 46,XX karyotype, whereas the father exhibited a 46,XY,der(15)t(Y;15) karyotype. We performed cytogenetic analysis of the father's family as a result of the father and confirmed the same karyotype in his mother and brother. Fluorescence in situ hybridization and quantitative fluorescent-polymerase chain reaction analysis identified the breakpoint and demonstrated the absence of the SRY gene in female members. Thus, the proband inherited this translocation from the father and grandmother. This makes the prediction of the fetal phenotype possible through assessing the grandmother. Therefore, we suggest that conventional cytogenetic and molecular cytogenetic methods, in combination with family history, provide informative results for prenatal diagnosis and prenatal genetic counseling.
Chromosomes, Human, Pair 15* ; Cytogenetic Analysis ; Cytogenetics ; Fathers ; Female* ; Fetus* ; Fluorescence ; Genes, sry ; Genetic Counseling ; Grandparents ; Humans ; In Situ Hybridization ; Karyotype ; Mothers ; Parents ; Phenotype ; Prenatal Diagnosis* ; Sex Chromosome Aberrations ; Siblings

PURPOSE: To identify the clinical characteristics of SRY-negative male patients and genes related to male sex reversal, we performed a retrospective study using cases of 46,XX testicular disorders of sex development with a review of the literature. MATERIALS AND METHODS: SRY-negative cases of 46,XX testicular disorders of sex development referred for cytogenetic analysis from 1983 to 2013 were examined using clinical findings, seminal analyses, basal hormone profiles, conventional cytogenetic analysis and polymerase chain reaction. RESULTS: Chromosome analysis of cultured peripheral blood cells of 8,386 individuals found 19 cases (0.23%) with 46,XX testicular disorders of sex development. The SRY gene was confirmed to be absent in three of these 19 cases (15.8%). CONCLUSION: We report three rare cases of SRY-negative 46,XX testicular disorders of sex development. Genes on autosomes and the X chromosome that may have a role in sex determination were deduced through a literature review. These genes, through differences in gene dosage variation, may have a role in sex reversal in the absence of SRY.
Azoospermia ; Blood Cells ; Cytogenetic Analysis ; Disorders of Sex Development ; Gene Dosage ; Genes, sry ; Humans ; Infertility ; Male ; Polymerase Chain Reaction ; Retrospective Studies ; Sexual Development* ; X Chromosome

OBJECTIVETo investigate the clinical and genetic characteristics of a patient with mixed gonadal dysgenesis.

METHODSClinical data was collected. The patient was subjected for serum hormone testing and G-banding chromosomal analysis. Sex-determining region of Y-chromosome (SRY) gene and azoospermia factor (AZF) a, b, c regions were analyzed with multiple polymerase chain reaction (PCR) and whole gene sequencing.

RESULTSAll serum hormone testing were normal. The karyotype of the patient was 45,X/46,X,Yqh-. PCR has proven the presence of SRY, ZFY and AZFa, and deletion of AZFb and AZFc regions. No mutation was detected in the sequence of the SRY gene. Abdominal computerized tomography has detected a huge mass in the pelvic cavity, which was positive for PLAP and CD117 on immunohistochemistry stain.

CONCLUSIONBased on clinical data and result of genetic testing, the patient was diagnosed with mixed gonadal dysgenesis. Pathological and immunohistochemistry analysis of the transformed gland has confirmed the diagnosis of seminoma. For patient with a karyotype of 45,X/46,X,Yqh-, the risk of seminoma may be related with the presence of SRY gene.

Chromosome Banding ; Chromosomes, Human, Y ; genetics ; Female ; Genes, sry ; Gonadal Dysgenesis, Mixed ; diagnosis ; genetics ; Humans ; Male ; Middle Aged ; Sex Determination Analysis

PURPOSE: Conventional methods for the prenatal detection of fetal RhD status involve invasive procedures such as fetal blood sampling and amniocentesis. The identification of cell-free fetal DNA (cffDNA) in maternal plasma creates the possibility of determining fetal RhD status by analyzing maternal plasma DNA. However, some technical problems still exist, especially the lack of a positive control marker for the presence of fetal DNA. Therefore, we assessed the feasibility and accuracy of fetal RHD genotyping incorporating the RASSF1A epigenetic fetal DNA marker from cffDNA in the maternal plasma of RhD-negative pregnant women in Korea. MATERIALS AND METHODS: We analyzed maternal plasma from 41 pregnant women identified as RhD-negative by serological testing. Multiplex real-time PCR was performed by amplifying RHD exons 5 and 7 and the SRY gene, with RASSF1A being used as a gender-independent fetal epigenetic marker. The results were compared with those obtained by postnatal serological analysis of cord blood and gender identification. RESULTS: Among the 41 fetuses, 37 were RhD-positive and 4 were RhD-negative according to the serological analysis of cord blood. There was 100% concordance between fetal RHD genotyping and serological cord blood results. Detection of the RASSF1A gene verified the presence of cffDNA, and the fetal SRY status was correctly detected in all 41 cases. CONCLUSION: Noninvasive fetal RHD genotyping with cffDNA incorporating RASSF1A is a feasible, reliable, and accurate method of determining fetal RhD status. It is an alternative to amniocentesis for the management of RhD-negative women and reduces the need for unnecessary RhIG prophylaxis.
Amniocentesis ; DNA* ; Epigenomics ; Exons ; Female ; Fetal Blood ; Fetus ; Genes, sry ; Genetic Markers ; Humans ; Korea* ; Plasma ; Pregnant Women* ; Prenatal Diagnosis ; Real-Time Polymerase Chain Reaction ; Serologic Tests

Turner syndrome is the most common chromosomal disorder in girls. Various phenotypic features show depending upon karyotype from normal female through ambiguous genitalia to male. Usually, Turner girls containing 45,X/46,XY mosaicism, or sex-determining region Y (SRY) gene may have mixed gonadal dysgenesis with various external sexual differentiation. We experienced a short statured 45,X Turner girl with normal external genitalia. Because SRY gene was positive, laparoscopic gonadectomy was performed. The dysgenetic gonads revealed bilateral ovotesticular tissues. The authors report a mixed gonadal dysgenesis case found in clinical 45,X Turner patient with positive SRY gene. Screening for SRY gene should be done even the karyotype is 45,X monosomy and external genitalia is normal.
Chromosome Disorders ; Disorders of Sex Development ; Female ; Genes, sry* ; Genitalia ; Gonadal Dysgenesis, Mixed* ; Gonads ; Humans ; Karyotype ; Male ; Mass Screening ; Monosomy ; Mosaicism ; Sex Differentiation ; Turner Syndrome*

The 46,XX testicular disorder of sex development (DSD), also known as 46,XX male syndrome, is a rare form of DSD and clinical phenotype shows complete sex reversal from female to male. The sex-determining region Y (SRY) gene can be identified in most 46,XX testicular DSD patients; however, approximately 20% of patients with 46,XX testicular DSD are SRY-negative. The SRY-box 9 (SOX9) gene has several important functions during testis development and differentiation in males, and overexpression of SOX9 leads to the male development of 46,XX gonads in the absence of SRY. In addition, SOX9 duplication has been found to be a rare cause of 46,XX testicular DSD in humans. Here, we report a 4.2-year-old SRY-negative 46,XX boy with complete sex reversal caused by SOX9 duplication for the first time in Korea. He showed normal external and internal male genitalia except for small testes. Fluorescence in situ hybridization and polymerase chain reaction (PCR) analyses failed to detect the presence of SRY, and SOX9 intragenic mutation was not identified by direct sequencing analysis. Therefore, we performed real-time PCR analyses with specific primer pairs, and duplication of the SOX9 gene was revealed. Although SRY-negative 46,XX testicular DSD is a rare condition, an effort to make an accurate diagnosis is important for the provision of proper genetic counseling and for guiding patients in their long-term management.
46, XX Testicular Disorders of Sex Development ; Diagnosis ; Disorders of Sex Development ; Female ; Fluorescence ; Genes, sry ; Genetic Counseling ; Genitalia, Male ; Gonads ; Humans ; In Situ Hybridization ; Korea ; Male ; Phenotype ; Polymerase Chain Reaction ; Real-Time Polymerase Chain Reaction ; Sexual Development* ; Testis

Sex typing may become the start point in investigations that are usually performed through amelogenin typing. In cases involving genotype-phenotype discrepancy, amelogenin typing could yield misleading results. The rare XX male syndrome is characterized by a phenotypic male with a 46, XX female karyotype. In this point, this case report would help understand the importance of genotype-phenotype discrepancy.
Amelogenin ; Female ; Genes, sry ; Humans ; Karyotype ; Klinefelter Syndrome ; Male ; Y Chromosome