OBJECTIVE: To explore the prevalence and clinical manifestations of ring chromosomes among children featuring abnormal development. METHODS: From January 2015 to August 2021, 7574 children referred for abnormal development were selected, and their peripheral blood samples were subjected to G-banded chromosomal karyotyping analysis. RESULTS: Twelve cases of ring chromosomes were detected, which have yielded a prevalence of 0.16% and included 1 r(6), 2 r(9), 1 r(13), 1 r(14), 2 r(15), 1 r(21) and 3 r(X). The children had various clinical manifestations including growth and mental retardation, limb malformation, and congenital heart disease. For two children with r(9) and two with r(15) with similar breakpoints, one child with r(9) and one with r(15) only had growth retardation, whilst another with r(9) and another with r(15) also had peculiar facies and complex congenital heart disease. The r(X) has featured some manifestations of Turner syndrome. CONCLUSION Ring chromosomes are among the common causes for severe growth and mental retardation in children with diverse clinical phenotypes. Clinicians should pay attention to those with developmental anomalies and use chromosomal analysis to elucidate their genetic etiology.
Humans ; Ring Chromosomes ; Intellectual Disability/genetics* ; Turner Syndrome/genetics* ; Phenotype ; Heart Defects, Congenital/genetics*

OBJECTIVE: To explore the clinical features and genetic diagnosis of two cases with rare diseases and X chromosome abnormalities. METHODS: Multiple ligation-dependent probe amplification (MLPA) and karyotype analysis were carried out on an 8-year-old girl who was diagnosed with Duchenne muscular dystrophy. Karyotype analysis and PCR assay for SRY and AZF genes were carried out for a-2-month-old male infant with short penis. RESULTS: The girl, who featured short stature and cubitus valgus, was diagnosed as Turner syndrome with a karyotype of 46,X,i(Xq). The male infant was detected with a karyotype of 45,X, with presence of SRY gene but absence of AZF gene. CONCLUSION Both cases may be associated with abnormalities of X chromosome. Genetic testing can facilitate early diagnosis and clinical intervention for such patients.
Chromosomes, Human, X ; Humans ; Infant ; Karyotyping ; Male ; Muscular Dystrophy, Duchenne ; genetics ; Rare Diseases ; Turner Syndrome ; genetics

We report two cases of Turner syndrome with a female phenotype and a 45,X(22)/46,XY(88) karyotype. The relevant literatures in relation to the incidence, pathogenesis, clinical manifestations and managements of Turner syndrome with a 45,X/46,XY karyotype were reviewed.
Adolescent ; Child ; Chromosome Aberrations ; Female ; Humans ; Karyotype ; Phenotype ; Turner Syndrome ; genetics

OBJECTIVE: To explore the genetic characteristics of idic(X)(p11.22) in Turner syndrome (TS). METHODS: Two fetuses suspected for sex chromosome abnormalities or ultrasound abnormalities were selected from Chengdu Women's and Children's Central Hospital in October 2020 and June 2020, and amniotic fluid samples were collected for G-banded chromosomal karyotyping analysis, chromosomal microarray analysis (CMA), and fluorescence in situ hybridization (FISH). RESULTS: The two fetuses were respectively found to have a karyotype of 45,X[47]/46,X,psu idic(X)(p11.2)[53] and 46,X,psu idic(X)(p11.2). CMA found that both had deletions in the Xp22.33p11.22 region and duplications in the p11.22q28 region. FISH showed that the centromeres in both fetuses had located on an isochromosome. CONCLUSION The combination of karyotyping analysis, FISH, and CMA is useful for the delineation of complex structural chromosomal aberrations. High-resolution CMA can accurately identify chromosomal breakpoints, which can provide a clue for elucidating the mechanism of chromosomal breakage and rearrangement.
Female ; Pregnancy ; Humans ; Turner Syndrome/genetics* ; In Situ Hybridization, Fluorescence ; Sex Chromosome Aberrations ; Centromere ; Prenatal Diagnosis

OBJECTIVE: To investigate the clinical features and genetic etiology of a case of Turner syndrome (TS) with rapidly progressive puberty. METHODS: A child who had presented at the Pediatric Endocrinology Clinic of the Shenzhen People's Hospital on January 19, 2022 was selected as the study subject. Clinical data of the child were collected. Peripheral blood sample of the child was subjected to chromosomal microarray analysis (CMA) and multiple ligation-dependent probe amplification (MLPA). Previous studies related to TS with rapidly progressive puberty were retrieved from the CNKI, Wanfang Data Knowledge Service Platform, Boku, CBMdisc and PubMed databases with Turner syndrome and rapidly progressive puberty as the keywords. The duration for literature retrieval was set from November 9, 2021 to May 31, 2022. The clinical characteristics and karyotypes of the children were summarized. RESULTS: The child was a 13-year-and-2-month-old female. She was found to have breast development at 9, short stature at 10, and menarche at 11. At 13, she was found to have a 46,X,i(X)(q10) karyotype. At the time of admission, she had a height of 143.5 cm (< P3), with 6 ~ 8 nevi over her face and right clavicle. She also had bilateral simian creases but no saddle nasal bridge, neck webbing, cubitus valgus, shield chest or widened breast distance. She had menstruated for over 2 years, and her bone age has reached 15.6 years. CMA revealed that she had a 58.06 Mb deletion in the Xp22.33p11.1 region and a 94.49 Mb duplication in the Xp11.1q28 region. MLPA has confirmed monosomy Xp and trisomy Xq. A total of 13 reports were retrieved from the CNKI, Wanfang Data Knowledge Service Platform, Boku, CBMdisc and PubMed databases, which had included 14 similar cases. Analysis of the 15 children suggested that their main clinical manifestations have included short stature and growth retardation, and their chromosomal karyotypes were mainly mosaicisms. CONCLUSION The main clinical manifestations of TS with rapidly progressive puberty are short stature and growth retardation. Deletion in the Xp22.33p11.1 and duplication in the Xp11.1q28 probably underlay the TS with rapid progression in this child, which has provided a reference for clinical diagnosis and genetic counselling for her.
Humans ; Female ; Adolescent ; Puberty ; Turner Syndrome/genetics* ; Chromosomes, Human, X ; Karyotyping

OBJECTIVE: To explore the genetic characteristics of a child with mosaicism Turner syndrome. METHODS: A child who had presented at Linyi People's Hospital on May 19, 2022 due to short stature was selected as the study subject. The child was subjected to combined chromosomal karyotyping, fluorescence in situ hybridization (FISH), and chromosomal microarray analysis (CMA). RESULTS: The child was found to have a 46,X,i(X)(q10)[94]/45,X[6] karyotype. The result of FISH was nucish(XYpter,XYqter)1[78]/(XYpter)1,(XYqter)3[122]. CMA result for her peripheral blood sample was arr[hg19]Xp22.33p11.1(168551_58526888)×1, and that for her oral mucosal cells was arr[hg19]Xp22.33p11.1(168551_58526888)1-2,Xq11.2q28(63000001_155233098)×2-3. By integrating the above findings, her molecular karyotype was determined as mos 46,X,i(X)(q10)[94]/45,X[6].arr[hg19]Xp22.33p11.1(168551_58526888)×1-2,Xq11.2q28(63000001_155233098)×2-3.nucish(XYpter)1,(XYqter)3[122]/(XYpter,XYqter)1[78], which has indicated mosaicism Turner syndrome. CONCLUSION The 46,X,i(X)(q10)/45,X mosaicism probably underlay the pathogenesis in this child.
Humans ; Child ; Female ; Turner Syndrome/genetics* ; Mosaicism ; In Situ Hybridization, Fluorescence ; Karyotyping ; Karyotype

Turner syndrome is one of the most common cytogenetic abnormalities. It is known that the Y chromosome or Y derived material is present in 6-9% of TS patient and it may develop a high risk of gonadoblastoma in 15-25%. So it is crucial to carry out cyto genetic analysis and Y-specific probe studies for all persons with gonadal dysgenesis to rule out mosaicism with Y-bearing cell line; eg 45,X/46,XY. In this study, 26 archival slides previously analyzed cytogenetically as 45,X, 45,X/46,X,i(X), 45,X/46,X,r(X), and 45,X/46,XX were examined. Coamplification PCR, having the advantage of providing rapid result and confirming PCR failure, was performed with the slide samples in the regions of dystrophin gene in Xp21and DYZ3 in the Y centromeric region. All of archived slides were positive for X-specific gene and one slide of 45,X was found to have the cryptic Y chromosome material. Our result suggests that the archived cytogenetic slides could be applied for the detection of Y chromosome rapidly and efficiently in TS patients.
Biopsy ; Centromere/genetics ; Cytogenetic Analysis ; DNA/genetics ; DNA/analysis ; Dystrophin/genetics ; Female ; Human ; Karyotyping ; Male ; Mosaicism* ; Polymerase Chain Reaction ; Time Factors ; Tissue Preservation ; Turner's Syndrome/pathology ; Turner's Syndrome/genetics* ; X Chromosome/genetics ; Y Chromosome/genetics*

OBJECTIVETo study the relationship of karyotypes and gonadal development in children with Turner syndrome.

METHODSFifty-one children with Turner syndrome were studied. Pelvic ultrasonography was performed on the children. Twenty healthy age-matched girls were used as control group.

RESULTSEleven kinds of karyotypes were detected in 51 children with Turner syndrome. Children were classified into two groups based on karyotypes: Group 1 (45,XO; n= 24) and Group 2 (karyotypes other than 45, XO; n=27). 45,XO karyotype was the most common (47.1%), followed by 46,X,i (Xq)/45, XO (21.6%), 46,XX/45, XO (7.8%) and 47,XXX/45, XO (5.9%). Pelvic ultrasonography showed a primordial uterus in 41 cases, infantile uterus in 7 cases, congenital absence of uterus and ovary in 3 cases, simple anovarism in 42 cases and ovarian dysgenesis in 6 cases. Uterine size in both Groups 1 and 2 were significantly smaller than those of the control group (P<0.05). Group 1 showed smaller size of uterus than Group 2 (P<0.05). Ovaries were not detected in all Group 1 patients.

CONCLUSIONSThe dysplasia and atrophy of ovaries and uterus exist in children with Turner syndrome. The patients with 45,XO karyotype had poorer gonadal development than those with other karyotypes.

Child ; Child, Preschool ; Female ; Humans ; Karyotyping ; Ovary ; diagnostic imaging ; Turner Syndrome ; diagnostic imaging ; genetics ; Ultrasonography ; Uterus ; diagnostic imaging

Adolescent ; Body Height ; Chromosomes, Human, X ; Female ; Growth Hormone ; deficiency ; Humans ; Karyotyping ; Monosomy ; Mosaicism ; Turner Syndrome ; genetics ; metabolism ; pathology

A cytogenetic study was performed on 4,117 Korean patients referred for suspected chromosomal abnormalities. Chromosome aberrations were identified in 17.5% of the referred cases. The most common autosomal abnormality was Down syndrome and Turner syndrome in abnormalities of sex chromosome. The proportions of different karyotypes in Down syndrome (trisomy 21 92.5%, translocation 5.1%, mosaic 2.4%) were similar to those reported in other countries. However, it was different in Turner syndrome (45, X 28.1%, mosaic 50.8%, 46, X, del (Xq) 4.4%, 46, X, i (Xq) 16.7%), in which proportions of mosaics and isochromosome, 46, X, i(Xq), were higher than those reported in other countries. In structural chromosome aberrations of autosome, translocation was the most common (43.6%), and duplication (21.3%), deletion (14.4%), marker chromosome (7.9%) and ring chromosome (4.0%) followed in order of frequency. Rates of several normal variant karyotypes were also described. Inversion of chromosome 9 was observed in 1.7% of total referred cases.
Adolescence ; Chromosomes, Human, Pair 6 ; Down Syndrome/genetics* ; Down Syndrome/epidemiology* ; Family Health ; Female ; Gene Deletion ; Human ; Infant, Newborn ; Inversion (Genetics) ; Karyotyping ; Klinefelter's Syndrome/genetics ; Klinefelter's Syndrome/epidemiology ; Korea/epidemiology ; Male ; Mosaicism ; Prevalence ; Translocation (Genetics) ; Turner's Syndrome/genetics* ; Turner's Syndrome/epidemiology* ; X Chromosome ; Y Chromosome