Exclusively paternal X chromosomes in a girl with short stature

A 13 1/2 year-old girl with short stature and very few Turner stigmata revealed 45,X/46,XX mosaicism with 90%–100% 46,XX cells in three sequential blood lymphocyte cultures. Molecular investigation of the parental origin of her X chromosomes revealed homozygosity for paternal X markers and an absence of maternal markers. Luteinizing hormone response to growth hormone releasing hormone was increased. Impaired gonadal function and shortness of stature in this case could be a result of the mild mosaicism with a 45,X cell line and/or is a consequence of the paternal-only origin of her X chromosomes.     

46,X,i(Xq)/47,XX,+13 mosaicism

A 10-year-old girl with short stature and other features of Turner's syndrome was found to be a mosaic consisting of 46,X,i(Xq) and 47,XX,+13 cell lines, a hitherto undescribed situation. She had none of the clinical features of trisomy 13 syndrome, with a possible exception of postaxial polydactyly of the left foot. Her PHA-stimulated blood lymphocytes and EB virus-transformed B lymphocytes both revealed the Xi(Xq)/XX,+13 mosaicism, while her skin fibroblasts showed an exclusively 46,X,i(Xq) karyotype. Studies using Q-and R-banding heteromorphisms as markers indicated that the patient started as a 13 trisomic zygote resulting from a maternal meiotic error, followed by the loss of chromosome 13 at an early mitotic division. C-banding analysis revealed two C banding blocks in the iso X chromosome, an indication that the chromosome was dicentric. BrdU-Hoechst-Giemsa analysis revealed that the iso X chromosome was late-replicating with both its arms either synchronously or asynchronously replicating. The iso X chromosome was thus designated as idic (Xq)(p11:p11). In view of the presence of the XX cell line, it was concluded that the patient started as an XX,+13 zygote, followed by two mitotic events, the loss of a chromosome 13 and the formation of the iso X chromosome, occurring either simultaneously or in succession.     

Turner's syndrome--correlation between karyotype and phenotype

Turner's syndrome is defined as a congenital disease determining by quantitative and/or structural aberrations of one from two X chromosomes with frequent presence of mosaicism. Clinically it is characterized by growth and body proportion abnormalities, gonadal dysgenesis resulting in sexual infantilism, primary amenorrhoea, infertility, characteristic stigmata, anomalies of heart, renal and bones and the presence of some diseases like Hashimoto thyroiditis with hypothyroidism, diabetes mellitus type 2, osteoporosis, hypertension. Turner's syndrome occurs in 1:2000 to 1:2500 female livebirth. The most frequent X chromosome aberrations in patients with phenotype of Turner syndrome are as follows: X monosomy - 45,X; mosaicism (50-75%), including 45,X/46,XX (10-15%), 45,X/46,XY (2-6%), 45,X/46,X,i(Xq), 45,X/46,X,del(Xp), 45,X/46,XX/47,XXX; aberration of X structure: total or partial deletion of short arm of X chromosome (46,X,del(Xp)) isochromosom of long arm of X chromosome (46,X,(i(Xq)), ring chromosome (46, X,r(X)), marker chromosome (46,X+m). Searching of X chromosome and mapping and sequencing of genes located at this chromosome (such as SHOX, ODG2, VSPA, SOX 3) have made possible to look for linkage between phenotypes and adequate genes or regions of X chromosome. In this paper current data concerning correlation between phenotype and karyotype in patients with TS have been presented.     

Case report: a successful pregnancy outcome in a patient with non-mosaic Turner syndrome (45, X) via in vitro fertilization

We describe a successful pregnancy outcome in a patient with non-mosaic Turner syndrome (45, X) via in vitro fertilization. The patient achieved a second pregnancy at 35 years of age. The her blood lymphocyte karyotype was examined by G-band and FISH. Furthermore, cumulus cells and her elbow skin cells were evaluated via FISH. Non-mosaic Turner syndrome was determined by G-banding [100 % (50/50) 45, X]. Lymphocytes were shown as 478/500 (95.6 %) cells of X sex chromosome signal, 15/500 (3.0 %) cells of XXX signal, and 7/500 (1.4 %) cells of XX signal. The cumulus cells were mosaic: 152/260 (58.5 %) were X; 84/260 (32.3 %) were XXX, 20/260 (7.7 %) were XX, and 4/260 (1.5 %) were XY. Moreover, skin cells included a mosaic karyotype [47, XXX(29)/46, XX(1)]. We conclude that the collection of a large number of blood lymphocytes can reveal different mosaic patterns (X, XX and XXX) by FISH in spite of non-mosaic Turner syndrome.     

Mosaic triple X syndrome in a female with primary amenorrhea

BACKGROUND:

Turner''s syndrome is the most common chromosomal abnormality in females, affecting 1 in 2,500 live female births. It is a result of absence of an X chromosome or the presence of a structurally abnormal X chromosome. Its most consistent clinical features are short stature and ovarian failure.

AIM:

The aim of the study was to report a rare case of mosaic triple X syndrome in a female with primary amenorrhea.

MATERIALS AND METHODS:

The chromosomal analysis using GTG banding was carried out, which revealed a mosaicism with 45,XO/47,XXX chromosomal constitution. Fluorescent in situ hybridization was also carried out to further confirm the observation made in the study.

CONCLUSION:

The physical features presented by the female could be due to the 45,XO/47,XXX mosaicism and the karyotype analysis was consistent with the diagnosis and clinical symptoms. Triple X mosaicism was confirmed with conventional and molecular cytogenetic analysis.     

Chromosome 14 maternal uniparental disomy in the euploid cell line of a fetus with mosaic 46,XX/47,XX,+14 karyotype

We investigated the parental origin of the extra chromosome 14 and of the two chromosomes 14 of the euploid cell line, in a case of fetal mosaicism 46,XX/47,XX+14 diagnosed at amniocentesis. Molecular analysis of five polymorphic loci of the short tandem repeat type was performed. Markers D14S43 and D14S49 showed the presence of maternal uniparental disomy of chromosome 14 in the apparently normal cell line. The distribution of the markers analysed along the chromosome suggests maternal heterodisomy with a large isodisomic segment in the telomeric region, possibly caused by meiotic crossing-over.     

Dicentric Y-chromosome mosaicism in a girl with clitoral hypertrophy

Summary A 12-year-old girl with small stature and a hypertrophic clitoris was found to be mosaic for 45,X/46,X.dic(Y)(qter»p11:p11»qter)/46,XX/47, XX,dic(Y)(qter»p11:raqter). The dicentric chromosome was identified using Q-banding. These findings indicate mitotic instability of the dicentric Y, as well as the presence of an X chromosome in this patient.     

Triple X Egyptian woman and a Down's syndrome offspring

The 47, XXX karyotype (triple X) has a frequency of 1 in 1000 female newborns. However, this karyotype is not usually suspected at birth or childhood. Female patients with a sex chromosome abnormality may be fertile. In patients with a 47, XXX cell line there appears to be an increased risk of a cytogenetically abnormal child but the extent of this risk cannot yet be determined; it is probably lower in the non-mosaic 47, XXX patient than the mosaic 46, XX/47, XXX one. We describe a new rare case of triple X woman and a Down''s syndrome offspring. The patient is 26 years of age. She is a housewife, her height is 160 cm and weight is 68 kg and her physical features and mentality are normal. She has had one pregnancy at the age of 25 years resulted in a girl with Down''s syndrome. The child had 47 chromosomes with trisomy 21 (47, XX, +21) Figure 1. The patient also has 47 chromosomes with a triple X karyotype (47, XX, +X) Figure 2. The patient''s husband (27 years old) is physically and mentally normal. He has 46 chromosomes with a normal XY karyotype (46, XY). There are neither Consanguinity between her parent''s nor she and her husband.Open in a separate windowFigure 1Karyotype 47, XX + 21 of the daughter of Triple X syndromeOpen in a separate windowFigure 2Karyptype 47, XX + X of the Down syndrome''s mother     

A low-level X chromosome mosaicism in mares, detected by chromosome painting

Fluorescence in situ hybridization with the use of the equine X whole chromosome painting probe was carried out on chromosome spreads originating from three mares with poor reproductive performance (infertility, miscarriage or stillbirth). The numbers of analysed spreads were high (105, 300 and 480) and in all three mares a low frequency of mosaicism was identified. The mares had the following karyotypes: 64,XX/63,X/65,XXX (93.6%/5.7%/0.7%), 64,XX/63,X (98.9%/1.1%) and 64,XX/63,X (94.3%/5.7%). The incidence and importance of the low percentage X chromosome mosaicism are discussed.     

Mosaicism 45,X/46,X, t dic(Xp:Xp) in a girl with short stature

An eight-year-old girl with marked short stature and no apparent stigmata of Turner syndrome was investigated. Clinical features include bilateral epicanthic folds, frontal bossing, prominent ears and normal intelligence. Ultrasound scanning revealed an apparently normal vagina, streak ovaries and no uterus. Bone age was normal. Karyotype analysis of peripheral blood lymphocytes showed mos 45,X/46,X tdic(Xp:Xp) in the ratio 66:34, respectively. In addition, three cells with different abnormal X chromosomes were present which possibly originated from a 46,XX clone. Replication of the duplicated X chromosome was consistently late and symmetrical. Buccal smear confirmation of the karyotype showed Barr body negative in 90% and large or bipartite in 10% of the cells. Karyotypes of the parents were normal. The clinical manifestations in cases of Xp deletion due to terminal rearrangement associated with or without a 45,X cell line are discussed.     

Hypersarcosinemia with craniostenosis-syndactylism syndrome

Summary A 46,XX/47,XX,+16 mosaicism was demonstrated in cultured chorionic cells obtained from an abortion material. By tracing polymorphic fluorescent chromosome markers in the abortus and the parents, the karyotypically normal component was confirmed to be non-maternal in origin. The trisomic cells showed a growth disadvantage, and were overtaken by the normal cells in prolonged cultivation.     

Clinical outcome and follow-up of the first reported case of Russell-Silver syndrome with the unique combination of maternal uniparental heterodisomy 7 and mosaic trisomy 7

BACKGROUND: Russell-Silver syndrome (RSS) has been associated with maternal uniparental disomy (UPD) for chromosome 7 although the etiology of the syndrome is still unknown. Cases of RSS associated with maternal UPD7 have involved isodisomies, heterodisomies, and mixed isodisomy with heterodisomy simultaneously. This publication is a follow-up report of the postnatal clinical outcome of the first prenatally suspected case of combined mosaic trisomy 7 with maternal uniparental disomy of chromosome 7 (UPD7). CASE: The diagnosis of RSS in the proband was suspected prenatally because trisomy 7 mosaicism (47,XX,+7[13]/46,XX[19]) and maternal uniparental heterodisomy 7 were both found in amniotic fluid cells. Cord blood karyotype analysis showed only disomic cells (46,XX[50]), whereas postpartum chorionic villus analysis was completely trisomic for chromosome 7 (47,XX,+7[19]). Postnatally, the diagnosis of RSS was confirmed by physical findings, her trisomy 7 mosaicism was confirmed by cytogenetic analysis of her skin biopsy (47,XX,+7[9]/46,XX[20]) and her UPD7 was confirmed on both peripheral blood and skin biopsy using microsatellite markers. During infancy, the proband experienced growth deficiency, persistent hypoglycemia, and psychomotor developmental delay. CONCLUSIONS: Trisomic rescue as a life-saving mechanism, with subsequent chromosomal mosaicism in combination with UPD may occur more frequently in RSS than has been reported. Systematic testing of cases suspected prenatally or postnatally would be informative regarding the individual contribution of each factor. Imprinting, loss of heterozygosity for recessive genes, and mosaicism may explain the short stature, asymmetry, and the variable expression of the phenotype. The contribution of these mechanisms to the syndrome should be evaluated in these cases.     

On telomere replication and fusion in eukaryotes: apropos of a case of 45,X/46,X,ter rea(X;X)(p22.3;p22.3)

A Mexican 181/2-year-old girl with short stature, primary amenorrhea, and mild Turner stigmata was found to have a 45,X/46,X,ter rea(X;X)(p22.3;p22.3) karyotype in her lymphocytes. The rearranged chromosome was twice the size of a normal X, appeared to be attached head-to-head, had no detectable chromatin loss, only one primary constriction, constitutive heterochromatin at both the centromere and pseudocentromere regions, was mitotically stable, and always showed late replication. From the analysis of this and other X;X terminal rearrangements we draw four conclusions: (1) Terminal rearrangements may arise either by telomeric fusion (tel fus) without loss of genetic material or from a conventional telomeric translocation. (2) Telomeric fusions between homologous chromosomes (the commonest type) can be secondary to impaired telomeric replication. (3) Phenotypically, patients with an X;X terminal rearrangement show great variability which depends mainly on whether or not chromatin has been lost in the rejoining process and a 45,X clone. (4) Patients with an X;X telomeric fusion without mosaicism are likely to have an XXX phenotype, whereas turneroid features are expected in mixoploidies that include an X monosomic clone and in cases of translocations involving the short arms.     

Detection of X chromosome aneuploidy using Southern blot analysis during routine population-based screening for fragile X syndrome

We report herein two cases where detection of X chromosome aneuploidy (cytogenetically proved 45,X/46XX and 47,XXX) was made possible by molecular diagnosis during population-based carrier screening for Fragile X syndrome, using Southern blot analysis. This study emphasizes the value of molecular analysis for gene dosage to suggest chromosomal aneuploidy.     

An infant with Turner-Down aneuploidy and massive capillary hemangioma of the orbit: a case report with review

We report on a case of double aneuploidy involving Down and Turner cell lines in a female child with a massive capillary hemangioma of the left orbit and mild clinical features of Down syndrome. Cytogenetic findings with G-banding revealed mosaicism in her peripheral blood, i.e. mos45,X[48]/47,XX,+21[28]/46,XX[12/47,XXX[12]. Mosaicism of such nature is rare and to our knowledge the present case is the first reported of Turner-Down double aneuploidy mosaicism associated with an orbital capillary hemangioma. An annotated bibliography of earlier reported cases with documented karyotyping is also included.     

Turner syndrome mosaicism: an unusual case with a de novo large dicentric marker chromosome: mos 45,X/46,X, ter rea(X;X)(p22.3;p22.3)

X/X translocations are quite rare in humans. The effect of this anomaly on the phenotype is variable and depends on the amount of deleted material and whether the chromosomes are joined by their long or short arms. We report an unusual case of Turner syndrome mosaicism in a 16-year-old girl, who was referred to our Institute for primary amenorrhoea associated with short stature. Endocrine evaluation revealed hypergonadotropic hypogonadism, which required a study of the karyotype. Cytogenetic analysis, performed on peripheral blood leucocytes, showed a mos 45,X/46,X,ter rea (X;X)(p22.3;p22.3) de novo karyotype. The prevalent cell line was 45,X (90% cells). A second cell line (10% cells) showed a very large marker chromosome, similar to a large metacentric chromosome. FISH (fluorescent in situ hybridisation) and molecular analysis revealed that the marker chromosome was dicentric and totally derived from the paternal X chromosome.     

Karyological characteristics of Down's syndrome: clinical and theoretical aspects

These data have been collected from St. Petersburg Down Syndrome Register that comprises information on 1778 liveborn children with the Down syndrome, including three twin sets, ascertained within 1970-1996. Karyotypes were obtained in 1223 cases, of which 1119 (90.7%) displayed regular trisomy. Mosaicism was found in 44 cases (3.6%), including 21 males and 24 females, and among these one familial case of mosaicism in a daughter and in a healthy mother. Of 70 cases of translocations, 41(5.7%) were Robertsonian D ones. 21 (17 inherited, 16 de novo and 8 of unknown origin), 28 translocations of isochromosomes 21q; 21q (1 inherited translocation 21; 22, 22 de novo and 5 of unknown origin). One child received the anomaly from his 46XX/45XX, t(D;G) mother-carrier. In 6 cases, free trisomy 21 was associated with structural or numerical anomalies: 46XY,t(13;14)mat + 21 in twins, 47XY,t(C;C) + 21, 47XY,t(10;15)pat + 21, 47XY,inv(19)mat + 21, 47XX + 21/48XX + 21 + ring, 48XXX + 21. In 12 families parental mosaicism was shown or suspected. In 6 families one parent had chromosome anomaly, in three cases it was not inherited: t(15;22) and t(6;21) in mothers and an additional small marker in a father. In cases confirmed cytogenetically an increased sex ratio was shown (679 males and 551 females, SR = 1.23), but it was not shown in patients not tested cytogenetically (264 males and 275 females, SR = 0.96, different from the expected 297 males and 242 females, P < 0.01).     

A Turner patient with a 45,X,t(1;2) (q41;p11.2) karyotype

The most common chromosomal anomaly is 45,X in the Turner syndrome. In addition to this, anomaly, mosaicism such as structural 46,X,i(Xq), 46,X,del(Xp), 46,X,r(X), 46,X,t(X;Y) and numerical 46XO/46,XX/47XXX are seen rather frequently. An infant with the Turner syndrome was found to have a karyotype 45X,t(1;2) (q41;p16) using high resolution banding. Based on our knowledge, we present the first case of 45X,t(1;2) (q41;p11.2), a karyotype in Turner's syndrome in the literature.     

Molecular studies of chromosomal mosaicism: relative frequency of chromosome gain or loss and possible role of cell selection.

Studies of uniparental disomy and origin of nonmosaic trisomies indicate that both gain and loss of a chromosome can occur after fertilization. It is therefore of interest to determine both the relative frequency with which gain or loss can contribute to chromosomal mosaicism and whether these frequencies are influenced by selective factors. Thirty-two mosaic cases were examined with molecular markers, to try to determine which was the primary and which was the secondary cell line: 16 cases of disomy/trisomy mosaicism (5 trisomy 8, 2 trisomy 13, 1 trisomy 18, 4 trisomy 21, and 4 involving the X chromosome), 14 cases of 45,X/46,XX, and 2 cases of 45,X/47,XXX. Of the 14 cases of mosaic 45,X/46,XX, chromosome loss from a normal disomic fertilization predominated, supporting the hypothesis that 45,X might be compatible with survival only when the 45,X cell line arises relatively late in development. Most cases of disomy/trisomy mosaicism involving chromosomes 13, 18, 21, and X were also frequently associated with somatic loss of one (or more) chromosome, in these cases from a trisomic fertilization. By contrast, four of the five trisomy 8 cases were consistent with a somatic gain of a chromosome 8 during development from a normal zygote. It is possible that survival of trisomy 8 is also much more likely when the aneuploid cell line arises relatively late in development.     

Trisomy 21 Down syndrome

Summary In a series of 374 families with Down syndrome progeny, structural chromosome rearrangements were detected in the parents of six children with regular trisomy. The aberrations were reciprocal translocations and inversions. In all three informative families, the parent who transmitted the extra chromosome was not the one with the structural rearrangement. Among the three non-informative families there was one in which both parents carried different reciprocal translocations. In two other families a chromosome aberration was detected: a triple X mother and a father with a Philadelphia chromosome. Omitting the four parents with possible biased asccrtainment, 0.4% had a chromosome rearrangement. When the parents with constitutional chromosome aberrations and those with mosaicism, described previously, are combined, the frequency of chromosomally abnormal parents lies between 1.9% and 3.2%. When correlated with parental transmission of the extra chromosome, mosaicism rather than structural rearrangements appears to be of ctiologic significance.