46,XY monozygotic twins with discordant sex phenotype.

OBJECTIVE: To analyze male and female sex differentiation in monozygotic twins. DESIGN: Retrospective study. SETTING: Multiple academic centers. PATIENT(S): A pair of monozygotic twins. INTERVENTION(S): Skin and blood samples were obtained for DNA analysis and karyotyping. MAIN OUTCOME MEASURE(S): Mutation within the SRY gene was analyzed by the polymerase chain reaction-single-stranded conformation polymorphism test. Monozygosity was ascertained by short tandem repeat analysis. Karyotypes were studied in blood and skin fibroblasts. RESULT(S): SRY was present in both twins, but no mutations were detected in the SRY conserved motif. Monozygosity was confirmed by the use of short tandem repeat analysis in four loci: c-fms, thyroid peroxidase, von Willebrand factor, and tyrosine hydroxylase. The karyotype was 46,XY uniformly in both twins. CONCLUSION(S): Monozygotic twins can develop discordant male and female phenotypes despite the presence of a common karyotype and despite the presence of intact testis-determining genes. In the present case, this could be due to mutation or to mosaicism involving occult 45,X cell lines in the dysgenetic gonads.

Localization of SRY by primed in situ labeling in XX and XY sex reversal.

Primed in situ labeling (PRINS) can be used to localize DNA segments too small to be detected by fluorescence in situ hybridization. By PRINS we identified the SRY gene in two XX males, a woman with XY gonadal dysgenesis, and an azoospermic male with Xp-Yp interchange. Because PRINS has been used generally in the study of repetitive sequences, we modified the technique for study of the single copy 2. 1-kb SRY sequence. SRY signals were identified at band Yp11.31p11.32 in normal XY males and in the woman with XY gonadal dysgenesis. SRY signals were identified on Xp22 in one XX male but not in the other. They were identified in the corresponding region (Xp22) of the der(X) in the azoospermic male with Xp-Yp interchange. SRY signals were not observed in normal XX females. Presence of SRY in DNA samples from the various subjects was confirmed by polymerase chain reaction. We conclude that PRINS is ideal for rapid localization of single copy genes and small DNA segments in general.

Chromosomal localization of single copy genes SRY and SOX3 by primed in situ labeling (PRINS).

Primed in situ labeling (PRINS) is a sensitive and specific technique that can be used for the localization of single copy genes and DNA segments that are too small to be detected by conventional FISH. With PRINS, we physically localized the SRY gene to Yp11.31p11.32 and the SOX3 gene to Xq26q27. Locus-specific oligonucleotide primers were annealed in situ and extended on chromosome preparations fixed on microscope slides, in the presence of dATP, dCTP, dGTP, dTTP, biotin-16-dUTP, Tris-HCl, KCl, MgCl2, BSA, and Taq DNA polymerase. Fluorescent signals were detected in metaphase spreads and interphase nuclei. Our method may prove valuable for use with single copy genes in general.

Hypomelanosis of ito and a 'mirror image' whole chromosome duplication resulting in trisomy 14 mosaicism.

We describe a female infant with multiple congenital anomalies including unusual hyperpigmentation, tetralogy of Fallot, absent corpus callosum and wide prominent nasal bridge. The infant was initially seen for genetic consultation on day one after birth. Chromosome analysis from cultured lymphocytes showed a normal 46,XX karyotype. However, cultured skin fibroblasts showed mosaicism with 46,XX,add(14)(q32).ish psu dic dup(14)(q32p13)(wcp14+)/46,XX complements. A review of the published report with chromosome mosaicism and hypomelanosis of Ito (HMI) is included. We suggest that the trisomy 14 mosaicism seen in fibroblast cultures has importance in the expression of pigmentation dysplasias in this patient. Pigmentary anomaly may be due to loss or gain of specific genes that influence pigmentation located on the long arm of chromosome 14 in this patient.

Fetal 'space-suit' hydrops in the first trimester: differentiating risk for chromosome abnormalities by delineating characteristics of nuchal translucency.

Detecting first trimester fetuses with pan-body hydrops, giving the appearance of a 'space-suit,' is associated with a marked increased risk for chromosome abnormalities. In 30 consecutive fetuses prospectively characterized by space-suit hydrops, detected at or before 13.9 weeks' gestation, 26 (86.7%) were characterized by chromosome abnormalities. However, as opposed to the preponderance of autosome abnormalities among first-trimester fetuses with prominent nuchal translucencies, 15 of the 26 fetuses (57.7%) with abnormal complements were characterized by sex chromosome aneuploidies. Genetic counselling and consideration of invasive prenatal testing is warranted when space-suit hydrops is detected in the first trimester.

Chromosome duplications and deletions and their mechanisms of origin.

Duplications and deletions of the same gene loci or chromosome regions are known to produce different clinical manifestations and are significant factors in human morbidity and mortality. Extensive cytogenetic and molecular cytogenetic studies with cosmid and YAC probes in two patients with unique mosaicism for reciprocal duplication-deletion allowed us to further understand the origin of these abnormalities. The first patient's mosaic karyotype was 46,XX, inv dup(11) (q23q13)/46,XX,del(11)(q13q23). The second patient had a 46,XY,dup(7)(p11.2p13)/46,XY,del(7)(p11.2p13)/46,XY karyotype. Fluorescence in situ hybridization studies on the first patient placed the two breakpoints near the folate-sensitive fragile sites FRA11A and FRA11B. The presence of repeated sequences responsible for these fragile sites may have been involved in the patient's duplication-deletion. Our investigation leads us to conclude that, in addition to known mechanisms (such as unequal crossovers between homologs, unequal sister chromatid exchanges, excision of intrachromatid loops, and meiotic recombination within a single chromatid), duplication-deletion can also arise by the formation of an overlying loop followed by an uneven crossover at the level of the DNA strand.

Validation of primed in situ labeling (PRINS) for interphase analysis: comparative studies with conventional fluorescence in situ hybridization and chromosome analyses.

Primed in situ labeling (PRINS) is a rapidly developing new technology with wide ranging clinical applications. To assess the sensitivity, specificity, and accuracy of PRINS, we carried out a retrospective study on cultured bone marrow cells to detect aneuploidy for chromosomes 7, 8, and 12. The results were then compared to the results of previous fluorescence in situ hybridization (FISH) and chromosome analyses (CA). In patients who showed aneuploidy with CA, both FISH and PRINS confirmed the aneuploidy in interphase cells. FISH and PRINS also showed excellent correlation with conventional cytogenetic analysis for the detection of mosaic aneuploidies. However, both FISH and PRINS showed significantly higher sensitivity in the detection of abnormal clones compared to CA. In 9 of the 17 cases, there were no significant differences in the detection rates between the two methods. Based on our studies, we conclude that PRINS is as sensitive as FISH in most cases for aneuploidy detection; and that PRINS, like FISH, is more sensitive than conventional CA for aneuploidy detection.

Prenatal karyotyping using fetal blood obtained by cordocentesis: rapid and accurate results within 24 hours.

Spontaneously-dividing nucleated erythrocytes present in prenatal cordocentesis samples can be used to obtain fetal karyotype information within 24 hours. Following a modified protocol we performed rapid chromosome analysis on fetal blood from 70 second- and third-trimester fetuses. In all cases cordocentesis was performed following detection of ultrasound abnormalities. Cytogenetic diagnoses were obtained within 24 hours from 59 (84.3%) of the 70 samples. Follow-up chromosome analysis from mitogen-stimulated cultures showed concordant results in 57 of the 59 successful cases. In one case a mosaicism for 45, X[4]/46,X,i(X)(q10)[4] was detected in unstimulated harvest while mitogen-stimulated preparations showed only the 46,X,i(X)(q10) line. In the second case, a marker chromosome was identified in all 5 cells analyzed from the unstimulated harvest while mitogen-stimulated cultures showed only 4 out of 100 cells with the marker.

Primed in situ labeling for rapid prenatal diagnosis.

OBJECTIVE: Our purpose was to assess the feasibility of primed in situ labeling for analysis of prenatal diagnostic specimens. STUDY DESIGN: Prenatal diagnostic specimens were chosen at random for analysis without knowledge of clinical indication. Primed in situ labeling with primers for chromosomes 18, 21, X, and Y was performed separate from conventional cytogenetic analyses. All clinical management considerations were based solely on conventional cytogenetic analyses. RESULTS: Forty-one samples were analyzed by primed in situ labeling: 35 direct preparations of chorionic villi and 6 uncultured amniotic fluid samples. In all cases analysis confirmed the particular chromosome number determined by conventional cytogenetic analysis. CONCLUSIONS: Although conventional metaphase studies remain the standard for prenatal cytogenetic analyses, the preliminary feasibility study finds primed in situ labeling to be a rapid and reliable adjunctive diagnostic technique applicable for prenatal diagnosis in certain clinical situations. Further study is needed to assess the efficacy of primed in situ labeling in comparison to fluorescent in situ hybridization and conventional cytogenetic analyses for prenatal diagnoses.

Most Jacobsen syndrome deletion breakpoints occur distal to FRA11B.

Recent studies have identified a (CCG)n repeat in the 5' untranslated region of the CBL2 protooncogene (11q23.3) and have demonstrated that expansion of this repeat causes expression of the folate-sensitive fragile site FRA11B. It has also been demonstrated that FRA11B is the site of breakage in some cases of Jacobsen syndrome (JS) involving terminal deletions of chromosome 11q. We report on 2 patients with JS and a 46,XX,del(11)(q23.3) karyotype. In both cases, microsatellite and fluorescence in situ hybridization analyses indicated that the deletion breakpoint was approximately 1.5-3 Mb telomeric to FRA11B. There was no evidence of expansion of the CBL2 (CCG)n repeat in the parents of either patient. The deleted chromosome was of paternal origin in both cases, although it was of maternal origin in the cases reported to be caused by FRA11B. These findings and those in previously reported patients suggest that the breakpoint for most 11q deletions in JS patients is telomeric to FRA11B, which raises the possibility that there may be other fragile sites in 11q23.3 in addition to FRA11B. These findings also support previous evidence that there may be a propensity for breakpoints to differ depending on the parental origin of the deleted chromosome.

Rapid identification of marker chromosomes using primed in situ labeling (PRINS).

Primed in situ labeling (PRINS) is a relatively new technology with wide-ranging applications in clinical cytogenetics. Using PRINS, we have identified the chromosomal origin of marker chromosomes in three patients. In the first patient with primary amenorrhea, we were able to confirm the marker chromosome as originating from an X. In the second (prenatal) case, PRINS allowed us to determine rapidly the origin of the marker as a Y chromosome. In the third patient with minor anomalies, the marker was identified as derived from a chromosome 18. In all three cases, application of PRINS permitted us to characterize the marker chromosomes within 1 hour after the slides were prepared. The methodology is simple, has added advantages over conventional fluorescence in situ hybridization (FISH), and can be used as a viable and effective alternative to FISH in clinical cytogenetic diagnosis.

Down syndrome with biparental inheritance of der(14q21q) and maternally derived trisomy 21: confirmation by fluorescent in situ hybridization and microsatellite polymorphism analysis.

Individuals with translocation Down syndrome (DS) often inherit the rearranged chromosome from a carrier parent. DS due to inheritance of one Robertsonian or derivative (14q21q) from one parent and a second der(14q21q) in addition to a free chromosome 21 from the other parent are rarely documented in liveborn infants. Presented here is such a propositus with DS and with a unique karyotype 45,XY,der(14;21) (p11.1;p11.1)pat,der(14;21)(p11.1;q11.1)mat, +21mat. Using conventional chromosome heteromorphisms, fluorescent in situ hybridization (FISH), and microsatellite polymorphism analyses, we established the biparental origin of the 2 der(14q21q) and the maternal origin of the extra chromosome 21 in the patient. A combination of both cytogenetic and molecular genetic techniques also enabled us to show that the 2 der(14q21q) were not identical by descent and hence the parents were nonconsanguineous. It has been a well-established fact that mothers with Robertsonian translocations have higher risk for nondisjunction than do carrier fathers. Our case, wherein the nondisjunctional event occurred in the mother, even though both parents are carriers of a 14;21 Robertsonian translocation, is yet another example of this.

Discordant direct and culture results following chorionic villus sampling and the diagnosis of a third cell line in the fetus.

We report a case of discordant non-mosaic karyotypes following chorionic villus sampling (CVS). A 45,XX,der(21;21)(q10;q10) karyotype was found on direct preparation of cytotrophoblasts and 46,XX was found on long-term culture of mesenchymal core cells. Analysis of amniotic fluid cells and fetal tissue revealed a third karyotype: 46,XX,+21,der(21;21)(q10;q10). Had only culture analysis been performed, follow-up studies might not have been undertaken. This case demonstrates the importance of direct CVS preparation in helping to identify fetal abnormalities, and the need for follow-up of discordant CVS results.

Clinical applications of primed in situ labelling (PRINS) rapid identification of a marker chromosome in a fetus.

Marker chromosomes pose a serious problem in clinical cytogenetic diagnosis since the conventional banding analyses are often not useful in identifying their origin or composition. In the absence of information, counseling as to the clinical significance and prognosis is difficult, especially in prenatal diagnosis. With the introduction of fluorescence in situ hybridization (FISH) marker identification has became feasible. However, FISH is relatively time-consuming and expensive. In an effort to overcome these disadvantages, we have used primed in situ labelling (PRINS) technique as an alternative. Presented here is one case in which PRINS was useful in rapidly identifying the origin of a marker chromosome detected on amniotic fluid chromosome analysis. Based on our experience with this case and others, we propose that PRINS can become a viable and cost effective alternative to FISH and is as reliable as FISH in terms of accuracy, specificity, and sensitivity.

Jacobsen syndrome: report of a patient with severe eye anomalies, growth hormone deficiency, and hypothyroidism associated with deletion 11 (q23q25) and review of 52 cases.

We have evaluated a patient with Jacobsen syndrome. The patient presented with growth retardation, hypotonia, trigonocephaly, telecanthus, downward slanting palpebral fissures, bilateral inferior colobomas (of the iris, choroid, and retina), hydrocephalus, central nervous system (CNS) abnormalities, and an endocardial cushion defect, features commonly seen in Jacobsen syndrome. Endocrine evaluation showed growth hormone deficiency and central hypothyroidism. Chromosome analysis showed a 46,XX,del(11)(q23q25) de novo karyotype. Cytogenetically, the deletion appeared to include most of bands 11q23 and q24 and a portion of q25. Using chromosome specific paint probe, a combination of chromosome 11 centromere, telomere, and region specific cosmid probes from 11q14.1-14.3, 11q23.3, and 11q24.1, we have localised the deletion breakpoint to q24.1. Phenotype-karyotype correlation of patients with Jacobsen syndrome and specific deletions of chromosome 11q has enabled us to suggest that the critical region for this syndrome lies in close proximity to cytogenetic band 11q24. Although growth retardation is a consistent finding in 11q deletion syndrome, the presence of hypothalamic-pituitary hormone deficiency has not been reported previously.

A jumping Robertsonian translocation: a molecular and cytogenetic study.

We report a patient with mosaicism for two different Robertsonian translocations, both involving chromosome 21. She carries an unbalanced cell line with an i(21q) and a balanced cell line with a rob(21q22q). She is phenotypically normal but has two children who inherited the i(21q) and have Down syndrome. We demonstrate that both abnormal chromosomes are dicentric and that the proband's 21/21 rearrangement is an isochromosome formed from a maternally derived chromosome 21. We propose a model in which the i(21q) is the progenitor rearrangement in the proband, which subsequently participated in a nonreciprocal rearrangement characteristic of a jumping translocation. In addition, we review other cases of constitutional mosaicism involving jumping translocations.

Risk of fetal mosaicism when placental mosaicism is diagnosed by chorionic villus sampling.

OBJECTIVE: Our purpose was to determine the risk of fetal mosaicism when placental mosaicism is found on chorionic villus sampling. STUDY DESIGN: We present a case of mosaic trisomy 22 detected on chorionic villus sampling and subsequently found in the fetus. A review of comprehensive chorionic villus sampling studies with emphasis on follow-up for fetal mosaicism was conducted. RESULTS: Among 13 studies reviewed, 469 cases of placental mosaicism are presented; fetal mosaicism was found in 50 (10.7%). Factors associated with fetal mosaicism are (1) mosaicism on mesenchymal core culture and (2) type of chromosome abnormality involved--specifically, marker chromosomes (26.7%) and common autosomal trisomies (19.0%). Amniocentesis predicted fetal genotype in 93% to 100% of cases of placental mosaicism, depending on the cell type in which mosaicism was diagnosed. CONCLUSIONS: Although mosaicism is usually confined to the placenta, the fetus is involved in about 10% cases. Patients should be counseled about this risk and the accuracy of follow-up amniocentesis.

Characterization of an unbalanced de novo rearrangement by microsatellite polymorphism typing and by fluorescent in situ hybridization.

Unbalanced de novo rearrangements, difficult to characterize by conventional cytogenetic techniques, may be elucidated by molecular approaches. By dinucleotide repeat polymorphism typing and fluorescence in situ hybridization (FISH), we have defined the composition of an unbalanced de novo translocation (46,XX,15p+) in a child with multiple congenital anomalies. Use of a microsatellite repeat D5S208 (localized to 5p15) and polymerase chain reaction (PCR) analysis confirmed that the extra segment originated from the short arm of chromosome 5. Amplification of the patient's DNA with primers for dinucleotide repeats D5S350 and D5S118 showed that the entire 5p (from 5pter to 5q11) was present in 3 copies. FISH confirmed the trisomic status of 5p, and further revealed the presence of centromeres of both chromosomes 5 and 15 on the rearranged chromosome thus delineating its dicentric nature. This information allowed us to redefine the de novo rearrangement in this patient as 46,XX,dic der(15)t(5;15)(q11;p11).