GTG-banded Chromosome Analysis Research Articles

Copy number variations in male breast cancer.

Common copy number variations often contain cancer-related genes and are likely to play a role in carcinogenesis. Different mechanisms of tumorigenesis are suggested in female and male breast cancer because of different molecular profiles. The cytogenetic analysis of GTG-banded chromosomes was performed in six male patients with infiltrating ductal carcinoma and six healthy male controls matched for age. Single-nucleotide polymorphism (SNP) array analysis was performed in male breast cancer (MBC) patients. Cytogenetic analysis found aberrations previously implicated in cancer. SNP array analysis in patients revealed a gain of Xp11.23, 8p23.2, Yq11.221, Yq11.3 (AZF region), 12p11.21, 18q12.1, and 17q21.3; a loss of Yq11.222 and 7q11.21; and a loss of heterozygosity of 4p16.3, 6p12.3, 6p22.2-p21.31, 7p14.2-14.1, 18q11.2-q12.1, 20p11.23-11.1, 20q11.21-11.23, 1q25.2-q25.3, 2q11.1-q11.2, 5q23.1-23.2, 11p15.4-15.3, and 22q13.1-13.31. Some of these variations, especially those of the Y-chromosome, have not been reported earlier. Chromosomal loci identified by SNP array harbor genes were reported to be associated with cancer progression and metastasis, indicating their involvement in MBC also.

Chromosomal abnormalities in products of conception of first-trimester miscarriages detected by conventional cytogenetic analysis: a review of 1000 cases.

The purpose of this study is to perform a retrospective analysis of types and frequencies of chromosomal abnormalities detected by conventional cytogenetic studies in first-trimester miscarriages after spontaneous conception and IVF. Standard cytogenetic analysis of GTG-banded chromosomes obtained from products of conception (POCs): semi-direct and short-term cultured chorionic villi or long-term cultured fetal mesodermal cells. 50.1% of first-trimester miscarriages in the studied group had chromosomal abnormalities: 59.7% of trisomies, 22% of poliploidies, 7.5% of monosomies, 7% of unbalanced structural abnormalities, and 3.8% of multiple aneuploidies. An increase in the frequency of chromosomally abnormal miscarriages was observed in the group of women above 40 when compared to groups of women under 35 (P<0.05). No difference in frequencies and types of chromosomal abnormalities in POCs of miscarriages after ICSI and spontaneous conception was observed. Approximately, 50% of first-trimester miscarriages have chromosomal abnormalities which can be detected by conventional cytogenetic analysis. The presence of chromosomal abnormality may explain the cause of miscarriage, improving the reproductive counseling and planning.

Axenfeld–Rieger anomaly and Axenfeld–Rieger syndrome: Clinical, molecular‐cytogenetic, and DNA array analyses of three patients with chromosomal defects at 6p25

Clinical phenotypes of and genetic aberrations in three unrelated Japanese patients with Axenfeld-Rieger anomalies and various accompanying malformations of systemic organs are described. GTG-banded chromosome analysis showed terminal deletions of the short arm of chromosome 6 in two patients and an inversion, inv(6)(p25q14), in the other. FISH and DNA array analyses revealed that the two patients with deletions had 5.0-5.7 Mb and 6.6 Mb 6p terminal deletions, respectively, and FOXC1 was apparently deleted in both patients. In the other patient, the inversion breakpoint at 6p25 was estimated to be in or very close to the FOXC1 locus, but DNA array analysis did not reveal a deletion around the breakpoint. Common extraocular findings in these patients included broad forehead, brachycephaly, hypertelorism, downslanting palpebral fissures, small anteverted nose, and cardiac defects. Two patients also exhibited autistic characteristics. The two patients with deletions exhibited poor muscle tone and developmental delays. Most of these extraocular findings were similar to those found in previous patients with FOXC1 mutations and distinct from those found in patients with PITX2 mutations, who frequently develop umbilical and dental anomalies. We suggest that the psychomotor retardation is a clinical manifestation associated with a deletion of multiple contiguous genes in the 6p terminus and that this phenomenon is similar to the 6p25 deletion syndrome. Understanding the relationship between genetic lesions and the spectrum of extraocular findings in patients with Axenfeld-Rieger anomalies may lead to better clinical management.

Identification of complex chromosome 18 rearrangements by FISH and array CGH in two patients with apparent isochromosome 18q

Identification of complex chromosome 18 rearrangements by FISH and array CGH in two patients with apparent isochromosome 18q

A de novo marker chromosome derived from 9p in a patient with 9p partial duplication syndrome and autism features: genotype-phenotype correlation

BackgroundPrevious studies focusing on candidate genes and chromosomal regions identified several copy number variations (CNVs) associated with increased risk of autism or autism spectrum disorders (ASD).Case PresentationWe describe a 17-year-old girl with autism, severe mental retardation, epilepsy, and partial 9p duplication syndrome features in whom GTG-banded chromosome analysis revealed a female karyotype with a marker chromosome in 69% of analyzed metaphases. Array CGH analysis showed that the marker chromosome originated from 9p24.3 to 9p13.1 with a gain of 38.9 Mb. This mosaic 9p duplication was detected only in the proband and not in the parents, her four unaffected siblings, or 258 ethnic controls. Apart from the marker chromosome, no other copy number variations (CNVs) were detected in the patient or her family. Detailed analysis of the duplicated region revealed: i) an area extending from 9p22.3 to 9p22.2 that was previously identified as a critical region for the 9p duplication syndrome; ii) a region extending from 9p22.1 to 9p13.1 that was previously reported to be duplicated in a normal individual; and iii) a potential ASD locus extending from 9p24.3 to 9p23. The ASD candidate locus contained 34 genes that may contribute to the autistic features in this patient.ConclusionWe identified a potential ASD locus (9p24.3 to 9p23) that may encompass gene(s) contributing to autism or ASD.

Identical cryptic partial monosomy 20pter and trisomy 20qter in three adult siblings due to a large maternal pericentric inversion: Detection by MLPA and breakpoint mapping by SNP array analysis

Genotypic and phenotypic data are presented on three adult siblings with mild to moderate mental retardation and mild dysmorphic features. All three siblings showed a chromosome 20 gain at the q-telomere and loss at the p-telomere in routine subtelomeric MLPA screening. Analysis of GTG-banded chromosomes did not detect any abnormalities, but subtelomeric fluorescent in situ hybridization (FISH) confirmed cryptic partial monosomy of chromosome region 20p13 --> 20pter and cryptic partial trisomy of chromosome region 20q13.33 --> 20qter. Furthermore, FISH analysis in the mother showed a cryptic inv(20)(p13q13.33). This explained the cytogenetic mechanism underlying the chromosomal imbalance in the three children, that is, the meiotic formation of a recombinant chromosome 20 due to crossing-over in the inverted segment. All three children thus carried a rec(20)dup(20q)inv(20)(p13q13.33)mat chromosome. SNP array analysis enabled rapid and detailed imbalance sizing and showed a 1.06 Mb loss in 20p13 and a 2.51 Mb gain in 20q13.33, comprising 21 and 78 genes, respectively. The maternal inversion is the largest described thus far for chromosome 20, comprising 94.4% of its length. Such large inversions result in a particularly high risk for live-born unbalanced offspring because the partial monosomy and trisomy segments are small. Moreover, the inversion size is directly related to the percentage of unbalanced gametes due to high crossing-over change within the inverted segment. The fact that all three children carry an identical chromosomal rearrangement has consequences for genetic counseling for carriers of large pericentric inversions, as the recurrence risk is very high.

Interphase FISH in plasma cell dyscrasia: increase in abnormality detection with plasma cell enrichment

Historically, cytogenetic studies of plasma cell neoplasms have been hampered by the fact that terminally differentiated plasma cells do not proliferate well in vitro. Although the use of interphase FISH (iFISH) has greatly improved the ability to detect cytogenetic abnormalities, cases with low numbers of neoplastic cells often do not demonstrate abnormalities. Using a four-assay, nine-probe iFISH panel, we compared the abnormality detection rate for overnight unstimulated bone marrow cultures (ONC) to that for plasma-cell enriched fractions obtained with use of CD138-coated immunomagnetic beads (PCE). In the ONC, an abnormality was detected in 11 of 29 cases (38%); in the PCE, an abnormality was detected in 30 of 33 cases (91%). For 28 cases in which iFISH results from ONC were compared directly with PCE samples, the overall abnormality rate was 36% for ONC and 89% for PCE ( P < 0.01). The conventional GTG-banded chromosome analysis revealed only 2 of 34 cases with an abnormal karyotype (6%); both cases were hyperdiploid. We conclude that the plasma cell enrichment step for iFISH should be incorporated into the routine cytogenetic work-up for all patients with plasma cell neoplasms.

Prenatal identification of a marker chromosome 16 by chromosome microdissection and reverse FISH

Prenatal cytogenetic analysis of cultured amniocytes was performed after an increased foetal nuchal translucency thickness was detected by ultrasound in week 17 of a pregnancy. Analysis of GTG-banded chromosomes showed a small marker chromosome in six of the 12 colonies analysed. The supernumerary abnormal chromosome appeared to be positive with DA/DAPI staining and C-banding. The parents' karyotypes were normal. Using microFISH and FISH with band-specific probes, we found the marker appeared to be derived from chromosome region (16)(p13.1→q12.2). Accurate identification of the marker chromosome was important for prenatal counselling: the marker chromosome contained euchromatic sequences, the foetus was carrying mosaic trisomy 16, and based on the literature the prognosis for the foetus was unfavourable and the pregnancy was terminated.

Familial insertion (3;5)(q25.3;q22.1q31.3) with deletion or duplication of chromosome region 5q22.1-5q31.3 in ten unbalanced carriers.

We report on the clinical and cytogenetic data of a large family with an unbalanced insertion translocation (3;5)(q25.3;q22.1q31.3). Analysis of GTG-banded chromosomes demonstrated that unbalanced inheritance of a parental insertion translocation caused either a partial deletion or duplication 5q in this family. The derivative chromosomes were characterized further using microdissection and FISH with band-specific probes. The clinical picture of the proband with a partial deletion of chromosome 5 was characterized by moderate psychomotor retardation, mild facial dysmorphism, cleft palate, and single transverse crease. The family members with a partial duplication of chromosome 5 were borderline intelligent, had mild facial dysmorphism, a cardiac anomaly, and a high-pitched voice. The unbalanced carriers were compared with patients reported in the literature with a duplication or deletion of chromosome region 5q22.1 --> 5q31.3.

Duplication of chromosome region 8p23.1 ? p23.3: A benign variant?

Chromosome analysis was performed in a 34-year-old man who was phenotypically normal except for oligoasthenozoospermia. In this patient, analysis of GTG-banded chromosomes showed in one chromosome 8 additional chromosomal material of unknown origin. To characterize the aberrant chromosome more precisely, a paint specific for chromosome region 8pter-->8p23.1 was generated by microdissection and degenerated oligonucleotide primed-polymerase chain reaction (DOP-PCR) and used as fluorescence in situ hybridization (FISH) paint. After reverse painting, hybridization signals were only found on the short arm of the two chromosomes 8, with an enlarged signal on the derivative chromosome 8. The duplication was characterized further with band-specific FISH probes. We concluded that (part of) chromosome region 8p23.1-->p23.3 was duplicated. Chromosome analysis of the parents showed that the dup(8) was of maternal origin and that the fertile brother of the index patient also was a carrier of the chromosome aberration. There was no history of miscarriages. We suggest that duplication of region 8p23.1-->p23.3 can be regarded as euchromatic variant or duplication with no phenotypic effect.

Identification of a marker chromosome as inv dup(15) by molecular analysis

The origin of an extra marker chromosome in a patient with mental retardation and intractable epilepsy was ascertained by DNA analysis. Gene dose and restriction fragment length polymorphism (RFLP) studies of D15S9 proved that the patient was tetrasomic for the gene and that the extra chromosome was of maternal origin. On the basis of the molecular findings, further detailed GTG-banded chromosome analysis interpreted the marker chromosome as inv dup(15)(pter----q14::q14----pter). The clinical manifestations of the patient are consistent with those of the patients previously described.