De novo balanced reciprocal translocation mosaic t(1;3)(q42;q25) detected by prenatal genetic diagnosis: a fetus conceived using preimplantation genetic testing due to a t(12;14)(q22;q13) balanced paternal reciprocal translocation

Introduction De novo balanced reciprocal translocations mosaicism in fetus conceived using preimplantation genetic testing from a different balanced translocation carrier parent has been rarely reported. Methods Chromosomal microarray analysis, karyotype analysis and fluorescent in situ hybridization were performed to verify the type and heredity of the rearrangement. STR analysis was conducted to identify potential contamination and verify kinship. In addition, a local BLAST engine was performed to locate potentially homologous segments which might contribute to the translocation in breakpoints of chromosome. Results A rare de novo balanced reciprocal translocations mosaicism mos 46,XY,t(1;3)(q42;q25)[40]/46,XY[39] was diagnosed in a fetus conceived using preimplantation genetic testing due to a 46,XY,t(12;14)(q22;q13) balanced translocation carrier father through multiplatform genetic techniques. Two of the largest continuous high homology segments were identified in chromosomal band 1q42.12 and 3q25.2. At the 21-months follow up, infant has achieved all psychomotor development milestones as well as growth within the normal reference range. Conclusion We present a prenatal diagnosis of a rare de novo balanced reciprocal translocations mosaicism in a fetus who conceived by preimplantation genetic testing. The most reasonable driving mechanism was that a de novo mitotic error caused by nonallelic homologous recombination between 1q42.12 and 3q25.2 in a zygote within the first or early cell divisions, which results in a mosaic embryo with the variant present in a half proportion of cells.

Clear Cell Sarcoma of Tendon and Aponeuroses with Excessive Melanin Production – An Unusual Presentation

Clear cell sarcoma of tendons and aponeuroses also called as malignant melanoma of soft parts is a rare tumor of neural crest origin with 70% of them possessing balanced translocation t(12; 22). Approximately 50% of the tumor produces melanin which often shows focal pigmentation or needs special stains to demonstrate melanin. Production of excessive melanin by this tumor is very unusual and very few case reports are available in literature. We report a case of Clear cell sarcoma with excessive melanin production in a 50-year-old female patient involving the left popliteal fossa.

Marfan Syndrome Caused by Disruption of the FBN1 Gene due to A Reciprocal Chromosome Translocation

Marfan syndrome (MFS) is a hereditary connective tissue disease caused by heterozygous mutations in the fibrillin-1 gene (FBN1) located on chromosome 15q21.1. A complex chromosomal rearrangement leading to MFS has only been reported in one case so far. We report on a mother and daughter with marfanoid habitus and no pathogenic variant in the FBN1 gene after next generation sequencing (NGS) analysis, both showing a cytogenetically reciprocal balanced translocation between chromosomes 2 and 15. By means of fluorescence in situ hybridization of Bacterial artificial chromosome (BAC) clones from the breakpoint area on chromosome 15 the breakpoint was narrowed down to a region of approximately 110 kb in FBN1. With the help of optical genome mapping (OGM), the translocation breakpoints were further refined on chromosomes 2 and 15. Sequencing of the regions affected by the translocation identified the breakpoint of chromosome 2 as well as the breakpoint of chromosome 15 in the FBN1 gene leading to its disruption. To our knowledge, this is the first report of patients with typical clinical features of MFS showing a cytogenetically reciprocal translocation involving the FBN1 gene. Our case highlights the importance of structural genome variants as an underlying cause of monogenic diseases and the useful clinical application of OGM in the elucidation of structural variants.

Characterization of a Rare Mosaic Unbalanced Translocation of t(3;12) in a Patient With Neurodevelopmental Disorders

Background Unbalanced translocations may be de novo or inherited from one parent carrying the balanced form and are usually present in all cells. Mosaic unbalanced translocations are extremely rare with a highly variable phenotype depending on the tissue distribution and level of mosaicism. Mosaicism for structural chromosomal abnormalities is clinically challenging for diagnosis and counseling due to the limitation of technical platforms and complex mechanisms, respectively. Here we report a case with a tremendously rare maternally-derived mosaic unbalanced translocation of t(3;12), and we illustrate the unreported complicated mechanism using single nucleotide polymorphism (SNP) array, fluorescence in situ hybridization (FISH), and chromosome analyses. Case Presentation: An 18-year-old female with a history of microcephaly, pervasive developmental disorder, intellectual disability, sensory integration disorder, gastroparesis, and hypotonia presented to our genetics clinic. She had negative karyotype by parental report but no other genetic testing performed previously. SNP microarray analysis revealed a complex genotype including 8.4 Mb terminal mosaic duplication on chromosome 3 (3p26.3->3p26.1) with the distal 5.7 Mb involving two parental haplotypes and the proximal 2.7 Mb involving three parental haplotypes, and a 6.1 Mb terminal mosaic deletion on chromosome 12 (12p13.33->12p13.31) with no evidence for a second haplotype. Adjacent to the mosaic deletion is an interstitial mosaic copy-neutral region of homozygosity (1.9 Mb, 12p13.31). The mother of this individual was confirmed by chromosome analysis and FISH that she carries a balanced translocation, t(3;12)(p26.1;p13.31). Conclusion Taken together, the proband, when at the stage of a zygote, likely carried the derivative chromosome 12 from this translocation, and a postzygotic mitotic recombination event occurred between the normal paternal chromosome 12 and maternal derivative chromosome 12 to “correct” the partial 3p trisomy and partial deletion of 12p. To the best of our knowledge, it is the first time that a mechanism utilizing a combined cytogenetic and cytogenomic approach, and we believe it expands our knowledge of mosaic structural chromosomal disorders and provides new insight into clinical management and genetic counseling.

Highly precise breakpoint detection of chromosome balanced translocation in a Chronic Myelogenous Leukemia patient

Chronic Myelogenous Leukemia (CML) has a special phenomenon of chromosome translocation, which is called Philadelphia chromosome translocation. However, the detailed connection of this structure is troublesome and expensive to be identified. Low-coverage whole genome sequencing (LCWGS) could not only detect the chromosomal translocation which does not be known in advance, but also provide the breakpoint candidate small region (with an accuracy of ±200 bases). Importantly, the sequencing cost of LCWGS is about US$300. Then, with the Sanger DNA sequencing, the precise breakpoint can be determined at a single base level. In our project, with LCWGS, BCR and ABL1 are successfully identified and were disrupted at chr22:23,632,356 and chr9:133,590,450, respectively. Due to the reconnection after chromosome breakage, classical fusion gene (BCR-ABL1) was found in bone marrow and peripheral blood. The precise breakpoints were helpful to study the pathogenic mechanism of CML and could better guide the classification of CML subtypes. This LCWGS method is universal and can be used to detect all diseases related to chromosome variation, such as solid tumors, liquid tumors and birth defects.

Allelic and dosage effects of NHS in X-linked cataract and Nance–Horan syndrome: a family study and literature review

Nance–Horan syndrome (NHS) is a rare X-linked dominant disorder caused by mutation in the NHS gene on chromosome Xp22.13. (OMIM 302350). Classic NHS manifested in males is characterized by congenital cataracts, dental anomalies, dysmorphic facial features and occasionally intellectual disability. Females typically have a milder presentation. The majority of reported cases of NHS are the result of nonsense mutations and small deletions. Isolated X-linked congenital cataract is caused by non-recurrent rearrangement-associated aberrant NHS transcription. Classic NHS in females associated with gene disruption by balanced X-autosome translocation has been infrequently reported. We present a familial NHS associated with translocation t(X;19) (Xp22.13;q13.1). The proband, a 28-year-old female, presented with intellectual disability, dysmorphic features, short stature, primary amenorrhea, cleft palate, and horseshoe kidney, but no NHS phenotype. A karyotype and chromosome microarray analysis (CMA) revealed partial monosomy Xp/partial trisomy 19q with the breakpoint at Xp22.13 disrupting the NHS gene. Family history revealed congenital cataracts and glaucoma in the patient’s mother, and congenital cataracts in maternal half-sister and maternal grandmother. The same balanced translocation t(X;19) was subsequently identified in both the mother and maternal half-sister, and further clinical evaluation of the maternal half-sister made a diagnosis of NHS. This study describes the clinical implication of NHS gene disruption due to balanced X-autosome translocations as a unique mechanism causing Nance–Horan syndrome, refines dose effects of NHS on disease presentation and phenotype expressivity, and justifies consideration of karyotype and fluorescence in situ hybridization (FISH) analysis for female patients with familial NHS if single-gene analysis of NHS is negative.

A rare familial rearrangement of chromosomes 9 and 15 associated with intellectual disability: a clinical and molecular study

Background There are many reports on rearrangements occurring separately in the regions of chromosomes 9p and 15q affected in the case under study. 15q duplication syndrome is caused by the presence of at least one extra maternally derived copy of the Prader–Willi/Angelman critical region. Trisomy 9p is the fourth most frequent chromosome anomaly with a clinically recognizable syndrome often accompanied by intellectual disability. Here we report a new case of a patient with maternally derived unique complex sSMC resulting in partial trisomy of both chromosomes 9 and 15 associated with intellectual disability. Case presentation We characterise a supernumerary derivative chromosome 15: 47,XY,+der(15)t(9;15)(p21.2;q13.2), likely resulting from 3:1 malsegregation during maternal gametogenesis. Chromosomal analysis showed that a phenotypically normal mother is a carrier of balanced translocation t(9;15)(p21.1;q13.2). Her 7-year-old son showed signs of intellectual disability and a number of physical abnormalities including bilateral cryptorchidism and congenital megaureter. The child’s magnetic resonance imaging showed changes in brain volume and in structural and functional connectivity revealing phenotypic changes caused by the presence of the extra chromosome material, whereas the mother’s brain MRI was normal. Sequence analyses of the microdissected der(15) chromosome detected two breakpoint regions: HSA9:25,928,021-26,157,441 (9p21.2 band) and HSA15:30,552,104-30,765,905 (15q13.2 band). The breakpoint region on chromosome HSA9 is poor in genetic features with several areas of high homology with the breakpoint region on chromosome 15. The breakpoint region on HSA15 is located in the area of a large segmental duplication. Conclusions We discuss the case of these phenotypic and brain MRI features in light of reported signatures for 9p partial trisomy and 15 duplication syndromes and analyze how the genomic characteristics of the found breakpoint regions have contributed to the origin of the derivative chromosome. We recommend MRI for all patients with a developmental delay, especially in cases with identified rearrangements, to accumulate more information on brain phenotypes related to chromosomal syndromes.

Cytogenetic and molecular analysis of distal 4q duplication with distinctive phenotype using single-nucleotide polymorphism array

Aims There is little knowledge about partial trisomy 4q and the genotype–phenotype correlation. In this study, we presented the detail of two Chinese families with partial distal 4q duplication in an attempt to clarify the correlation between the genotype and the phenotype. Methods Two pedigrees with distal 4q duplication were enrolled in this study. Karyotype analysis and single-nucleotide polymorphism (SNP) array detection were performed for prenatal diagnosis. Fluorescence in situ hybridization analysis. (FISH) was conducted to verify the copy number variants. Results Two families with partial trisomy 4q were identified. The fetus in pedigree 1 exhibited multiple ultrasound anomalies including intrauterine growth restriction and an atrioventricular septal defect who had a duplication of 4q28.3-qter associate with 6p25.2-p25.3 deletion, which resulted from balanced translocation carried by his father t(4;6)(q28.3;p25.2). The fetus in pedigree 2 had a distal 4q28.3-qter duplication combined with monosomy of Xp21.3-p22.3, and the karyotype was described as 46,X,der(X)t(X;4)(p21.3;q28.3)mat, which originally inherited from the pregnant woman who exhibited a mild clinical phenotype limited to short stature. Conclusions In our study, we for the first time identified the partial trisomy 4q associate with 6p or Xp deletion. In addition, our finding further strengthens that mild clinical phenotype in 4q duplication case may be due to the spreading of X inactivation to the autosomal in derivation of chromosome X.

Application of Chromosome Microarray Analysis and Karyotype Analysis in Diagnostic Assessment of Abnormal Down's Syndrome Screening Results

Background: Although screening for fetal aneuploidy with the use of cell-free DNA obtained from maternal plasma is highly effective, biomarkers screening is in extensive use in economically underdeveloped areas and poor population. This study aims to explore the application value of chromosomal microarray analysis (CMA) and karyotype analysis in prenatal diagnosis for pregnant women with abnormal Down’s syndrome (DS) screening results.Methods: The study recruited 813 pregnant women with abnormal DS screening results from Chengdu Women’s and Children’s Central Hospital. They underwent amniocentesis to obtain fetal amniotic fluid for CMA and G-band karyotype analysis. An Affymetrix CytoScan 750 K Array chip was used for CMA analysis according to the manufacturer’s instructions.Results: In total, CMA identified 21/813 abnormal results, which was more efficient than karyotype analysis(10/813, P<0.001.) CMA is equivalent to traditional karyotype analysis for the prenatal diagnosis of aneuploidies. However, CMA identified 1.60% more copy number variants(CNVs) than karyotype analysis. These pathogenic/likely pathogenic(P/LP) CNVs ranged from 159Kb deletion to 3616Kb deletion. 53.8% of them were recurrent pathogenic CNVs associated with risk of neurodevelopmental disorders. CMA identified 7 variants of uncertain significance (VUS) results, including 6 microduplication and 1 microdeletion, with the size ranged from 840kb-1484kb. Karyotype analysis identified 2 mosaic sex chromosome aneuploidy, 2 balanced translocation and 1 mosaic balanced translocation, which could not be identified by CMA. Conclusions: Performing both CMA and karyotype analysis simultaneously is more beneficial to pregnant women with abnormal DS screening results.