Fold-back mechanism originating inv-dup-del rearrangements in chromosomes 13 and 15.

IF 2.4 4区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Chromosome Research Pub Date : 2023-02-24 DOI:10.1007/s10577-023-09720-0

Bruna Burssed, Malú Zamariolli, Bianca Pereira Favilla, Vera Ayres Meloni, Eny Maria Goloni-Bertollo, Fernanda Teixeira Bellucco, Maria Isabel Melaragno

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引用次数: 1

Abstract

Intrachromosomal rearrangements involve a single chromosome and can be formed by several proposed mechanisms. We reported two patients with intrachromosomal duplications and deletions, whose rearrangements and breakpoints were characterized through karyotyping, chromosomal microarray, fluorescence in situ hybridization, whole-genome sequencing, and Sanger sequencing. Inverted duplications associated with terminal deletions, known as inv-dup-del rearrangements, were found in 13q and 15q in these patients. The presence of microhomology at the junction points led to the proposal of the Fold-back mechanism for their formation. The use of different high-resolution techniques allowed for a better characterization of the rearrangements, with Sanger sequencing of the junction points being essential to infer the mechanisms of formation as it revealed microhomologies that were missed by the previous techniques. A karyotype-phenotype correlation was also performed for the characterized rearrangements.

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13号和15号染色体中产生inv- up-del重排的折叠机制。

染色体内重排涉及单个染色体，可以通过几种提出的机制形成。我们报告了两例染色体内重复和缺失的患者，通过核型分析、染色体微阵列、荧光原位杂交、全基因组测序和Sanger测序对其重排和断点进行了表征。在这些患者的13q和15q中发现了与末端缺失相关的反向重复，称为inv-dup-del重排。在连接点上的微同源性导致了它们形成的折叠机制的提出。使用不同的高分辨率技术可以更好地表征重排，连接点的Sanger测序对于推断形成机制至关重要，因为它揭示了以前技术所遗漏的微同源性。核型-表型的相关性也进行了表征重排。

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来源期刊

Chromosome Research 生物-生化与分子生物学

CiteScore

4.70

自引率

3.80%

发文量

审稿时长

1 months

期刊介绍： Chromosome Research publishes manuscripts from work based on all organisms and encourages submissions in the following areas including, but not limited, to: · Chromosomes and their linkage to diseases; · Chromosome organization within the nucleus; · Chromatin biology (transcription, non-coding RNA, etc); · Chromosome structure, function and mechanics; · Chromosome and DNA repair; · Epigenetic chromosomal functions (centromeres, telomeres, replication, imprinting, dosage compensation, sex determination, chromosome remodeling); · Architectural/epigenomic organization of the genome; · Functional annotation of the genome; · Functional and comparative genomics in plants and animals; · Karyology studies that help resolve difficult taxonomic problems or that provide clues to fundamental mechanisms of genome and karyotype evolution in plants and animals; · Mitosis and Meiosis; · Cancer cytogenomics.