Next generation cytogenetics: genome-imaging enables comprehensive structural variant detection for 100 constitutional chromosomal aberrations in 85 samples

Abstract

Chromosomal aberrations and structural variations are a major cause of human genetic diseases. Their detection in clinical routine still relies on standard cytogenetics, karyotyping and CNV-microarrays, in spite of the low resolution of the first one and the inability to detect neither balanced SVs nor to provide the genomic localization or the orientation of duplicated segments, of the latter. We here investigated the clinical utility of high resolution optical mapping by genome imaging for patients carrying known chromosomal aberrations in a context of constitutional conditions.

For 85 samples, ultra-high molecular weight gDNA was isolated either from blood or cultured cells. After labeling, DNA was processed and imaged on the Saphyr instrument (Bionano Genomics). A de novo genome assembly was performed followed by SV and CNV calling and annotation. Results were compared to known aberrations from standard-of-care tests (karyotype, FISH and/or CNV-microarray).

In total, we analyzed 100 chromosomal aberrations including 7 aneuploidies, 35 translocations, 6 inversions, 2 insertions, 39 copy number variations (20 deletions and 19 duplications), 6 isochromosomes, 1 ring chromosome and 4 complex rearrangements. High resolution optical mapping reached 100% concordance compared to standard assays for all aberrations with non-centromeric breakpoints.

Our study demonstrates the ability of high resolution optical mapping to detect almost all types of chromosomal aberrations within the spectrum of karyotype, FISH and CNV-microarray. These results highlight its potential to replace these techniques, and provide a cost-effective and easy-to-use technique that would allow for comprehensive detection of chromosomal aberrations.