# Optical Genome Mapping Enhances Structural Variant Detection and Refines Risk Stratification in Chronic Lymphocytic Leukemia

**Authors:** Soma Roy Chakraborty, Michelle A. Bickford, Narcisa A. Smuliac, Kyle A. Tonseth, Jing Bao, Farzana Murad, Irma G. Domínguez Vigil, Heather B. Steinmetz, Lauren M. Wainman, Parth Shah, Elizabeth M. Bengtson, Swaroopa PonnamReddy, Gabriella A. Harmon, Liam L. Donnelly, Laura J. Tafe, Jeremiah X. Karrs, Prabhjot Kaur, Wahab A. Khan

PMC · DOI: 10.3390/genes17010106 · 2026-01-19

## TL;DR

Optical genome mapping improves detection of genetic changes in chronic lymphocytic leukemia and helps better predict patient outcomes.

## Contribution

OGM reveals structural variants and complex genomic profiles in CLL that standard tests miss, enhancing risk stratification.

## Key findings

- OGM detected structural variants in 82% of CLL patients.
- OGM identified deletions and translocations not captured by traditional FISH panels.
- Combining OGM with NGS improved genomic risk classification in CLL.

## Abstract

Background: Optical genome mapping (OGM) detects genome-wide structural variants (SVs), including balanced rearrangements and complex copy-number alterations beyond standard-of-care cytogenomic assays. In chronic lymphocytic leukemia (CLL), cytogenetic and genomic risk stratification is traditionally based on fluorescence in situ hybridization (FISH), karyotyping, targeted next-generation sequencing (NGS), and immunogenetic assessment of immunoglobulin heavy chain variable region (IGHV) somatic hypermutation status, each of which interrogates only a limited aspect of disease biology. Methods: We retrospectively evaluated fifty patients with CLL using OGM and integrated these findings with cytogenomics, targeted NGS, IGHV mutational status, and clinical time-to-first-treatment (TTFT) data. Structural variants were detected using OGM and pathogenic NGS variants were derived from a clinical heme malignancy panel. Clinical outcomes were extracted from the electronic medical record. Results: OGM identified reportable structural variants in 82% (41/50) of cases. The most frequent abnormality was del(13q), observed in 29/50 (58%) and comprising 73% (29/40) of all OGM-detected deletions with pathologic significance. Among these, 12/29 (42%) represented large RB1-spanning deletions, while 17/29 (58%) were focal deletions restricted to the miR15a/miR16-1 minimal region, mapping to the non-coding host gene DLEU2. Co-occurrence of adverse lesions, including deletion 11q/ATM, BIRC3 loss, trisomy 12, and deletion 17p/TP53, were recurrent and strongly associated with shorter TTFT. OGM also uncovered multiple cryptic rearrangements involving chromosomal loci that are not represented in the canonical CLL FISH probe panel, including IGL::CCND1, IGH::BCL2, IGH::BCL11A, IGH::BCL3, and multi-chromosomal copy-number complexity. IGHV data were available in 37/50 (74%) of patients; IGHV-unmutated status frequently co-segregated with OGM-defined high-risk profiles (del(11q), del(17p), trisomy 12 with secondary hits, and complex genomes whereas mutated IGHV predominated in OGM-negative or structurally simple del(13q) cases and aligned with indolent TTFT. Integration of OGM with NGS further improved genomic risk classification, particularly in cases with discordant or inconclusive routine testing. Conclusions: OGM provides a comprehensive, genome-wide view of structural variation in CLL, resolving deletion architecture, identifying cryptic translocations, and defining complex multi-hit genomic profiles that tracked closely with clinical behavior. Combining OGM and NGS analysis refined risk stratification beyond standard FISH panels and supports more precise, individualized management strategies in CLL. Prospective studies are warranted to evaluate the clinical utility of OGM-guided genomic profiling in contemporary treatment paradigms.

## Linked entities

- **Genes:** RB1 (RB transcriptional corepressor 1) [NCBI Gene 5925], DLEU2 (deleted in lymphocytic leukemia 2) [NCBI Gene 8847], ATM (ATM serine/threonine kinase) [NCBI Gene 472], BIRC3 (baculoviral IAP repeat containing 3) [NCBI Gene 330], TP53 (tumor protein p53) [NCBI Gene 7157], CCND1 (cyclin D1) [NCBI Gene 595], BCL2 (BCL2 apoptosis regulator) [NCBI Gene 596], BCL11A (BCL11 transcription factor A) [NCBI Gene 53335], BCL3 (BCL3 transcription coactivator) [NCBI Gene 602]
- **Diseases:** chronic lymphocytic leukemia (MONDO:0004948), CLL (MONDO:0004948)

## Full-text entities

- **Genes:** RB1 (RB transcriptional corepressor 1) [NCBI Gene 5925] {aka OSRC, PPP1R130, RB, p105-Rb, p110-RB1, pRb}, ATM (ATM serine/threonine kinase) [NCBI Gene 472] {aka AT1, ATA, ATC, ATD, ATDC, ATE}, MIR15A (microRNA 15a) [NCBI Gene 406948] {aka MIRN15A, hsa-mir-15a, miRNA15A, mir-15a}, DLEU2 (deleted in lymphocytic leukemia 2) [NCBI Gene 8847] {aka ALT1, BCMSUN, DLB2, LEU2, LINC00022, MIR15AHG}, MIR16-1 (microRNA 16-1) [NCBI Gene 406950] {aka MIRN16-1, miRNA16-1, mir-16-1}, TP53 (tumor protein p53) [NCBI Gene 7157] {aka BCC7, BMFS5, LFS1, P53, TRP53}, IGHV3OR16-17 (immunoglobulin heavy variable 3/OR16-17 (non-functional)) [NCBI Gene 390714], BIRC3 (baculoviral IAP repeat containing 3) [NCBI Gene 330] {aka AIP1, API2, CIAP2, HAIP1, HIAP1, IAP-1}
- **Diseases:** heme malignancy (MESH:D009369), OGM (MESH:D042822), CLL (MESH:D015451), TTFT (MESH:D000377)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12840957/full.md

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Source: https://tomesphere.com/paper/PMC12840957