A Dedicated System Accounting for Specific Germline/Somatic Genomic Constellations Is Essential to Predict Outcomes in DDX41-Mutant Myeloid Neoplasia

Background: Inherited DDX41 mutations are found in 5-10% of myeloid neoplasia (MN), accounting for 80% of the currently known etiologic fraction of germline predisposition to MN. Existing evidence separates DDX41-mutant MN in a distinct entity because of its clinical-molecular characteristics: male...

Full description

Saved in:
Bibliographic Details
Published in:Blood 2024-11, Vol.144 (Supplement 1), p.1332-1332
Main Authors: Gurnari, Carmelo, Makishima, Hideki, Durmaz, Arda, Attardi, Enrico, Saiki, Ryunosuke, Bataller, Alex, Mendes Sapinho, Guilherme, Gondek, Lukasz P., Nannya, Yasuhito, Best, Steve, Krishnamurthy, Pramila, Kong, Kar Lok, Atsuta, Yoshiko, Kasahara, Senji, Ohyashiki, Kazuma, Miyazaki, Yasushi, Kanemura, Nobuhiro, Hiramoto, Nobuhiro, Awada, Hussein, Visconte, Valeria, DiNardo, Courtney D., Voso, Maria Teresa, DeZern, Amy E., Garcia-Manero, Guillermo, Kulasekararaj, Austin G., Maciejewski, Jaroslaw, Ogawa, Seishi
Format: Article
Language:English
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Background: Inherited DDX41 mutations are found in 5-10% of myeloid neoplasia (MN), accounting for 80% of the currently known etiologic fraction of germline predisposition to MN. Existing evidence separates DDX41-mutant MN in a distinct entity because of its clinical-molecular characteristics: male bias, late onset, defiance of general mechanisms of MN ontogenesis, and unique outcomes. Secondary somatic DDX41 mutations (chiefly R525H) constitute the molecular events preluding MN progression in almost half of the cases, and no co-mutational signature seems to impact on disease biology, nor on survival outcomes (including TP53 biallelic inactivation). When compared to wild-type (WT) counterparts, DDX41-mutants show better outcome, but it is unclear how DDX41 mutational constellations may influence disease trajectories. To address this gap in knowledge, we tested the new 2022 MN diagnostic/prognostic schemes and generated a risk scoring system accounting for the diverse DDX41 mutational configurations. Methods: We accrued a total of 431 MN patients with DDX41 mutations leveraging a global effort across 6 academic centers, and a cohort of 2282 DDX41 WT MN for relevant comparisons. Results: DDX41-mutant patients had a median age of 69 years (IQR 61-75) at MN diagnosis (MDS=239, AML= 192) with a strong male predominance (3.5 M:F ratio). The majority harbored a classic biallelic germline/somatic constellation (54%, of whom 64% had the canonical R525H), 35% carried a single DDX41 germline mutation, and only 11% had one somatic variant alone. Diagnostic re-classification from 2016 to 2022 WHO schemes showed an overall shift of categories in 14.9% and 29.7%, for DDX41-mutant MDS and AML, respectively. These changes were largely substantiated by the new categories “MDS with biallelic TP53 inactivation”, and “hypoplastic MDS” (absent in the ICC), and the specific genomic signature of AML “myelodysplasia related”. In MDS, the overall shift from IPSS-R to IPSS-M was 43%, with 12% up- and 31% down-staged. Pairwise Log-Rank tests across IPSS-R/M risk categories resulted in non-significant survival differences in most subgroups. Conversely, the same analysis in the WT cohort led to a significant separation of distinct prognostic categories. In AML, the overall shift from ELN17 to ELN22 was 15%, entirely due to the upgrade of cases from ELN17 intermediate to ELN22 adverse risk category. In analogy to MDS, pairwise Log-Rank tests across ELN17/22 risk categories resulted in n
ISSN:0006-4971
1528-0020
DOI:10.1182/blood-2024-194024