Abstract
B‐cell precursor acute lymphoblastic leukemia (BCP‐ALL) can be classified into subtypes according to the genetic aberrations they display. For instance, the translocation t(12;21)(p13;q22), representing the ETV6‐RUNX1 fusion gene (ER), is present in a quarter of BCP‐ALL cases. However, around 10% of the cases lack classifying chromosomal abnormalities (B‐other). In pediatric ER BCP‐ALL, rearrangement mediated by RAG (recombination‐activating genes) has been proposed as the predominant driver of oncogenic rearrangement. Herein we analyzed almost 1600 pediatric BCP‐ALL samples to determine which subtypes express RAG. We demonstrate that RAG1 mRNA levels are especially high in the ETV6‐RUNX1 (ER) subtype and in a subset of B‐other samples. We also define 31 genes that are co‐expressed with RAG1 (RAG1‐signature) in the ER subtype, a signature that also identifies this subset of B‐other samples. Moreover, this subset also shares leukemia and pro‐B gene expression signatures as well as high levels of the ETV6 target genes (BIRC7, WBP1L, CLIC5, ANGPTL2) with the ER subtype, indicating that these B‐other cases are the recently identified ER‐like subtype. We validated our results in a cohort where ER‐like has been defined, which confirmed expression of the RAG1‐signature in this recently described subtype. Taken together, our results demonstrate that the RAG1‐signature identifies the ER‐like subtype. As there are no definitive genetic markers to identify this novel subtype, the RAG1‐signature represents a means to screen for this leukemia in children.
Highlights
Acquired chromosomal aberrations have been linked to the overall survival of patients with B-cell precursor acute lymphoblastic leukemia (BCP-ALL), which is the most common cancer in children.[1]
We have previously shown that the components of the pre- B-cell antigen receptor (BCR) complex, assembled from Ig heavy chain and surrogate light chain, are differentially expressed in the ETV6-RUNX1 and TCF3-PBX1 B-cell precursors (BCP)-ALL subtypes.[18]
To determine the expression pattern of RAG1 and RAG2 that regulate Ig gene rearrangements, we first analyzed the expression of the RAG1 and RAG2 genes in the microarray dataset DS1-M that was used in the aforementioned study, which includes 127 BCP-A LL samples (Table 1, Table S1)
Summary
This work has been supported by grants from Barncancerfonden (TJ2016-0007, TJ2019-0098, PR2018-0170), Cancerfonden (CAN2016/0668, CAN2019/0464PG), Swedish Research Council (2018-0 3128), AG Fond (FB 18-2 2, FB19-66), IngaBritt och Arne Lundbergs Forskning Stiftelse, Stiftelsen Wilhelm och Martina Lundgrens Vetenskap, Adlerbertska forskningsstiftelsen.
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