Abstract
Background: B cells are selected for an intermediate level of (pre-) B cell receptor (BCR) signaling strength: attenuation below minimum (e.g. non-functional BCR) or hyperactivation above maximum (e.g. autoreactive BCR) thresholds of signaling strength causes negative selection and cell death. About 25% of B cell acute lymphoblastic leukemia (ALL) is driven by oncogenic tyrosine kinases (e.g. BCR-ABL1 in Ph+ ALL), which mimics constitutively active pre-BCR signaling and defines the ALL subgroup with the worst clinical outcome. Currently more potent tyrosine kinase inhibitors (TKI) are developed for Ph+ ALL to suppress oncogenic signaling below a minimum threshold for survival. However Ph+ ALL cells invariably develop resistance against TKI. Here, we tested the hypothesis that targeted hyperactivation of oncogenic signaling above a maximum threshold will trigger B cell-inherent mechanisms of negative selection and selectively kill Ph+ALL cells.
Results: The Ph+ ALL cells don not express a functional pre-BCR and BCR-ABL1 oncogene mimics a constitutively active pre-BCR by phosphorylating SYK, LYN, BTK and PLCg2. An incremental increase of pre-BCR downstream signaling (ITAM or SYK overexpression) was indeed sufficient to induce cell death in Ph+ ALL. TKI-treatment, while designed to kill leukemia cells, seemingly paradoxically rescued Ph+ALL cells in this experimental setting.
Ph+ ALL cells differ from normal pre-B cells by expression of high levels of ITIM containing inhibitory receptors including PECAM1 (CD31), CD300A and LAIR1. Importantly, high expression levels of ITIM-receptors are predictive of poor outcome in two clinical trials. In the COG trial (P9906; n=207) for children high-risk ALL, mRNA levels of PECAM1, CD300A and LAIR1at diagnosis positively correlated with early minimal residual disease (MRD) findings on day 29 (p<0.0005), and negatively correlated with overall survival (OS) rate (p<0.02) or relapse free survival (RFS) rate (p<0.05). In the ECOG trial (E2993; n=215) for adults ALL, PECAM1 mRNA level negatively correlated with OS rate (p=0.0285).
Genetic studies revealed that Pecam1, Cd300a and Lair1 receptors are critical to calibrate pre-BCR signaling strength through recruitment of the inhibitory phosphatases Ptpn6 (SHP1) and Inpp5d (SHIP1). Deletion of Pecam1, Cd300a or Lair1 in Ph+ ALL cells caused increased ROS levels, G0/G1cell cycle arrest, decreased colony formation capacity and cellular senescence. Phosphorylation of pre-BCR downstream molecules (SYK, LYN, BTK and PLCg2) was increased after Lair1 deletion and this hyper-signaling could not be tolerated by Ph+ ALL cells. Lair1 deletion resulted in rapid leukemia regression and prolonged survival of recipient mice in a transplant experiment. Leukemia cell death caused by Lair1-deletion could be rescued by overexpression of the active inhibitory phosphatase Ptpn6 (CD8-SHP1) or Inpp5d (CD8-SHIP1). Genetic deletion of Ptpn6 and Inpp5d caused increased pre-BCR signaling and cell death in BCR-ABL1 ALL cells but not myeloid cells (normal and BCR-ABL1-transformed), which -unlike B cells- are not subject to negative selection of auto-reactive clones. Decreasing pre-BCR signaling by SYK inhibition rescued cell death after Ptpn6- or Inpp5d- deletion.
Blocking inhibitory receptors by using chimeric PECAM1, CD300A and LAIR1 receptor decoys inhibited proliferation and caused cell death in Ph+ ALL xenograft cells. More potently, a novel small molecule inhibitor of INPP5D (SHIP1) selectively killed Ph+ ALL xenograft cells through inducing hyper pre-BCR signaling, regardless of TKI resistance. We demonstrate that inhibitory phosphatase signaling represents a potential novel class of therapeutic targets for Ph+ALL.
Conclusions: These results indicated that inhibitory receptors and downstream phosphatases are critical regulators of pre-BCR signaling strength in Ph+ ALL, and identified ITIM-receptors and phosphatases as members of a potential novel class of therapeutic targets. The concept of pharmacological perturbance of oncogenic signaling equilibrium in leukemia cells by inhibition (e.g. TKI-treatment) or exaggeration of signaling strength (e.g. blockade of ITIM-receptors) may lead to the discovery of multiple additional therapeutic targets and broaden our repertoire of currently available therapeutic intervention.
No relevant conflicts of interest to declare.
Author notes
Asterisk with author names denotes non-ASH members.
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