TPL2 enforces RAS-induced inflammatory signaling and is activated by point mutations
Paarth B. Dodhiawala, … , Andrea Wang-Gillam, Kian-Huat Lim
Paarth B. Dodhiawala, … , Andrea Wang-Gillam, Kian-Huat Lim
Published June 23, 2020
Citation Information: J Clin Invest. 2020;130(9):4771-4790. https://doi.org/10.1172/JCI137660.
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Research Article Inflammation Oncology

TPL2 enforces RAS-induced inflammatory signaling and is activated by point mutations

Abstract

NF-κB transcription factors, driven by the IRAK/IKK cascade, confer treatment resistance in pancreatic ductal adenocarcinoma (PDAC), a cancer characterized by near-universal KRAS mutation. Through reverse-phase protein array and RNA sequencing we discovered that IRAK4 also contributes substantially to MAPK activation in KRAS-mutant PDAC. IRAK4 ablation completely blocked RAS-induced transformation of human and murine cells. Mechanistically, expression of mutant KRAS stimulated an inflammatory, autocrine IL-1β signaling loop that activated IRAK4 and the MAPK pathway. Downstream of IRAK4, we uncovered TPL2 (also known as MAP3K8 or COT) as the essential kinase that propels both MAPK and NF-κB cascades. Inhibition of TPL2 blocked both MAPK and NF-κB signaling, and suppressed KRAS-mutant cell growth. To counter chemotherapy-induced genotoxic stress, PDAC cells upregulated TLR9, which activated prosurvival IRAK4/TPL2 signaling. Accordingly, a TPL2 inhibitor synergized with chemotherapy to curb PDAC growth in vivo. Finally, from TCGA we characterized 2 MAP3K8 point mutations that hyperactivate MAPK and NF-κB cascades by impeding TPL2 protein degradation. Cancer cell lines naturally harboring these MAP3K8 mutations are strikingly sensitive to TPL2 inhibition, underscoring the need to identify these potentially targetable mutations in patients. Overall, our study establishes TPL2 as a promising therapeutic target in RAS- and MAP3K8-mutant cancers and strongly prompts development of TPL2 inhibitors for preclinical and clinical studies.

Authors

Paarth B. Dodhiawala, Namrata Khurana, Daoxiang Zhang, Yi Cheng, Lin Li, Qing Wei, Kuljeet Seehra, Hongmei Jiang, Patrick M. Grierson, Andrea Wang-Gillam, Kian-Huat Lim

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Figure 2

IRAK4 is crucial for oncogenic RAS-driven MAPK signaling.

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IRAK4 is crucial for oncogenic RAS-driven MAPK signaling. (A) Linear fol...
(A) Linear fold-change for all targets evaluated by reverse-phase protein array (RPPA) performed on HPNE-KRASG12D overexpressing (OE) IRAK4 and treated with IRAK4i. Targets with fold-change >2 upon IRAK4 overexpression are identified. (B) Heatmap showing relative expression of ERK-regulated targets in RPPA shown in A. (C) Immunoblots of 293T cells transfected with AU1 epitope–tagged WT or kinase-dead IRAK4. (D) Heatmap depicting fold-change for MAPK-, RAS-, and cell growth–related Gene Ontology (GO) signatures upon Irak4 knockout (KO) and rescue (KO + Irak4WT) in murine KP2 cells. Comparisons are KO vs. WT and rescue vs. KO. Signatures significantly (P < 0.05) depleted (blue) or enriched (red) are marked with an asterisk (*). (E) Immunoblots of WT and Irak4-KO KP2 cells. (F and G) Gene set enrichment plot and normalized enrichment scores (NES), respectively, for signatures associated with oncogenic KRAS in WT, Irak4-KO, and rescue KP2 cells, compared as in D. “Hallmark” and “C6: Oncogenic Signatures” databases were used. Negative NES indicates downregulation and signatures significantly (P < 0.05) depleted (blue) or enriched (red) are marked with an asterisk (*). (H) Gene set enrichment plot for PDAC signature in Irak4-KO and -rescue KP2 cells. PDAC signature gene list is provided in Supplemental Table 3. Barcode plots under curves in F and H depict the enrichment clustering for individual genes in the respective gene signatures interrogated for KO vs. WT (top barcode) and rescue vs. KO (bottom barcode) cells. (I) Immunoblots of KP2 and KI cells treated with IRAK4i (PF06650833) or vehicle (V) for 24 hours in serum-free condition. (J) Immunoblots of PDAC cells treated with IRAK4i for 16 hours. (K) Immunoblots of HPNE-KRASG12D and 293T-KRASG12V cells treated with IRAK4i for 24 hours in serum-free media. For D and FH, RNA sequencing was performed on n = 2 independent samples for each condition.