RAB27B controls palmitoylation-dependent NRAS trafficking and signaling in myeloid leukemia
Jian-Gang Ren, … , Mark R. Philips, Wei Tong
Jian-Gang Ren, … , Mark R. Philips, Wei Tong
Published June 15, 2023
Citation Information: J Clin Invest. 2023;133(12):e165510. https://doi.org/10.1172/JCI165510.
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Research Article Cell biology Hematology

RAB27B controls palmitoylation-dependent NRAS trafficking and signaling in myeloid leukemia

Abstract

RAS mutations are among the most prevalent oncogenic drivers in cancers. RAS proteins propagate signals only when associated with cellular membranes as a consequence of lipid modifications that impact their trafficking. Here, we discovered that RAB27B, a RAB family small GTPase, controlled NRAS palmitoylation and trafficking to the plasma membrane, a localization required for activation. Our proteomic studies revealed RAB27B upregulation in CBL- or JAK2-mutated myeloid malignancies, and its expression correlated with poor prognosis in acute myeloid leukemias (AMLs). RAB27B depletion inhibited the growth of CBL-deficient or NRAS-mutant cell lines. Strikingly, Rab27b deficiency in mice abrogated mutant but not WT NRAS–mediated progenitor cell growth, ERK signaling, and NRAS palmitoylation. Further, Rab27b deficiency significantly reduced myelomonocytic leukemia development in vivo. Mechanistically, RAB27B interacted with ZDHHC9, a palmitoyl acyltransferase that modifies NRAS. By regulating palmitoylation, RAB27B controlled c-RAF/MEK/ERK signaling and affected leukemia development. Importantly, RAB27B depletion in primary human AMLs inhibited oncogenic NRAS signaling and leukemic growth. We further revealed a significant correlation between RAB27B expression and sensitivity to MEK inhibitors in AMLs. Thus, our studies presented a link between RAB proteins and fundamental aspects of RAS posttranslational modification and trafficking, highlighting future therapeutic strategies for RAS-driven cancers.

Authors

Jian-Gang Ren, Bowen Xing, Kaosheng Lv, Rachel A. O’Keefe, Mengfang Wu, Ruoxing Wang, Kaylyn M. Bauer, Arevik Ghazaryan, George M. Burslem, Jing Zhang, Ryan M. O’Connell, Vinodh Pillai, Elizabeth O. Hexner, Mark R. Philips, Wei Tong

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Figure 2

CBL depletion or inactivation enhances RAB27B gene transcription, and RAB27B expression correlates with poor survival in AML.

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CBL depletion or inactivation enhances RAB27B gene transcription, and RA...
(A) qRT-PCR to examine RAB27B and RAB27A mRNA levels in single or double knockout (DKO) of CBL and CBL-B compared with Ctrl TF-1 cells. (B) qRT-PCR to examine RAB27B and RAB27A mRNA levels in TF-1 cells stably expressing CBLC381A mutant or CBLWT compared with empty vector (EV). (C) qRT-PCR to examine RAB27B nascent and mature RNA level in TF-1 DKO cells compared with Ctrl cells. Two different pairs of primers were used to detect premRNA (designated as pre 1 and pre 2, depending on the primer set). Mature messenger RNA is labeled as mRNA. (D) RAB27B protein (left) and mRNA (right) levels in primary human PBMCs from healthy donors (C1–C3, n = 3) and patients with JAK2V617F+ MPN (n = 4) are shown. (E) RAB27B mRNA levels in BM CD34+ cells from healthy donors (n = 15) and patients with JAK2V617F+ MPN (n = 43) plotted using the expression data from GSE103176 (28). Each symbol indicates individual subject. (F) RAB27B expression level in patients with AML and healthy controls (GEPIA Cancer Database). (G and H) Kaplan-Meier plot of overall survival for patients with AML with low or high expression of RAB27B. UALCAN (G) top 25% or bottom 75% (low/medium) expression of RAB27B; CTGA database from BloodSpot (H) top 50% or bottom 50% expression of RAB27B. P values determined by log-rank t test are shown. In all relevant panels, data are represented as mean ± SD. 1-way ANOVA was used in panels A, B and D; Student’s 2-tailed t tests were used in Figure C and E; *P < 0.05; **P < 0.01; ***P < 0.001.