MYC‐driven inhibition of the glutamate‐cysteine ligase promotes glutathione depletion in liver cancer

How MYC reprograms metabolism in primary tumors remains poorly understood. Using integrated gene expression and metabolite profiling, we identify six pathways that are coordinately deregulated in primary MYC‐driven liver tumors: glutathione metabolism; glycine, serine, and threonine metabolism; aminoacyl‐tRNA biosynthesis; cysteine and methionine metabolism; ABC transporters; and mineral absorption. We then focus our attention on glutathione (GSH) and glutathione disulfide (GSSG), as they are markedly decreased in MYC‐driven tumors. We find that fewer glutamine‐derived carbons are incorporated into GSH in tumor tissue relative to non‐tumor tissue. Expression of GCLC, the rate‐limiting enzyme of GSH synthesis, is attenuated by the MYC‐induced microRNA miR‐18a. Inhibition of miR‐18a in vivo leads to increased GCLC protein expression and GSH abundance in tumor tissue. Finally, MYC‐driven liver tumors exhibit increased sensitivity to acute oxidative stress. In summary, MYC‐dependent attenuation of GCLC by miR‐18a contributes to GSH depletion in vivo, and low GSH corresponds with increased sensitivity to oxidative stress in tumors. Our results identify new metabolic pathways deregulated in primary MYC tumors and implicate a role for MYC in regulating a major antioxidant pathway downstream of glutamine.     

AMPK promotes survival of c‐Myc‐positive melanoma cells by suppressing oxidative stress

Although c‐Myc is essential for melanocyte development, its role in cutaneous melanoma, the most aggressive skin cancer, is only partly understood. Here we used the Nras^Q61KINK4a^?/? mouse melanoma model to show that c‐Myc is essential for tumor initiation, maintenance, and metastasis. c‐Myc‐expressing melanoma cells were preferentially found at metastatic sites, correlated with increased tumor aggressiveness and high tumor initiation potential. Abrogation of c‐Myc caused apoptosis in primary murine and human melanoma cells. Mechanistically, c‐Myc‐positive melanoma cells activated and became dependent on the metabolic energy sensor AMP‐activated protein kinase (AMPK), a metabolic checkpoint kinase that plays an important role in energy and redox homeostasis under stress conditions. AMPK pathway inhibition caused apoptosis of c‐Myc‐expressing melanoma cells, while AMPK activation protected against cell death of c‐Myc‐depleted melanoma cells through suppression of oxidative stress. Furthermore, TCGA database analysis of early‐stage human melanoma samples revealed an inverse correlation between C‐MYC and patient survival, suggesting that C‐MYC expression levels could serve as a prognostic marker for early‐stage disease.     

The regulatory role of c‐MYC on HDAC2 and PcG expression in human multipotent stem cells

Myelocytomatosis oncogene (c‐MYC) is a well‐known nuclear oncoprotein having multiple functions in cell proliferation, apoptosis and cellular transformation. Chromosomal modification is also important to the differentiation and growth of stem cells. Histone deacethylase (HDAC) and polycomb group (PcG) family genes are well‐known chromosomal modification genes. The aim of this study was to elucidate the role of c‐MYC in the expression of chromosomal modification via the HDAC family genes in human mesenchymal stem cells (hMSCs). To achieve this goal, c‐MYC expression was modified by gene knockdown and overexpression via lentivirus vector. Using the modified c‐MYC expression, our study was focused on cell proliferation, differentiation and cell cycle. Furthermore, the relationship of c‐MYC with HDAC2 and PcG genes was also examined. The cell proliferation and differentiation were checked and shown to be dramatically decreased in c‐MYC knocked‐down human umbilical cord blood‐derived MSCs, whereas they were increased in c‐MYC overexpressing cells. Similarly, RT‐PCR and Western blotting results revealed that HDAC2 expression was decreased in c‐MYC knocked‐down and increased in c‐MYC overexpressing hMSCs. Database indicates presence of c‐MYC binding motif in HDAC2 promoter region, which was confirmed by chromatin immunoprecipitation assay. The influence of c‐MYC and HDAC2 on PcG expression was confirmed. This might indicate the regulatory role of c‐MYC over HDAC2 and PcG genes. c‐MYCs’ regulatory role over HDAC2 was also confirmed in human adipose tissue‐derived MSCs and bone‐marrow derived MSCs. From this finding, it can be concluded that c‐MYC plays a vital role in cell proliferation and differentiation via chromosomal modification.     

The c‐MYC‐ABCB5 axis plays a pivotal role in 5‐fluorouracil resistance in human colon cancer cells

c‐MYC overexpression is frequently observed in various cancers including colon cancer and regulates many biological activities such as aberrant cell proliferation, apoptosis, genomic instability, immortalization and drug resistance. However, the mechanism by which c‐MYC confers drug resistance remains to be fully elucidated. In this study, we found that the c‐MYC expression level in primary colorectal cancer tissues correlated with the recurrence rate following 5‐fluorouracil (5‐FU)‐based adjuvant chemotherapy. Supporting this finding, overexpression of exogenous c‐MYC increased the survival rate following 5‐FU treatment in human colon cancer cells, and knockdown of endogenous c‐MYC decreased it. Furthermore, c‐MYC knockdown decreased the expression level of ABCB5, which is involved in 5‐FU resistance. Using a chromatin immunoprecipitation assay, we found that c‐MYC bound to the ABCB5 promoter region. c‐MYC inhibitor (10058‐F4) treatment inhibited c‐MYC binding to the ABCB5 promoter, leading to a decrease in ABCB5 expression level. ABCB5 knockdown decreased the survival rate following 5‐FU treatment as expected, and the ABCB5 expression level was increased in 5‐FU‐resistant human colon cancer cells. Finally, using a human colon cancer xenograft murine model, we found that the combined 5‐FU and 10058‐F4 treatment significantly decreased tumorigenicity in nude mice compared with 5‐FU or 10058‐F4 treatment alone. 10058‐F4 treatment decreased the ABCB5 expression level in the presence or absence of 5‐FU. In contrast, 5‐FU treatment alone increased the ABCB5 expression level. Taken together, these results suggest that c‐MYC confers resistance to 5‐FU through regulating ABCB5 expression in human colon cancer cells.     

Protein Kinase D3 promotes the cell proliferation by activating the ERK1/c‐MYC axis in breast cancer

Breast cancer is the second leading death cause of cancer death for all women. Previous study suggested that Protein Kinase D3 (PRKD3) was involved in breast cancer progression. In addition, the protein level of PRKD3 in triple‐negative breast adenocarcinoma was higher than that in normal breast tissue. However, the oncogenic mechanisms of PRKD3 in breast cancer is not fully investigated. Multi‐omic data showed that ERK1/c‐MYC axis was identified as a major pivot in PRKD3‐mediated downstream pathways. Our study provided the evidence to support that the PRKD3/ERK1/c‐MYC pathway play an important role in breast cancer progression. We found that knocking out PRKD3 by performing CRISPR/Cas9 genome engineering technology suppressed phosphorylation of both ERK1 and c‐MYC but did not down‐regulate ERK1/2 expression or phosphorylation of ERK2. The inhibition of ERK1 and c‐MYC phosphorylation further led to the lower protein level of c‐MYC and then reduced the expression of the c‐MYC target genes in breast cancer cells. We also found that loss of PRKD3 reduced the rate of the cell proliferation in vitro and tumour growth in vivo, whereas ectopic (over)expression of PRKD3, ERK1 or c‐MYC in the PRKD3‐knockout breast cells reverse the suppression of the cell proliferation and tumour growth. Collectively, our data strongly suggested that PRKD3 likely promote the cell proliferation in the breast cancer cells by activating ERK1‐c‐MYC axis.     

Transmembrane domain is crucial to the subcellular localization and function of Myc target 1

Deregulation of c‐MYC occurs in a variety of human cancers. Overexpression of c‐MYC promotes cell growth, proliferation, apoptosis, transformation and genomic instability. MYC target 1 (MYCT1) is a direct target gene of c‐MYC, and its murine homologue MT‐MC1 recapitulated multiple c‐Myc‐related phenotypes. However, the molecular mechanism of MYCT1 remains unclear. Here, we identified the transmembrane (TM) domain of MYCT1, not the nuclear localization sequence, is indispensable to the vesicle‐associated localization of MYCT1 protein in the cytoplasmic membrane vesicle. Overexpression of MYCT1, not MYCT1 (ΔTM), decreased cell viability under serum deprivation and increased tumour cell migration ability. We further identified CKAP4 interacted with MYCT1 and contributed to the function of MYCT1. In addition, we found that a mutation, A88D, which is observed in patient sample, changed the localization, and abolished the effect on cell viability and cell migration, suggesting that the TM domain is critical to MYCT1.