Malignant melanomas often harbor activating mutations in BRAF (V600E) or, less frequently, in NRAS (Q61R). Intriguingly, the same mutations have been detected at higher incidences in benign nevi, which are largely composed of senescent melanocytes. Overexpression of BRAFV600E or NRASQ61R in human melanocytes in vitro has been shown to induce senescence, although via different mechanisms. How oncogene-induced senescence is overcome during melanoma progression remains unclear. Here, we report that in the majority of analysed BRAFV600E- or NRASQ61R-expressing melanoma cells, C-MYC depletion induced different yet overlapping sets of senescence phenotypes that are characteristic of normal melanocytes undergoing senescence due to overexpression of BRAFV600E or NRASQ61R, respectively. These senescence phenotypes were p16INK4A- or p53-independent, however, several of them were suppressed by genetic or pharmacological inhibition of BRAFV600E or phosphoino-sitide 3-kinase pathways, including rapamycin-mediated inhibition of mTOR-raptor in NRASQ61R-expressing melanoma cells. Reciprocally, overexpression of C-MYC in normal melanocytes suppressed BRAFV600E-induced senescence more efficiently than NRASQ61R-induced senescence, which agrees with the generally higher rates of activating mutations in BRAF than NRAS gene in human cutaneous melanomas. Our data suggest that one of the major functions of C-MYC overexpression in melanoma progression is to continuous suppress BRAFV600E- or NRASQ61R-dependent senescence programs.
Summary Reactive oxygen species (ROS) activate NF-E2-related transcription factor 2 (Nrf2), a key transcriptional regulator driving antioxidant gene expression and protection from oxidant injury. Here we report that in response to elevation of intracellular ROS above a critical threshold, Nrf2 stimulates expression of transcription Kruppel-like factor 9 (Klf9), resulting in further Klf9-dependent increases in ROS and subsequent cell death. We demonstrated that Klf9 independently causes increased ROS levels in various types of cultured cells and in mouse tissues and is required for pathogenesis of bleomycin-induced pulmonary fibrosis in mice. Mechanistically, Klf9 binds to the promoters and alters the expression of several genes involved in the metabolism of ROS, including suppression of thioredoxin reductase 2, an enzyme participating in ROS clearance. Our data reveal an Nrf2-dependent feed-forward regulation of ROS and identify Klf9 as a novel ubiquitous regulator of oxidative stress and lung injury.
SUMMARY Melanoma is one of the most aggressive types of human cancers, and the mechanisms underlying melanoma invasive phenotype are not completely understood. Here, we report that expression of guanosine monophosphate reductase (GMPR), an enzyme involved in de novo biosynthesis of purine nucleotides, was down-regulated in invasive stages of human melanoma. Loss- and gain-of-function experiments revealed that GMPR down-regulates the amounts of several GTP-bound (active) RHO-GTPases, suppresses the ability of melanoma cells to form invadopodia, degrade extracellular matrix and invade in vitro and grow as tumor xenografts in vivo. Mechanistically, we demonstrated that GMPR partially depletes intracellular GTP pools. Pharmacological inhibition of de novo GTP biosynthesis suppressed, whereas addition of exogenous guanosine increased invasion of melanoma cells as well as cells from other cancer types. Our data identified GMPR as a melanoma invasion suppressor, and established a link between guanosine metabolism and RHO-GTPase-dependent melanoma cell invasion.
Bortezomib, a therapeutic agent for multiple myeloma (MM) and mantle cell lymphoma, suppresses proteosomal degradation leading to substantial changes in cellular transcriptional programs and ultimately resulting in apoptosis. Transcriptional regulators required for bortezomibinduced apoptosis in MM cells are largely unknown. Using gene expression profiling, we identified 36 transcription factors that displayed altered expression in MM cells treated with bortezomib. Analysis of a publically available database identified Kruppel-like family factor 9 (KLF9) as the only transcription factor with significantly higher basal expression in MM cells from patients who responded to bortezomib compared with nonresponders. We demonstrated that KLF9 in cultured MM cells was up-regulated by bortezomib; however, it was not through the induction of endoplasmic reticulum stress. Instead, KLF9 levels correlated with bortezomib-dependent inhibition of histone deacetylases (HDAC) and were increased by the HDAC inhibitor LBH589 (panobinostat). Furthermore, bortezomib induced binding of endogenous KLF9 to the promoter of the proapoptotic gene NOXA. Importantly, KLF9 knockdown impaired NOXA up-regulation and apoptosis caused by bortezomib, LBH589, or a combination of theses drugs, whereas KLF9 overexpression induced apoptosis that was partially NOXA-dependent. Our data identify KLF9 as a novel and potentially clinically relevant transcriptional regulator of drug-induced apoptosis in MM cells. (Blood. 2012;119(6):1450-1458) IntroductionMultiple myeloma (MM) is a plasma cell disorder that accounts for approximately 10% of all hematologic malignancies. 1,2 Although the introduction of novel agents in the past decade has increased median overall survival of myeloma patients from 30 months to 45-72 months, the disease still remains incurable. [3][4][5] One of these agents, bortezomib (Velcade, PS-341), significantly increased overall survival in patients with relapsed or refractory multiple myeloma when used as a single agent in comparison to high-dose dexamethasone, one of the standard therapies for this disease. [1][2][3][4][5] Bortezomib acts via inhibition of proteasome-mediated protein degradation, ultimately causing death in cells from many types of malignancies, including MM cells. [3][4][5] Bortezomib apoptosisinducing activity has been attributed in part to the alterations in the expression of several BCL2 family proteins, 6 among which the BH3-only protein NOXA appears to play an important role. [7][8][9] NOXA triggers apoptosis by binding to the prosurvival molecule MCL1, thus preventing it from sequestering proteins BAX, BAK and BIM, which are all critical inducers of apoptosis. [9][10][11][12] It has been reported that bortezomib increases NOXA protein levels by suppressing its proteosomal degradation 8 and by transcriptional activation of its gene. 8,13 Recently, several transcription factors including C-MYC, 13,14 ATF3, 15 ATF4, 15,16 and p53 14 have been shown to functionally participate in bortezomib-induced death in cells ...
Malignant melanoma possesses one of the highest metastatic potentials among human cancers. Acquisition of invasive phenotypes is a prerequisite for melanoma metastases. Elucidation of the molecular mechanisms underlying melanoma invasion will greatly enhance the design of novel agents for melanoma therapeutic intervention. Here, we report that guanosine monophosphate synthase (GMPS), an enzyme required for the de novo biosynthesis of GMP, has a major role in invasion and tumorigenicity of cells derived from either BRAF V600E or NRAS Q61R human metastatic melanomas. Moreover, GMPS levels are increased in metastatic human melanoma specimens compared with primary melanomas arguing that GMPS is an attractive candidate for anti-melanoma therapy. Accordingly, for the first time we demonstrate that angustmycin A, a nucleoside-analog inhibitor of GMPS produced by Streptomyces hygroscopius efficiently suppresses melanoma cell invasion in vitro and tumorigenicity in immunocompromised mice. Our data identify GMPS as a powerful driver of melanoma cell invasion and warrant further investigation of angustmycin A as a novel anti-melanoma agent.
Melanoma progression is associated with increased invasion and, often, decreased levels of microphthalmia-associated transcription factor (MITF). Accordingly, downregulation of MITF induces invasion in melanoma cells, however little is known about the underlying mechanisms. Here, we report for the first time that depletion of MITF results in elevation of intracellular GTP levels and increased amounts of active (GTP-bound) RAC1, RHO-A and RHO-C. Concomitantly, MITF-depleted cells display larger number of invadopodia and increased invasion. We further demonstrate that the gene for guanosine monophosphate reductase (GMPR) is a direct MITF target, and that the partial repression of GMPR accounts mostly for the above phenotypes in MITF-depleted cells. Reciprocally, transactivation of GMPR is required for MITF-dependent suppression of melanoma cell invasion, tumorigenicity, and lung colonization. Moreover, loss of GMPR accompanies downregulation of MITF in vemurafenib-resistant BRAFV600E-melanoma cells and underlies the increased invasion in these cells. Our data uncover novel mechanisms linking MITF-dependent inhibition of invasion to suppression of guanylate metabolism.
The down-regulation of dominant oncogenes, including C-MYC, in tumor cells often leads to the induction of senescence via mechanisms that are not completely identified. In the current study, we demonstrate that MYC-depleted melanoma cells undergo extensive DNA damage that is caused by the underexpression of thymidylate synthase (TS) and ribonucleotide reductase (RR) and subsequent depletion of deoxyribonucleoside triphosphate pools. Simultaneous genetic inhibition of TS and RR in melanoma cells induced DNA damage and senescence phenotypes very similar to the ones caused by MYC-depletion. Reciprocally, overexpression of TS and RR in melanoma cells or addition of deoxyribo-nucleosides to culture media substantially inhibited DNA damage and senescence-associated phenotypes caused by C-MYC depletion. Our data demonstrate the essential role of TS and RR in C-MYC-dependent suppression of senescence in melanoma cells.
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