Impact of hypoxia on the pathogenesis and therapy resistance in multiple myeloma

Impact of hypoxia on the pathogenesis and therapy resistance in multiple myeloma

Multiple myeloma (MM) is a refractory plasma cell tumor. In myeloma cells, the transcription factor IRF4, the master regulator of plasma cells, is aberrantly upregulated and plays an essential role in oncogenesis. IRF4 forms a positive feedback loop with MYC, leading to additional tumorigenic proper...

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Veröffentlicht in:Cancer science 2021-10, Vol.112 (10), p.3995-4004
Hauptverfasser: Ikeda, Sho, Tagawa, Hiroyuki
Format: Artikel
Sprache:eng
Schlagworte:
Anemia
Antigens
Apoptosis
Bone marrow
Cancer therapies
Cell cycle
Drug resistance
Feedback
Gene expression
Genotype & phenotype
HIF
Homeostasis
Hypoxia
Interferon regulatory factor 4
IRF4
Medical prognosis
Metabolism
Microenvironments
Multiple myeloma
MYC
Myc protein
Plasma
Plasma cells
Population
Proteins
Regulation
Remission
Review
Stem cells
Transcription factors
Tumorigenesis
Tumors
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description Multiple myeloma (MM) is a refractory plasma cell tumor. In myeloma cells, the transcription factor IRF4, the master regulator of plasma cells, is aberrantly upregulated and plays an essential role in oncogenesis. IRF4 forms a positive feedback loop with MYC, leading to additional tumorigenic properties. In recent years, molecular targeted therapies have contributed to a significant improvement in the prognosis of MM. Nevertheless, almost all patients experience disease progression, which is thought to be a result of treatment resistance induced by various elements of the bone marrow microenvironment. Among these, the hypoxic response, one of the key processes for cellular homeostasis, induces hypoxia‐adapted traits such as undifferentiation, altered metabolism, and dissemination, leading to drug resistance. These inductions are caused by ectopic gene expression changes mediated by the activation of hypoxia‐inducible factors (HIFs). By contrast, the expression levels of IRF4 and MYC are markedly reduced by hypoxic stress. Notably, an anti‐apoptotic capability is usually acquired under both normoxic and hypoxic conditions, but the mechanism is distinct. This fact strongly suggests that myeloma cells may survive by switching their dependent regulatory factors from IRF4 and MYC (normoxic bone marrow region) to HIF (hypoxic bone marrow microenvironment). Therefore, to achieve deep remission, combination therapeutic agents, which are complementarily effective against both IRF4‐MYC‐dominant and HIF‐dominated fractions, may become an important therapeutic strategy for MM. Under normoxic conditions, inactivation of HIF leads to the activation of IRF4‐MYC‐positive feedback. By contrast, under hypoxic conditions, HIF suppresses IRF4‐MYC and contributes to the occurrence of drug resistance. Gene expression fluctuates because of environmental factors, and different fractions must be killed at the same time in multiple myeloma.
doi_str_mv 10.1111/cas.15087
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source DOAJ Directory of Open Access Journals; Wiley Online Library Journals Frontfile Complete; Wiley-Blackwell Open Access Titles; PubMed Central
subjects Anemia
Antigens
Apoptosis
Bone marrow
Cancer therapies
Cell cycle
Drug resistance
Feedback
Gene expression
Genotype & phenotype
HIF
Homeostasis
Hypoxia
Interferon regulatory factor 4
IRF4
Medical prognosis
Metabolism
Microenvironments
Multiple myeloma
MYC
Myc protein
Plasma
Plasma cells
Population
Proteins
Regulation
Remission
Review
Stem cells
Transcription factors
Tumorigenesis
Tumors
title Impact of hypoxia on the pathogenesis and therapy resistance in multiple myeloma
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