Serine-dependent redox homeostasis regulates glioblastoma cell survival

Engel, Anna L; Lorenz, Nadja I.; Klann, Kevin; Münch, Christian; Depner, Cornelia; Steinbach, Joachim P.; Ronellenfitsch, Michael; Luger, Anna‐Luisa

doi:10.1038/s41416-020-0794-x

Cited by 56 publications

(47 citation statements)

References 57 publications

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“…Recently, the upregulation of PHGDH and SHMT2 expression under hypoxic conditions has also been observed in certain GBM cell lines. This study has shown that high levels of PHGDH protect GBM cells from hypoxia-induced cell death and starvation conditions, sustaining redox homeostasis and maintaining NADPH/NADP+ ratio [ 116 ]. Likewise, serine/glycine metabolism was previously associated with the survival of glioma tumor cells within the hypoxic areas.…”

Section: Radiotherapy Resistance and The Link With De Novo Serine/mentioning

confidence: 99%

“…For instance, serine starvation resulted in reduced viability and impaired proliferation in p53-deficient tumors [ 153 ]. Inhibition of de novo serine/glycine biosynthesis is likely most effective in tumors that are reliant on de novo serine/glycine biosynthesis, such as PHGDH-amplified melanoma and breast cancers, as well as tumors with increased dependency on this pathway under metabolic/stress conditions, e.g., KRAS-mutated pancreatic tumors, which become insensitive to serine/glycine deprivation [ 16 , 26 ], or GBM and cMYC-amplified neuroblastomas with upregulation of this pathway in response to hypoxia [ 115 , 116 ]. However, it is important to consider the metabolic plasticity and the compensatory mechanisms following these therapeutic strategies.…”

Section: Future Perspectives: Therapeutic Targeting Of De Novo Sermentioning

confidence: 99%

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Linking Serine/Glycine Metabolism to Radiotherapy Resistance

Sánchez‐Castillo

Vooijs

Kampen

2021

Cancers

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The activation of de novo serine/glycine biosynthesis in a subset of tumors has been described as a major contributor to tumor pathogenesis, poor outcome, and treatment resistance. Amplifications and mutations of de novo serine/glycine biosynthesis enzymes can trigger pathway activation; however, a large group of cancers displays serine/glycine pathway overexpression induced by oncogenic drivers and unknown regulatory mechanisms. A better understanding of the regulatory network of de novo serine/glycine biosynthesis activation in cancer might be essential to unveil opportunities to target tumor heterogeneity and therapy resistance. In the current review, we describe how the activation of de novo serine/glycine biosynthesis in cancer is linked to treatment resistance and its implications in the clinic. To our knowledge, only a few studies have identified this pathway as metabolic reprogramming of cancer cells in response to radiation therapy. We propose an important contribution of de novo serine/glycine biosynthesis pathway activation to radioresistance by being involved in cancer cell viability and proliferation, maintenance of cancer stem cells (CSCs), and redox homeostasis under hypoxia and nutrient-deprived conditions. Current approaches for inhibition of the de novo serine/glycine biosynthesis pathway provide new opportunities for therapeutic intervention, which in combination with radiotherapy might be a promising strategy for tumor control and ultimately eradication. Further research is needed to gain molecular and mechanistic insight into the activation of this pathway in response to radiation therapy and to design sophisticated stratification methods to select patients that might benefit from serine/glycine metabolism-targeted therapies in combination with radiotherapy.

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Section: Radiotherapy Resistance and The Link With De Novo Serine/mentioning

confidence: 99%

Section: Future Perspectives: Therapeutic Targeting Of De Novo Sermentioning

confidence: 99%

Linking Serine/Glycine Metabolism to Radiotherapy Resistance

Sánchez‐Castillo

Vooijs

Kampen

2021

Cancers

View full text Add to dashboard Cite

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“…For instance, Engel and colleagues reported that tumor microenvironment with high serine concentration contributed to rapid cell growth in glioblastoma. Interfering serine metabolism could be a plausible therapeutic target (Engel et al, 2020). It was reported that the proliferative ability of cancer cells could be enhanced by high content of microenvironmental serine (Labuschagne et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

“…For example, Saito et al reported that elevated leucine in microenvironment can promote cell proliferation in breast cancer, and induce resistance to tamoxifen (Saito et al, 2019). Engel et al found that serine content of microenvironment determined the growth and survival of glioblastoma (Engel et al, 2020). In lung cancer, the imbalance of kynurenine to tryptophan ratio in microenvironment was closely related to the resistance for immune checkpoint inhibitor (Li et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Genetic Profiles Affect the Biological Effects of Serine on Gastric Cancer Cells

Xue

Xiang

et al. 2020

Front. Pharmacol.

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A high serine content in body fluid was identified in a portion of patients with gastric cancer, but its biological significance was not clear. Here, we investigated the biological effect of serine on gastric cancer cells. Serine was added into the culture medium of MGC803 and HGC27 cancer cells, and its influence on multiple biological functions, such as cell growth, migration and invasion, and drug resistance was analyzed. We examined the global transcriptomic profiles in these cultured cells with high serine content. Both MGC803 and HGC27 cell lines were originated from male patients, however, their basal gene expression patterns were very different. The finding of cell differentiationassociated genes, ALPI, KRT18, TM4SF1, KRT81, A2M, MT1E, MUC16, BASP1, TUSC3, and PRSS21 in MGC803 cells suggested that this cell line was more poorly differentiated, compared to HGC27 cell line. When the serine concentration was increased to 150mg/ml in medium, the response of these two gastric cancer cell lines was different, particularly on cell growth, cell migration, and invasion and 5-FU resistance. In animal experiment, administration of high concentration of serine promoted cancer cell metastasis to local lymph node. Taken together, we characterized the basal gene expressing profiles of MGC803 and HGC27. The HGC27 cells were more differentiated than MGC803 cells. MGC803 cells were more sensitive to the change of serine content. Our results suggested that the responsiveness of cancer cells to microenvironmental change is associated with their genetic background.

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Target enzymes in serine‐glycine‐one‐carbon metabolic pathway for cancer therapy

Sun

Zhao

Cui

2022

Intl Journal of Cancer

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Cancer cells selectively take up exogenous serine or synthesize serine via the serine synthesis pathway for conversion into intracellular glycine and one-carbon units for nucleotide biosynthesis. In this process, serine-glycine metabolism and the onecarbon cycle play vital roles, which is named serine-glycine-one-carbon metabolism (SGOC). The SGOC pathway is a metabolic network crucial for tumorigenesis with unexpected complexity and clinical importance. Accumulating evidence has demonstrated that metabolic enzymes in SGOC metabolism play key roles in tumorigenesis, metastasis and resistance to therapies. In this review, we focus on the involvement of serine and glycine in the folate-mediated one-carbon pathway during cancer progression and highlight the pathways through which cancer cells acquire and use onecarbon units. In addition, we discuss the recently elucidated effects of SGOC (folate cycle) metabolic enzymes in the occurrence and development of tumors and their links to drug resistance. Inhibitors of target enzymes in the SGOC pathway display promise as investigational new drug candidates for the treatment of tumors.

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Serine-dependent redox homeostasis regulates glioblastoma cell survival

Cited by 56 publications

References 57 publications

Linking Serine/Glycine Metabolism to Radiotherapy Resistance

Linking Serine/Glycine Metabolism to Radiotherapy Resistance

Genetic Profiles Affect the Biological Effects of Serine on Gastric Cancer Cells

Target enzymes in serine‐glycine‐one‐carbon metabolic pathway for cancer therapy

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