A framework for advancing our understanding of cancer-associated fibroblasts

Sahai, Erik; Astsaturov, Igor; Cukierman, Edna; DeNardo, David G.; Egeblad, Mikala; Evans, Ronald M.; Fearon, Douglas T.; Greten, Florian R.; Hingorani, Sunil R.; Hunter, Tony; Hynes, Richard O.; Jain, Rakesh K.; Janowitz, Tobias; Jørgensen, Claus; Kimmelman, Alec C.; Kolonin, Mikhail G.; Maki, Robert G.; Powers, Scott; Puré, Ellen; Ramirez, Daniel C.; Scherz-Shouval, Ruth; Sherman, Mara H.; Stewart, Sheila A.; Tlsty, Thea D.; Tuveson, David A.; Watt, Fiona M.; Weaver, Valerie M.; Weeraratna, Ashani T.; Werb, Zena

doi:10.1038/s41568-019-0238-1

Cited by 2,122 publications

(2,026 citation statements)

References 173 publications

(210 reference statements)

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“…In conclusion, we have identified PDC as a novel potent epigenetic regulator of collagen-rich ECM production and pinpointed proline metabolism as a critical link between the epigenetic regulation of collagen gene expression and protein production. So far, most of the efforts to reduce ECM production in tumours have focused on targeting pathways that are well known to trigger CAF activation 75…”

Section: Discussionmentioning

confidence: 99%

PYCR1-dependent proline synthesis in cancer-associated fibroblasts is required for the deposition of pro-tumorigenic extracellular matrix

Kay

Paterson

Domingo

et al. 2020

Preprint

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The extracellular matrix (ECM) is the central driver of the desmoplastic reaction that fosters cancer aggressiveness. Cancer associated fibroblasts (CAFs) are the major source of ECM in tumours, thus being the optimal target to limit deposition of pro-tumourigenic ECM to oppose cancer. CAFs are metabolically active cells, however, how they support the biosynthetic requirements of producing ECM, and whether this can be targeted to influence tumour progression has not been investigated.We found that the pyruvate dehydrogenase kinase 2 (PDK2), a major inhibitor of the pyruvate dehydrogenase complex (PDC), is highly downregulated in CAFs and in the tumour stroma, when compared to normal fibroblasts. As consequence, PDC is more activated and generates acetyl-CoA, which elicits an epigenetic reprogramming through the histone acetyl transferase P300/CBP. This epigenetic reprogramming drives increased ECM production through increasing transcription of collagen genes and proline synthesis. We found that increased proline availability is necessary to support the biosynthetic requirements that follow the epigenetic reprogramming, for the translation of collagen to make abundant ECM. Targeting the rate-limiting enzyme for proline synthesis, pyrroline-5-carboxylate reductase 1 (PYCR1), in CAFs was sufficient to limit collagen deposition and hamper tumour growth. In conclusion, ECM production in CAFs is under strict metabolic control, and our results warrant considering targeting proline synthesis to normalise ECM production in tumours and possibly other diseases involving collagen production, such as fibrosis.

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Section: Discussionmentioning

confidence: 99%

PYCR1-dependent proline synthesis in cancer-associated fibroblasts is required for the deposition of pro-tumorigenic extracellular matrix

Kay

Paterson

Domingo

et al. 2020

Preprint

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“…The role of microenvironment upon cancer formation, and progression to metastasis is supported by numerous studies [19,20], however the current knowledge is not sufficient to reconstruct the chain events from primary to secondary tumor progression. Normal stroma microenvironment is considered to halt tumor formation, however after interaction with tumor cells, it also undergoes a certain "transformation" at the transcriptomic and even at the genetic level [21][22][23][24].…”

Section: Discussionmentioning

confidence: 99%

Stroma transcriptomic and proteomic profile of prostate cancer metastasis xenograft models reveals conservation of bone microenvironment signatures

Karkampouna

Filippo

et al. 2020

Preprint

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Prostate cancer (PCa) is the second leading cause of cancer-associated death in men with therapy resistance acquisition to androgen deprivation treatment and metastasis progression.Understanding the mechanisms of tumor progression to metastatic stage is necessary for the design of therapeutic and prognostic schemes. The main objective of the current study is to determine, using transcriptomic and proteomic analyses on patient derived-xenograft models, whether differentially aggressive PCa tumors predispose their microenvironment (stroma) to a metastatic gene expression pattern, and how this information could be applied in prognostics.Transcriptomic profiling (RNA Sequencing) was performed on PCa PDX models representing different disease stages; BM18 (androgen dependent bone metastasis) and LAPC9 (androgen independent bone metastasis). Using organism-specific reference databases, the humanspecific transcriptome, representing the tumor, was identified and separated from the mousespecific transcriptome (representing the contributing stroma counterpart) from the same PDX tumor samples. To identify proteome changes in the tumor (human) versus the stroma (mouse), we performed human and mouse cell separation using the MACS mouse depletion sorting kit, and subjected protein lysates to quantitative TMT labeling and mass spectrometry. We show

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“…The understanding of CAFs biology and potential targeting strategies directed to CAFs constitute a relatively new and highly dynamic field of investigation. Recent excellent reviews summarize the state-of-the-art in this expanding field that will not be discussed further in this review [13,14].Here, we provide an overview of the current literature regarding the epigenetic background of TECs biology, as well as recently performed (and ongoing) clinical trials targeting tumors on the bases of combined treatment with antiangiogenic and epigenetic drugs.…”

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confidence: 99%

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confidence: 99%

The Epigenetic Profile of Tumor Endothelial Cells. Effects of Combined Therapy with Antiangiogenic and Epigenetic Drugs on Cancer Progression

Ciesielski

Biesiekierska

Panthu

et al. 2020

IJMS

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Tumors require a constant supply of nutrients to grow which are provided through tumor blood vessels. To metastasize, tumors need a route to enter circulation, that route is also provided by tumor blood vessels. Thus, angiogenesis is necessary for both tumor progression and metastasis. Angiogenesis is tightly regulated by a balance of angiogenic and antiangiogenic factors. Angiogenic factors of the vascular endothelial growth factor (VEGF) family lead to the activation of endothelial cells, proliferation, and neovascularization. Significant VEGF-A upregulation is commonly observed in cancer cells, also due to hypoxic conditions, and activates endothelial cells (ECs) by paracrine signaling stimulating cell migration and proliferation, resulting in tumor-dependent angiogenesis. Conversely, antiangiogenic factors inhibit angiogenesis by suppressing ECs activation. One of the best-known anti-angiogenic factors is thrombospondin-1 (TSP-1). In pathological angiogenesis, the balance shifts towards the proangiogenic factors and an angiogenic switch that promotes tumor angiogenesis. Here, we review the current literature supporting the notion of the existence of two different endothelial lineages: normal endothelial cells (NECs), representing the physiological form of vascular endothelium, and tumor endothelial cells (TECs), which are strongly promoted by the tumor microenvironment and are biologically different from NECs. The angiogenic switch would be also important for the explanation of the differences between NECs and TECs, as angiogenic factors, cytokines and growth factors secreted into the tumor microenvironment may cause genetic instability. In this review, we focus on the epigenetic differences between the two endothelial lineages, which provide a possible window for pharmacological targeting of TECs.Int. J. Mol. Sci. 2020, 21, 2606 2 of 22 organ" spread over an area of approximately 7 m 2 that controls: (i) the flow of blood, (ii) organism nutrition by the passage of metabolites and gases exchange, (iii) immunity by circulating immune cells and antibodies, as well as (iv) trafficking of leukocytes [2][3][4]. Moreover, endothelial cells are involved in several physiological processes including (v) angiogenesis, (vi) blood coagulation and fibrinolysis, (vii) vasomotor and blood pressure regulation, and (viii) inflammatory reactions, which are conditioned by a multitude of synthesized and released hormonal and chemical mediators, including vascular endothelial growth factor (VEGF), nitric oxide (NO • ), or prostaglandin E2 [5][6][7].Dysfunction of the endothelium results in a number of disorders. In tumors, endothelial cells due to chronic stimulation by growth factors and hypoxia, change their phenotype into tumor endothelial cells (TECs), which results in abnormalities in tumor blood vessel morphology. TECs are fragile and leaky as compared to normal vessels, that in consequence alters blood flow. These abnormalities in the tumor endothelium contribute to tumor growth and metastasis [8,9]. Thus, a detailed under...

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A framework for advancing our understanding of cancer-associated fibroblasts

Cited by 2,122 publications

References 173 publications

PYCR1-dependent proline synthesis in cancer-associated fibroblasts is required for the deposition of pro-tumorigenic extracellular matrix

PYCR1-dependent proline synthesis in cancer-associated fibroblasts is required for the deposition of pro-tumorigenic extracellular matrix

Stroma transcriptomic and proteomic profile of prostate cancer metastasis xenograft models reveals conservation of bone microenvironment signatures

The Epigenetic Profile of Tumor Endothelial Cells. Effects of Combined Therapy with Antiangiogenic and Epigenetic Drugs on Cancer Progression

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