Exosomal miR-155 from gastric cancer induces cancer-associated cachexia by suppressing adipogenesis and promoting brown adipose differentiation via C/EPBβ

References

1. 1.↵
   2. Argilés JM,
   3. Stemmler B,
   4. López-Soriano FJ,
   5. Busquets S.

   Inter-tissue communication in cancer cachexia. Nat Rev Endocrinol. 2018; 15: 9–20.

   OpenUrlCrossRefPubMed
2. 2.↵
   2. Baracos VE,
   3. Martin L,
   4. Korc M,
   5. Guttridge DC,
   6. Fearon KCH.

   Cancer-associated cachexia. Nat Rev Dis Primers. 2018; 4: 17105.

   OpenUrl
3. 3.↵
   2. Barton MK.

   Cancer cachexia awareness, diagnosis, and treatment are lacking among oncology providers. CA Cancer J Clin. 2017; 67: 91–2.

   OpenUrl
4. 4.↵
   2. Han L,
   3. Wang B,
   4. Wang R,
   5. Gong S,
   6. Chen G,
   7. Xu W.

   The shift in the balance between osteoblastogenesis and adipogenesis of mesenchymal stem cells mediated by glucocorticoid receptor. Stem Cell Res Ther. 2019; 10: 377.

   OpenUrl
5. 5.↵
   2. Bougarne N,
   3. Weyers B,
   4. Desmet SJ,
   5. Deckers J,
   6. Ray DW,
   7. Staels B, et al.

   Molecular actions of PPARα in lipid metabolism and inflammation. Endocr Rev. 2018; 39: 760–802.

   OpenUrlCrossRefPubMed
6. 6.↵
   2. Cao Y,
   3. Gomes SA,
   4. Rangel EB,
   5. Paulino EC,
   6. Fonseca TL,
   7. Li J, et al.

   S-nitrosoglutathione reductase-dependent PPARγ denitrosylation participates in MSC-derived adipogenesis and osteogenesis. J Clin Invest. 2015; 125: 1679–91.

   OpenUrlCrossRefPubMed
7. 7.↵
   2. Cao Y,
   3. Sun Z,
   4. Liao L,
   5. Meng Y,
   6. Han Q,
   7. Zhao RC.

   Human adipose tissue-derived stem cells differentiate into endothelial cells In vitro and improve postnatal neovascularization in vivo. Biochem Biophys Res Commun. 2005; 332: 370–9.

   OpenUrlCrossRefPubMedWeb of Science
8. 8.↵
   2. Feng S,
   3. Reuss L,
   4. Wang Y.

   Potential of natural products in the inhibition of adipogenesis through regulation of PPARγ expression and/or its transcriptional activity. Molecules (Basel, Switzerland). 2016; 21: 1278.

   OpenUrl
9. 9.↵
   2. Ghaben AL,
   3. Scherer PE.

   Adipogenesis and metabolic health. Nat Rev Mol Cell Biol. 2019; 20: 242–58.

   OpenUrlCrossRef
10. 10.↵
    2. Guo L,
    3. Li X,
    4. Tang QQ.

    Transcriptional regulation of adipocyte differentiation: a central role for CCAAT/enhancer-binding protein (C/EBP) β. J Biol Chem. 2015; 290: 755–61.

    OpenUrlAbstract/FREE Full Text
11. 11.↵
    2. Kahn CR,
    3. Wang G,
    4. Lee KY.

    Altered adipose tissue and adipocyte function in the pathogenesis of metabolic syndrome. J Clin Invest. 2019; 129: 3990–4000.

    OpenUrlCrossRefPubMed
12. 12.↵
    2. Kita S,
    3. Maeda N,
    4. Shimomura I.

    Interorgan communication by exosomes, adipose tissue, and adiponectin in metabolic syndrome. J Clin Invest. 2019; 129: 4041–9.

    OpenUrlCrossRef
13. 13.↵
    2. Liu Y,
    3. Song B,
    4. Wei Y,
    5. Chen F,
    6. Chi Y,
    7. Fan H, et al.

    Exosomes from mesenchymal stromal cells enhance imatinib-induced apoptosis in human leukemia cells via activation of caspase signaling pathway. Cytotherapy. 2018; 20: 181–8.

    OpenUrl
14. 14.↵
    2. O’Brien K,
    3. Breyne K,
    4. Ughetto S,
    5. Laurent LC,
    6. Breakefield XO.

    RNA delivery by extracellular vesicles in mammalian cells and its applications. Nat Rev Mol Cell Biol. 2020; 21: 585–606.

    OpenUrlCrossRef
15. 15.↵
    2. Sagar G,
    3. Sah RP,
    4. Javeed N,
    5. Dutta SK,
    6. Smyrk TC,
    7. Lau JS, et al.

    Pathogenesis of pancreatic cancer exosome-induced lipolysis in adipose tissue. Gut. 2016; 65: 1165–74.

    OpenUrlAbstract/FREE Full Text
16. 16.↵
    2. Zhang H,
    3. Zhu L,
    4. Bai M,
    5. Liu Y,
    6. Zhan Y,
    7. Deng T, et al.

    Exosomal circRNA derived from gastric tumor promotes white adipose browning by targeting the miR-133/PRDM16 pathway. Int J Cancer. 2019; 144: 2501–15.

    OpenUrl
17. 17.↵
    2. Roeland EJ,
    3. Bohlke K,
    4. Baracos VE,
    5. Bruera E,
    6. Del Fabbro E,
    7. Dixon S, et al.

    Management of cancer cachexia: ASCO guideline. J Clin Oncol. 2020; 38: 2438–53.

    OpenUrlPubMed
18. 18.↵
    2. Morigny P,
    3. Boucher J,
    4. Arner P,
    5. Langin D.

    Lipid and glucose metabolism in white adipocytes: pathways, dysfunction and therapeutics. Nat Rev Endocrinol. 2021; 17: 276–95.

    OpenUrlCrossRef
19. 19.↵
    2. Nguyen TD,
    3. Miyatake Y,
    4. Yoshida T,
    5. Kawahara H,
    6. Hanayama R.

    Tumor-secreted proliferin-1 regulates adipogenesis and lipolysis in cachexia. Int J Cancer. 2021; 148: 1982–92.

    OpenUrl
20. 20.↵
    2. Hu W,
    3. Ru Z,
    4. Zhou Y,
    5. Xiao W,
    6. Sun R,
    7. Zhang S, et al.

    Lung cancer-derived extracellular vesicles induced myotube atrophy and adipocyte lipolysis via the extracellular IL-6-mediated STAT3 pathway. Biochim Biophys Acta Mol Cell Biol Lipids. 2019; 1864: 1091–102.

    OpenUrl
21. 21.↵
    2. Lima J,
    3. Simoes E,
    4. de Castro G,
    5. Morais M,
    6. de Matos-Neto EM,
    7. Alves MJ, et al.

    Tumour-derived transforming growth factor-β signalling contributes to fibrosis in patients with cancer cachexia. J Cachexia Sarcopenia Muscle. 2019; 10: 1045–59.

    OpenUrl
22. 22.↵
    2. Rohm M,
    3. Schäfer M,
    4. Laurent V,
    5. Üstünel BE,
    6. Niopek K,
    7. Algire C, et al.

    An AMP-activated protein kinase-stabilizing peptide ameliorates adipose tissue wasting in cancer cachexia in mice. Nat Med. 2016; 22: 1120–30.

    OpenUrlCrossRef
23. 23.↵
    2. Gulei D,
    3. Raduly L,
    4. Broseghini E,
    5. Ferracin M,
    6. Berindan-Neagoe I.

    The extensive role of miR-155 in malignant and non-malignant diseases. Mol Aspects Med. 2019; 70: 33–56.

    OpenUrl
24. 24.↵
    2. Casabonne D,
    3. Benavente Y,
    4. Seifert J,
    5. Costas L,
    6. Armesto M,
    7. Arestin M, et al.

    Serum levels of hsa-miR-16-5p, hsa-miR-29a-3p, hsa-miR-150-5p, hsa-miR-155-5p and hsa-miR-223-3p and subsequent risk of chronic lymphocytic leukemia in the epic study. Int J Cancer. 2020; 147: 1315–24.

    OpenUrl
25. 25.↵
    2. Willerslev-Olsen A,
    3. Gjerdrum LMR,
    4. Lindahl LM,
    5. Buus TB,
    6. Pallesen EMH,
    7. Gluud M, et al.

    Staphylococcus aureus induces signal transducer and activator of transcription 5–dependent miR-155 expression in cutaneous T-cell lymphoma. J Invest Dermatol. 2021; 141: 2449–58.

    OpenUrl
26. 26.↵
    2. Tang QQ,
    3. Lane MD.

    Adipogenesis: From stem cell to adipocyte. Annu Rev Biochem. 2012; 81: 715–36.

    OpenUrlCrossRefPubMedWeb of Science
27. 27.↵
    2. Millward CA,
    3. Heaney JD,
    4. Sinasac DS,
    5. Chu EC,
    6. Bederman IR,
    7. Gilge DA, et al.

    Mice with a deletion in the gene for CCAAT/enhancer-binding protein beta are protected against diet-induced obesity. Diabetes. 2007; 56: 161–7.

    OpenUrlAbstract/FREE Full Text
28. 28.↵
    2. Vishvanath L,
    3. Gupta RK.

    Contribution of adipogenesis to healthy adipose tissue expansion in obesity. J Clin Invest. 2019; 129: 4022–31.

    OpenUrlCrossRef
29. 29.↵
    2. Walendzik K,
    3. Kopcewicz M,
    4. Bukowska J,
    5. Panasiewicz G,
    6. Szafranska B,
    7. Gawronska-Kozak B.

    The transcription factor FOXN1 regulates skin adipogenesis and affects susceptibility to diet-induced obesity. J Invest Dermatol. 2020; 140: 1166–75.e9.

    OpenUrl
30. 30.↵
    2. Watanabe Y,
    3. Watanabe K,
    4. Fujioka D,
    5. Nakamura K,
    6. Nakamura T,
    7. Uematsu M, et al.

    Protein S-glutathionylation stimulate adipogenesis by stabilizing C/EBPβ in 3T3L1 cells. FASEB J. 2020; 34: 5827–37.

    OpenUrl