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<record><TEI><teiHeader><fileDesc><titleStmt><title xml:lang="en">Metformin inhibits metastatic breast cancer progression and improves chemosensitivity by inducing vessel normalization via PDGF-B downregulation</title><author><name sortKey="Wang, Ji Chang" sort="Wang, Ji Chang" uniqKey="Wang J" first="Ji-Chang" last="Wang">Ji-Chang Wang</name><affiliation><nlm:aff id="Aff1"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Vascular Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation><affiliation><nlm:aff id="Aff2"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Center for Translational Medicine,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Li, Guang Yue" sort="Li, Guang Yue" uniqKey="Li G" first="Guang-Yue" last="Li">Guang-Yue Li</name><affiliation><nlm:aff id="Aff3"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Science and Technology,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Wang, Bo" sort="Wang, Bo" uniqKey="Wang B" first="Bo" last="Wang">Bo Wang</name><affiliation><nlm:aff id="Aff2"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Center for Translational Medicine,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Han, Su Xia" sort="Han, Su Xia" uniqKey="Han S" first="Su-Xia" last="Han">Su-Xia Han</name><affiliation><nlm:aff id="Aff4"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Oncological Radiotherapy,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Sun, Xin" sort="Sun, Xin" uniqKey="Sun X" first="Xin" last="Sun">Xin Sun</name><affiliation><nlm:aff id="Aff5"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Thoracic Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Jiang, Yi Na" sort="Jiang, Yi Na" uniqKey="Jiang Y" first="Yi-Na" last="Jiang">Yi-Na Jiang</name><affiliation><nlm:aff id="Aff6"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Pathology,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Shen, Yan Wei" sort="Shen, Yan Wei" uniqKey="Shen Y" first="Yan-Wei" last="Shen">Yan-Wei Shen</name><affiliation><nlm:aff id="Aff8"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Breast Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Zhou, Can" sort="Zhou, Can" uniqKey="Zhou C" first="Can" last="Zhou">Can Zhou</name><affiliation><nlm:aff id="Aff7"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Medical Oncology,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Feng, Jun" sort="Feng, Jun" uniqKey="Feng J" first="Jun" last="Feng">Jun Feng</name><affiliation><nlm:aff id="Aff1"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Vascular Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Lu, Shao Ying" sort="Lu, Shao Ying" uniqKey="Lu S" first="Shao-Ying" last="Lu">Shao-Ying Lu</name><affiliation><nlm:aff id="Aff1"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Vascular Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Liu, Jian Lin" sort="Liu, Jian Lin" uniqKey="Liu J" first="Jian-Lin" last="Liu">Jian-Lin Liu</name><affiliation><nlm:aff id="Aff1"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Vascular Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Wang, Mao De" sort="Wang, Mao De" uniqKey="Wang M" first="Mao-De" last="Wang">Mao-De Wang</name><affiliation><nlm:aff id="Aff9"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Neurosurgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Liu, Pei Jun" sort="Liu, Pei Jun" uniqKey="Liu P" first="Pei-Jun" last="Liu">Pei-Jun Liu</name><affiliation><nlm:aff id="Aff2"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Center for Translational Medicine,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation><affiliation><nlm:aff id="Aff10"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Key Laboratory for Tumor Precision Medicine of Shaanxi Province,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author></titleStmt><publicationStmt><idno type="wicri:source">PMC</idno><idno type="pmid">31164151</idno><idno type="pmc">6549289</idno><idno type="url">http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6549289</idno><idno type="RBID">PMC:6549289</idno><idno type="doi">10.1186/s13046-019-1211-2</idno><date when="2019">2019</date><idno type="wicri:Area/Pmc/Corpus">000106</idno><idno type="wicri:explorRef" wicri:stream="Pmc" wicri:step="Corpus" wicri:corpus="PMC">000106</idno></publicationStmt><sourceDesc><biblStruct><analytic><title xml:lang="en" level="a" type="main">Metformin inhibits metastatic breast cancer progression and improves chemosensitivity by inducing vessel normalization via PDGF-B downregulation</title><author><name sortKey="Wang, Ji Chang" sort="Wang, Ji Chang" uniqKey="Wang J" first="Ji-Chang" last="Wang">Ji-Chang Wang</name><affiliation><nlm:aff id="Aff1"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Vascular Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation><affiliation><nlm:aff id="Aff2"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Center for Translational Medicine,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Li, Guang Yue" sort="Li, Guang Yue" uniqKey="Li G" first="Guang-Yue" last="Li">Guang-Yue Li</name><affiliation><nlm:aff id="Aff3"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Science and Technology,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Wang, Bo" sort="Wang, Bo" uniqKey="Wang B" first="Bo" last="Wang">Bo Wang</name><affiliation><nlm:aff id="Aff2"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Center for Translational Medicine,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Han, Su Xia" sort="Han, Su Xia" uniqKey="Han S" first="Su-Xia" last="Han">Su-Xia Han</name><affiliation><nlm:aff id="Aff4"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Oncological Radiotherapy,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Sun, Xin" sort="Sun, Xin" uniqKey="Sun X" first="Xin" last="Sun">Xin Sun</name><affiliation><nlm:aff id="Aff5"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Thoracic Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Jiang, Yi Na" sort="Jiang, Yi Na" uniqKey="Jiang Y" first="Yi-Na" last="Jiang">Yi-Na Jiang</name><affiliation><nlm:aff id="Aff6"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Pathology,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Shen, Yan Wei" sort="Shen, Yan Wei" uniqKey="Shen Y" first="Yan-Wei" last="Shen">Yan-Wei Shen</name><affiliation><nlm:aff id="Aff8"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Breast Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Zhou, Can" sort="Zhou, Can" uniqKey="Zhou C" first="Can" last="Zhou">Can Zhou</name><affiliation><nlm:aff id="Aff7"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Medical Oncology,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Feng, Jun" sort="Feng, Jun" uniqKey="Feng J" first="Jun" last="Feng">Jun Feng</name><affiliation><nlm:aff id="Aff1"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Vascular Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Lu, Shao Ying" sort="Lu, Shao Ying" uniqKey="Lu S" first="Shao-Ying" last="Lu">Shao-Ying Lu</name><affiliation><nlm:aff id="Aff1"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Vascular Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Liu, Jian Lin" sort="Liu, Jian Lin" uniqKey="Liu J" first="Jian-Lin" last="Liu">Jian-Lin Liu</name><affiliation><nlm:aff id="Aff1"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Vascular Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Wang, Mao De" sort="Wang, Mao De" uniqKey="Wang M" first="Mao-De" last="Wang">Mao-De Wang</name><affiliation><nlm:aff id="Aff9"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Neurosurgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author><author><name sortKey="Liu, Pei Jun" sort="Liu, Pei Jun" uniqKey="Liu P" first="Pei-Jun" last="Liu">Pei-Jun Liu</name><affiliation><nlm:aff id="Aff2"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Center for Translational Medicine,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation><affiliation><nlm:aff id="Aff10"><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Key Laboratory for Tumor Precision Medicine of Shaanxi Province,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</nlm:aff></affiliation></author></analytic><series><title level="j">Journal of Experimental & Clinical Cancer Research : CR</title><idno type="ISSN">0392-9078</idno><idno type="eISSN">1756-9966</idno><imprint><date when="2019">2019</date></imprint></series></biblStruct></sourceDesc></fileDesc><profileDesc><textClass></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en"><sec><title>Background</title><p id="Par1">Vascular maturity and functionality are closely associated with tumor progression and chemosensitivity. The antidiabetic agent metformin has shown its ability to inhibit tumor angiogenesis in metastatic breast cancer models. However, it remains unclear if or how metformin remodels the abnormal vasculature of metastatic breast cancer, while inhibiting angiogenesis.</p></sec><sec><title>Methods</title><p id="Par2">Metastatic breast cancer models were constructed to compare microvessel density (MVD), vascular maturity and function, lung metastasis and chemosensitivity in metformin-treated or untreated mice. Protein array assay and transcriptome sequencing were performed for genetic screening. Lentiviral shRNA-PDGF-B transfection was used for observing the contribution of PDGF-B knockdown to metformin’s vascular effects.</p></sec><sec><title>Results</title><p id="Par3">Metastatic breast cancers were characterized by an excessively angiogenic, immature and morphologically abnormal vasculature. Compared to control, metformin significantly reduced MVD, leakage and hypoxia, and increased vascular mural cells coverage and perfusion, namely, “vessel normalization”. Metformin at human blood concentrations had no direct effect on the migration and proliferation of cancer cells. Based on that, reduced lung metastasis of the primary tumor and improved chemosensitization by metformin were assumed to be mediated via metformin’s vascular effects. Further results of genetic screening and in vivo experiments showed that the downregulation of platelet-derived growth factor B (PDGF-B) greatly contributed to the metformin-induced vessel normalization.</p></sec><sec><title>Conclusions</title><p id="Par4">These findings provide pre-clinical evidences for the vascular mechanism of metformin-induced metastasis inhibition and the chemosensitization of metastatic breast cancers.</p></sec><sec><title>Electronic supplementary material</title><p>The online version of this article (10.1186/s13046-019-1211-2) contains supplementary material, which is available to authorized users.</p></sec></div></front><back><div1 type="bibliography"><listBibl><biblStruct><analytic><author><name sortKey="Kerbel, Rs" uniqKey="Kerbel R">RS Kerbel</name></author></analytic></biblStruct><biblStruct><analytic><author><name sortKey="Folkman, J" uniqKey="Folkman J">J FOLKMAN</name></author></analytic></biblStruct><biblStruct><analytic><author><name sortKey="Ebos, 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<front><journal-meta><journal-id journal-id-type="nlm-ta">J Exp Clin Cancer Res</journal-id><journal-id journal-id-type="iso-abbrev">J. Exp. Clin. Cancer Res</journal-id><journal-title-group><journal-title>Journal of Experimental & Clinical Cancer Research : CR</journal-title></journal-title-group><issn pub-type="ppub">0392-9078</issn><issn pub-type="epub">1756-9966</issn><publisher><publisher-name>BioMed Central</publisher-name><publisher-loc>London</publisher-loc></publisher></journal-meta><article-meta><article-id pub-id-type="pmid">31164151</article-id><article-id pub-id-type="pmc">6549289</article-id><article-id pub-id-type="publisher-id">1211</article-id><article-id pub-id-type="doi">10.1186/s13046-019-1211-2</article-id><article-categories><subj-group subj-group-type="heading"><subject>Research</subject></subj-group></article-categories><title-group><article-title>Metformin inhibits metastatic breast cancer progression and improves chemosensitivity by inducing vessel normalization via PDGF-B downregulation</article-title></title-group><contrib-group><contrib contrib-type="author" equal-contrib="yes"><name><surname>Wang</surname><given-names>Ji-Chang</given-names></name><address><email>wangjichang@xjtu.edu.cn</email></address><xref ref-type="aff" rid="Aff1">1</xref><xref ref-type="aff" rid="Aff2">2</xref></contrib><contrib contrib-type="author" equal-contrib="yes"><name><surname>Li</surname><given-names>Guang-Yue</given-names></name><address><email>lgymoon@126.com</email></address><xref ref-type="aff" rid="Aff3">3</xref></contrib><contrib contrib-type="author"><name><surname>Wang</surname><given-names>Bo</given-names></name><address><email>realwbo@xjtu.edu.cn</email></address><xref ref-type="aff" rid="Aff2">2</xref></contrib><contrib contrib-type="author"><name><surname>Han</surname><given-names>Su-Xia</given-names></name><address><email>shan87@xjtu.edu.cn</email></address><xref ref-type="aff" rid="Aff4">4</xref></contrib><contrib contrib-type="author"><name><surname>Sun</surname><given-names>Xin</given-names></name><address><email>endeavour.sun@gmail.com</email></address><xref ref-type="aff" rid="Aff5">5</xref></contrib><contrib contrib-type="author"><name><surname>Jiang</surname><given-names>Yi-Na</given-names></name><address><email>yinajiang1122@sina.cn</email></address><xref ref-type="aff" rid="Aff6">6</xref></contrib><contrib contrib-type="author"><name><surname>Shen</surname><given-names>Yan-Wei</given-names></name><address><email>870923633@qq.com</email></address><xref ref-type="aff" rid="Aff8">8</xref></contrib><contrib contrib-type="author"><name><surname>Zhou</surname><given-names>Can</given-names></name><address><email>zhoucanz2005@126.com</email></address><xref ref-type="aff" rid="Aff7">7</xref></contrib><contrib contrib-type="author"><name><surname>Feng</surname><given-names>Jun</given-names></name><address><email>1223134642@qq.com</email></address><xref ref-type="aff" rid="Aff1">1</xref></contrib><contrib contrib-type="author"><name><surname>Lu</surname><given-names>Shao-Ying</given-names></name><address><email>robertlu@mail.xjtu.edu.cn</email></address><xref ref-type="aff" rid="Aff1">1</xref></contrib><contrib contrib-type="author"><name><surname>Liu</surname><given-names>Jian-Lin</given-names></name><address><email>liujianlin@mail.xjtu.edu.cn</email></address><xref ref-type="aff" rid="Aff1">1</xref></contrib><contrib contrib-type="author" corresp="yes"><name><surname>Wang</surname><given-names>Mao-De</given-names></name><address><phone>0086-18991232126</phone><phone>+86-029-85323985</phone><email>maodewang@163.com</email></address><xref ref-type="aff" rid="Aff9">9</xref></contrib><contrib contrib-type="author" corresp="yes"><contrib-id contrib-id-type="orcid">http://orcid.org/0000-0002-0767-0774</contrib-id><name><surname>Liu</surname><given-names>Pei-Jun</given-names></name><address><phone>+86-029-85324628</phone><email>liupeijun@mail.xjtu.edu.cn</email></address><xref ref-type="aff" rid="Aff2">2</xref><xref ref-type="aff" rid="Aff10">10</xref></contrib><aff id="Aff1"><label>1</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Vascular Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</aff><aff id="Aff2"><label>2</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Center for Translational Medicine,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</aff><aff id="Aff3"><label>3</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Science and Technology,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</aff><aff id="Aff4"><label>4</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Oncological Radiotherapy,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</aff><aff id="Aff5"><label>5</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Thoracic Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</aff><aff id="Aff6"><label>6</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Pathology,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</aff><aff id="Aff7"><label>7</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Medical Oncology,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</aff><aff id="Aff8"><label>8</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Breast Surgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>Xi’an, 710061 Shaanxi Province China</aff><aff id="Aff9"><label>9</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Department of Neurosurgery,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</aff><aff id="Aff10"><label>10</label><institution-wrap><institution-id institution-id-type="GRID">grid.452438.c</institution-id><institution>Key Laboratory for Tumor Precision Medicine of Shaanxi Province,</institution><institution>First Affiliated Hospital of Xi’an Jiaotong University,</institution></institution-wrap>No. 277 of the Western Yanta Road, Xi’an, 710061 Shaanxi Province China</aff></contrib-group><pub-date pub-type="epub"><day>4</day><month>6</month><year>2019</year></pub-date><pub-date pub-type="pmc-release"><day>4</day><month>6</month><year>2019</year></pub-date><pub-date pub-type="collection"><year>2019</year></pub-date><volume>38</volume><elocation-id>235</elocation-id><history><date date-type="received"><day>22</day><month>1</month><year>2019</year></date><date date-type="accepted"><day>3</day><month>5</month><year>2019</year></date></history><permissions><copyright-statement>© The Author(s). 2019</copyright-statement><license license-type="OpenAccess"><license-p><bold>Open Access</bold>This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (<ext-link ext-link-type="uri" xlink:href="http://creativecommons.org/licenses/by/4.0/">http://creativecommons.org/licenses/by/4.0/</ext-link>), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (<ext-link ext-link-type="uri" xlink:href="http://creativecommons.org/publicdomain/zero/1.0/">http://creativecommons.org/publicdomain/zero/1.0/</ext-link>) applies to the data made available in this article, unless otherwise stated.</license-p></license></permissions><abstract id="Abs1"><sec><title>Background</title><p id="Par1">Vascular maturity and functionality are closely associated with tumor progression and chemosensitivity. The antidiabetic agent metformin has shown its ability to inhibit tumor angiogenesis in metastatic breast cancer models. However, it remains unclear if or how metformin remodels the abnormal vasculature of metastatic breast cancer, while inhibiting angiogenesis.</p></sec><sec><title>Methods</title><p id="Par2">Metastatic breast cancer models were constructed to compare microvessel density (MVD), vascular maturity and function, lung metastasis and chemosensitivity in metformin-treated or untreated mice. Protein array assay and transcriptome sequencing were performed for genetic screening. Lentiviral shRNA-PDGF-B transfection was used for observing the contribution of PDGF-B knockdown to metformin’s vascular effects.</p></sec><sec><title>Results</title><p id="Par3">Metastatic breast cancers were characterized by an excessively angiogenic, immature and morphologically abnormal vasculature. Compared to control, metformin significantly reduced MVD, leakage and hypoxia, and increased vascular mural cells coverage and perfusion, namely, “vessel normalization”. Metformin at human blood concentrations had no direct effect on the migration and proliferation of cancer cells. Based on that, reduced lung metastasis of the primary tumor and improved chemosensitization by metformin were assumed to be mediated via metformin’s vascular effects. Further results of genetic screening and in vivo experiments showed that the downregulation of platelet-derived growth factor B (PDGF-B) greatly contributed to the metformin-induced vessel normalization.</p></sec><sec><title>Conclusions</title><p id="Par4">These findings provide pre-clinical evidences for the vascular mechanism of metformin-induced metastasis inhibition and the chemosensitization of metastatic breast cancers.</p></sec><sec><title>Electronic supplementary material</title><p>The online version of this article (10.1186/s13046-019-1211-2) contains supplementary material, which is available to authorized users.</p></sec></abstract><kwd-group xml:lang="en"><title>Keywords</title><kwd>Metformin</kwd><kwd>Metastatic breast cancer</kwd><kwd>Vessel normalization</kwd><kwd>Chemosensitization</kwd><kwd>PDGF-B</kwd></kwd-group><funding-group><award-group><funding-source><institution-wrap><institution-id institution-id-type="FundRef">http://dx.doi.org/10.13039/501100010909</institution-id><institution>Young Scientists Fund</institution></institution-wrap></funding-source><award-id>No.81602502</award-id><award-id>No.81602638</award-id><principal-award-recipient><name><surname>Wang</surname><given-names>Ji-Chang</given-names></name><name><surname>Li</surname><given-names>Guang-Yue</given-names></name></principal-award-recipient></award-group></funding-group><funding-group><award-group><funding-source><institution-wrap><institution-id institution-id-type="FundRef">http://dx.doi.org/10.13039/501100011710</institution-id><institution>Shaanxi Provincial Science and Technology Department</institution></institution-wrap></funding-source><award-id>No.2017SF017</award-id><award-id>No.2016SF196</award-id><principal-award-recipient><name><surname>Wang</surname><given-names>Ji-Chang</given-names></name><name><surname>Lu</surname><given-names>Shao-Ying</given-names></name></principal-award-recipient></award-group></funding-group><funding-group><award-group><funding-source><institution-wrap><institution-id institution-id-type="FundRef">http://dx.doi.org/10.13039/501100007128</institution-id><institution>Natural Science Foundation of Shaanxi Province</institution></institution-wrap></funding-source><award-id>No.2016JM8125</award-id><principal-award-recipient><name><surname>Li</surname><given-names>Guang-Yue</given-names></name></principal-award-recipient></award-group></funding-group><funding-group><award-group><funding-source><institution-wrap><institution-id institution-id-type="FundRef">http://dx.doi.org/10.13039/501100002412</institution-id><institution>Xi’an Jiaotong University</institution></institution-wrap></funding-source><award-id>No. xjj2016104</award-id><principal-award-recipient><name><surname>Wang</surname><given-names>Ji-Chang</given-names></name></principal-award-recipient></award-group></funding-group><custom-meta-group><custom-meta><meta-name>issue-copyright-statement</meta-name><meta-value>© The Author(s) 2019</meta-value></custom-meta></custom-meta-group></article-meta></front><body><sec id="Sec1"><title>Background</title><p id="Par5">Angiogenesis that mediates the formation of new blood vessels serves as a hallmark for cancers [<xref ref-type="bibr" rid="CR1">1</xref>], of which the critical role in cancer progression has now been widely accepted [<xref ref-type="bibr" rid="CR2">2</xref>]. Hence, anti-angiogenic drugs (AADs) have been extensively developed whose usage constitutes a major modality of anti-tumor therapy [<xref ref-type="bibr" rid="CR3">3</xref>]. However, mechanisms underlying AADs-induced antitumor effects remained unclear. Currently, there are two major hypotheses highly relevant to AADs-related antitumor activities. One offers a possible mechanism that cancer cells are killed through the blocking of blood supply by AADs via the inhibition of tumor angiogenesis [<xref ref-type="bibr" rid="CR2">2</xref>]. Up until now, this hypothesized tumor-starving mechanism has not been clinically verified. Another hypothesis involves the remodeling of the remaining abnormal vessels [<xref ref-type="bibr" rid="CR4">4</xref>, <xref ref-type="bibr" rid="CR5">5</xref>], also known as “vessel normalization”. In the latter hypothesis, the drugs not only suppress both the growth and metastasis of the tumor but also enhance the chemosensitization of cancer cells by improving the vascular maturity and functionality, and ameliorating tumor hypoxia [<xref ref-type="bibr" rid="CR6">6</xref>].</p><p id="Par6">Conventional therapies targeting tumor angiogenesis is efficacious (in terms of survival benefit) only for some cancers, such as colorectal cancer and renal cell carcinoma, etc., but not for others (e.g. breast cancer, melanoma) [<xref ref-type="bibr" rid="CR6">6</xref>, <xref ref-type="bibr" rid="CR7">7</xref>]. Anti-angiogenic benefit in term of survival cannot be seen in all patients with cancers [<xref ref-type="bibr" rid="CR8">8</xref>, <xref ref-type="bibr" rid="CR9">9</xref>], which have been clinically demonstrated to be responsive to anti-angiogenic therapies. For instance, bevacizumab added to chemo-drug did not significantly improve the overall survival of the patients with metastatic breast cancers [<xref ref-type="bibr" rid="CR9">9</xref>]. This is partially due to the lack of vascular parameters available for predicting the treatment efficacy [<xref ref-type="bibr" rid="CR10">10</xref>]. Moreover, intrinsic and acquired resistance have been shown to even impair the survival benefit already achieved clinically in some cancer patients [<xref ref-type="bibr" rid="CR3">3</xref>, <xref ref-type="bibr" rid="CR11">11</xref>]. Thus, there is a pressing need for researchers to develop a more effective treatment regimen.</p><p id="Par7">Population- and clinic-based studies have demonstrated the potential anti-proliferative and anti-metastatic activities of the antidiabetic agent metformin, a member of biguanides, when used in cases with malignant diseases [<xref ref-type="bibr" rid="CR12">12</xref>–<xref ref-type="bibr" rid="CR14">14</xref>]. Data from preclinical studies have revealed the pleiotropic effects of metformin [<xref ref-type="bibr" rid="CR15">15</xref>, <xref ref-type="bibr" rid="CR16">16</xref>]. However, the mechanisms of metformin’s effects in carcinogenesis were not fully understood, and more details concerning metformin’s effects should be further studied. The anti-angiogenesis potential of metformin has recently been reported by several laboratories [<xref ref-type="bibr" rid="CR17">17</xref>–<xref ref-type="bibr" rid="CR19">19</xref>]. However, little is known to date about if or how metformin remodels the abnormal tumor vasculature, while inhibiting angiogenesis. Since vascular maturity and functionality are closely associated with hypoxia and metastasis [<xref ref-type="bibr" rid="CR20">20</xref>], further researches with a focus on the vascular mechanism would be hugely meaningful. Additionally, biguanides also have the potential to enhance the in vivo toxicity of chemo-drug for cancer treatment [<xref ref-type="bibr" rid="CR21">21</xref>, <xref ref-type="bibr" rid="CR22">22</xref>], but it was still unclear whether this chemosensitization involves a vascular mechanism.</p><p id="Par8">The aim of the present study was to investigate the effects of metformin on vascular maturity and functionality and angiogenesis. Further results of genetic screening imply the deep involvement of platelet-derived growth factor B (PDGF-B) in metformin-induced vessel normalization.</p></sec><sec id="Sec2"><title>Methods</title><sec id="Sec3"><title>Cell culture, proliferation, colony formation and migration assays</title><p id="Par9">HUVECs and murine 4T1 and human MDA-MB-231 metastatic breast cancer cell lines were obtained from the American Type Culture Collection (ATCC, Manassas, VA) and cultured in Dulbecco’s Modified Eagle’s medium (DMEM) (Invitrogen) supplemented with 10% fetal bovine serum (FBS). All cell lines used in the study were not listed in the database of commonly misidentified cell lines maintained by International Cell Line Authentication Committee (ICLAC). Cell line Cross-Contamination was tested using the Short Tandem Repeat (STR) genotyping analysis method. Mycoplasma contamination was tested using Myco-Test Kit of MP Biomedicals (No.093030000) every three months, or when the growth rate and morphology of the cell lines were found to be abnormal. All cell lines were cultured and maintained in an atmosphere consisting of CO<sup>2</sup> (5%) and the room air (95%) at 37 °C. In vitro migration was analyzed by inoculating cancer cells in the upper chamber of a transwell (Millipore; 8 μm pore insert). To assess in vitro colonization ability, cancer cells were cultured in a 6-well culture plate, which were finally fixed and stained with crystal violet solution (C0775, Sigma). Cellular proliferation rate was measured by counting the number of cells in the culture dish (6 cm diameter) each day.</p></sec><sec id="Sec4"><title>Chemicals and reagents</title><p id="Par10">Metformin (No.13118), cyclophosphamide (CTX, No.13849), cisplatin (CPT, No.13119) and imatinib (No.13139) were purchased from Cayman Chemical. The active 4-hydroxy-CTX (4-OH-CTX) was obtained by the ozonization of cyclophosphamide using the method described previously [<xref ref-type="bibr" rid="CR23">23</xref>, <xref ref-type="bibr" rid="CR24">24</xref>].</p></sec><sec id="Sec5"><title>Protein array assay</title><p id="Par11">To analyze the proteome profile of angiogenesis-related factors, mouse angiogenesis array (ARY015, R&D System) was incubated with fresh cellular lysates containing 1 mg protein according to the manufacturer’s instructions. The RapidStep™ ECL reagent (No.345818, Millipore) was used, and spot intensities were measured using the NIH ImageJ software (Bethesda, MD) for data capture.</p></sec><sec id="Sec6"><title>Mouse models</title><p id="Par12">All animals were obtained from Animal Experiment Center of Xi’an Jiaotong University. To assess the in vivo tumor growth, 5Х10<sup>5</sup> 4T1 and 2Х10<sup>6</sup> MDA-MB-231 cells were suspended in 100 μL precoated PBS, and then injected into the fat pad of the 4th left mammary gland of mice (4T1: female BALB/c; MDA-MB-231: female nude mice). After 6–8 weeks, the mice without obvious abnormality in appearance were randomly divided into different groups (8 mice per group) when the mean tumor volume reached about 50–100 mm<sup>2</sup>. For the observation of chemosensitization, tumor-bearing mice were pretreated with metformin (orally) for 5 days before receiving the intraperitoneal injection of CTX. Before the experiment started formally, the proper sample size that ensures adequate power for a statistical difference was estimated using the following formula: <italic>N</italic> = 2·[(u<sub>0.05)</sub> + u<sub>(0.10)</sub>)·S/X]<sup>2</sup>, “S” indicates standard deviation of the overall sample, and “X” indicates the difference of the mean tumor weight between two groups. Tumor volume was measured with a caliper every two or three days and calculated using the formula V = 0.523•[a<sup>2</sup>•A] (“a” indicates the minor tumor axis; “A” indicates the major tumor axis). To observe the change of lung metastasis (4 T1) from primary tumors, tumor-bearing mice were fed for at least 28 days after inoculation.</p></sec><sec id="Sec7"><title>Flow cytometry analysis</title><p id="Par13">Necrotic and late apoptotic cells were labeled with propidium iodide (PI) at a concentration of 5 μg/mL, and PI<sup>+</sup> dead cells were identified by Flow Cytometry (BD Bioscience, USA).</p></sec><sec id="Sec8"><title>PDGF-B knockdown by shRNA</title><p id="Par14">Lentivirus-mediated PDGF-B silencing was performed by transfecting 4T1 cells with control shRNA (against scrambled sequence) or mouse PDGF-B shRNA. The transfection procedure was carried out according to the manufacture’s protocol. Positively transfected cells were selected using puromycin, and the silencing efficiency was investigated with the quantitative real-time polymerase chain reaction (PCR). The primers for detecting mRNA level of mouse PDGF-B (NM_011057.3 → NP_035187.2, CCDS: CCDS27656.1) were as follows: the forward primer: 5`-TCTCTGCTGCTACCTGCGTCT-3`, the reverse primer: 5`- CAGCCCCATCTTCATCTACGG -3`.</p></sec><sec id="Sec9"><title>Transcriptome sequencing assay</title><p id="Par15">100 mg tissue samples from the 4T1 tumors in metformin-treated or untreated mice were extracted quickly and then put on the ice, and each sample was immediately cryopreserved with liquid nitrogen. Messenger RNA (mRNA) extraction, cDNA synthesis, PCR enrichment, library construction, quality control and sequencing were performed by Beijing Biomarker Corporation (China, Beijing). 3 independent samples in each group were used for gene expression analysis. Heatmaps were presented to show the change of gene expression levels using Prism 7.0 (GraphPad, USA).</p></sec><sec id="Sec10"><title>Immunofluorescence, Histomorphometry and H&E Staining</title><p id="Par16">Mouse tissues were fixed in 4% PFA for 12 h at 4 °C, and sequentially dehydrated in the 20 and 30% sucrose solutions, respectively. For the 2D and 3D confocal imaging, tissue samples were cut into 6 μm-thick and 40 μm-thick sections, respectively. The prepared sections were stored in a − 80 °C Laboratory Freezer (DW-86L728J, Haier). Single or double immunostaining was performed with the following antibodies. Primary antibodies: CD31 (anti-rabbit, ab28364, Abcam; anti-Rat, ab7388, Abcam), PDGF-B (BA0519–2, Boster), α-SMA (BM0002, Boster), VE-cadherin (No.138101, BioLegend), cl-PARP (#9542, Cell Signaling), PCNA (BM3888, Boster), cl-Caspase-9 (#9542, Cell Signaling), cl-Caspase-3 (#9661, Cell Signaling); NG-2 (R&D, MAB6689). Secondary antibodies: Alexa fluor 488-conjugated Goat anti-Rabbit antibody (A-11008, Invitrogen), Alexa fluor 488-conjugated Goat anti-Rat antibody (A-11006, Invitrogen), DyLight 550-conjugated Donkey anti-Rat antibody (SA5–10027, Invitrogen), Alexa fluor 546-conjugated Goat anti-Rabbit antibody (A-11010, Invitrogen), Alexa fluor 546-conjugated Donkey anti-Mouse antibody (A-10036, Invitrogen), Alexa fluor 647-conjugated Donkey anti-Mouse antibody (A-31571, Invitrogen), Alexa fluor 546-conjugated Goat anti-Rat antibody (A-11081, Invitrogen). Sections were washed with 0.1% PBST, blocked with 5% BSA in PBST at 37 °C for 1 h, and permeabilized with the 0.2% triton X-100 solution for 15–30 min.</p><p id="Par17">For fluorescent 3D-reconstruction, 40 μm-thick sections were treated with the 0.1% trypsin retrieval solution at 37 °C for 15–20 min to get enhanced signal for signal detection. Sections were then incubated with primary antibodies diluted in 5% BSA (0.1% PBST) at 4 °C for no less than 24 h, followed by staining with the appropriate, fluorescently conjugated secondary antibodies. Nuclei were counter-stained by DAPI (2-5 μg/mL) at the room temperature for 15 min before the fluorescent imaging. The fluorescent single- or multi-layer images (2.5–3.5 μm per layer) were obtained using confocal laser scanning microscopy (Leica, German). Software of LAS AF Lite (Leica, German) was used to perform the 3D-reconstrution of CD31 or CD31/α-SMA fluorescent signaling. Furthermore, 5–10 fields (20 x magnification) per tumor were randomly selected and analyzed [<xref ref-type="bibr" rid="CR25">25</xref>].</p><p id="Par18">To observe the perfusion status, perfused vessels were labeled by the intravenous injection of 20 mg/kg Rhodamine-labeled lectin (RL-1102, Vector Labs) 15 min before the intracardiac perfusion of 40 ml 4% paraformaldehyde with a flux of 10 ml/min. Tumors were then extracted, fixed in 4% PFA for 1 h at 4 °C, sequentially dehydrated, embedded in OCT (Tissue-Tek #4583, Sakura Finetek, USA), and cut into 6 μm-thick sections. All perfused or un-perfused vessels were immunostained with anti-CD31 antibodies (ab28364, Abcam) followed by staining with Alexa fluor 488-conjugated Goat anti-Rabbit secondary antibodies (A-11008, Invitrogen). For the observation of the vascular leakage of tumors, 100 mg/kg Fluorescein Isothiocyanate (FITC)-conjugated Dextran (70kD, No.53471, Sigma) was intravenously injected into tumor-bearing mice 10 min before tumors were harvested. To detect tumor hypoxia, 60 mg/kg PIMO (Hypoxyprobe Inc.) was intravenously injected into the tail vein of tumor-bearing mice 90 min before tumors were wholly extracted. PIMO<sup>+</sup> hypoxic cells in tumor sections were then immunostained with anti-PIMO antibody (Hypoxyprobe Inc.) according to the manufacturer’s instructions.</p><p id="Par19">The H&E-stained paraffin sections (4 μm) of those fixed tumors or lung tissues were assessed for tumor necrosis, hemorrhage and metastatic nodules. To observe the chemosensitization, tumor sections from Cisplatin-treated mice were stained with anti-Cisplatin-modified DNA antibody (GTX17412, Genetex). Paraffin-embedded sections were sequentially incubated with secondary antibodies (SV0002, Boster), 3, 3′-diaminobenzidine (DAB, ZLI-9017, ZSGB-Bio) and the hematoxylin (H9627, Sigma) solution.</p></sec><sec id="Sec11"><title>Statistical analysis</title><p id="Par20">Quantitative analysis was performed using the Prism 5.0 or 7.0 software (GraphPad, San Diego, CA). All quantitative data were represented by mean ± SEM. Kolmogorov-Smirnov normality test was performed to analyze the normal distribution, and coefficient of variation (CV) was used to estimate the variation of data within each group. When CV was greater than 15%, the data was considered to be abnormal. Bartlett’s test was performed for investigating the homogeneity of variances between the groups. For any set of data which was not normally distributed, nonparametric Wilcoxon or Kruskal-Wallis test was performed to investigate the statistical difference between two or multiple independent samples. The statistical significance between two groups and multiple groups was defined as <italic>P</italic> < 0.05 by two-tailed student’s t test or one-way ANOVA t-test. Two-way ANOVA analysis was performed when an additional factor or variant was involved in the experiment.</p></sec></sec><sec id="Sec12"><title>Results</title><sec id="Sec13"><title>Metastatic breast cancers were characterized by an excessively angiogenic and immature vasculature</title><p id="Par21">Both MDA-MB-231 and 4T1 breast cancer cell lines were characterized by distant lung metastasis when orthotopically implanted, thus being selected. To observe the vascular morphology of both tumors, the 3D reconstruction of those CD31-stained vessels was performed. Microvessels in both cancers manifested the strong abilities of sprouting and branching (Fig. <xref rid="Fig1" ref-type="fig">1</xref>a), and were distinctly larger. This kind of vascular phenotype was similar with what was found in angiogenic cancers. It was further confirmed that a large number of vessels were found to be PCNA<sup>+</sup> in 4T1 cancers (53.4%), indicating that endothelial cells (ECs) were proliferative (Fig. <xref rid="Fig1" ref-type="fig">1</xref>b). These data suggested the involvement of excessive angiogenesis in the progression of metastatic breast cancers.<fig id="Fig1"><label>Fig. 1</label><caption><p>Vascular morphology, maturity and functional status of the metastatic breast cancers. 4 T1 and MDA-MB-231 metastatic breast cancer cells were orthotopically injected into the fat pad of mice. (<bold>a</bold>) 3D-reconstruction of CD31<sup>+</sup> vessels in 4 T1 and MDA-MB-231 (MM-231) tumors from untreated mice. Tumor sections were stained with an anti-CD31 antibody. Bars: 100 μm. (<bold>b</bold>) Immunofluorescent double-staining for PCNA (Green) and CD31 (Red) in sections of untreated CT-26 tumors. White arrows indicate PCNA nucleus positive endothelial cells that are proliferating. Nuclei were counterstained with DAPI. Bars: 100 μm. (<bold>c</bold>) Double immunostaining (Left) for CD31 (Green) and α-SMA (Red) in frozen sections of normal breast and 4 T1 tumors, and quantification (right) of percentage of α-SMA<sup>+</sup>/CD31<sup>+</sup> vessels (of CD31<sup>+</sup> vessels; <italic>n</italic> = 8). White and yellow triangles indicate disassociated vascular smooth muscle cells (VSMCs) and associated VSMCs, respectively. Nuclei were counterstained with DAPI. Bars: 100 μm. (<bold>d</bold>) Double immunostaining for CD31 (Green) and NG-2 (Red) in frozen sections of untreated 4 T1 tumors. White triangle indicates the pericyte associated with the vessel wall. Bars: 100 μm. (<bold>e</bold>) Representative images showing FITC-conjugated dextran perfused CD31<sup>+</sup> vessels (Red) in 4 T1 tumors from untreated mice. FITC-conjugated dextran was injected through the tail vein in advance. White triangles indicate CD31<sup>+</sup> vascular lumen containing FITC-Dextran; white arrows indicate dextran leaking outside the vessel wall. Bars: 100 μm. (<bold>f</bold>) Representative image for showing Pimonidazole (PIMO; brown) staining, and quantification of PIMO<sup>+</sup> hypoxic areas in 4 T1 tumors and normal breast of BALB/c mice (Lower Right Corner, <italic>n</italic> = 8). Bars: 100 μm. Quantitative data are indicated as mean ± SEM. ***<italic>p</italic> < 0.001</p></caption><graphic xlink:href="13046_2019_1211_Fig1_HTML" id="MO1"></graphic></fig></p><p id="Par22">Next, we focused on the vascular maturity and function. Vascular lumens in the normal breast tissue were extensively covered by vascular smooth muscle cells (VSMCs, marker: α-SMA), a common vascular mural cell, presenting an inerratic lumen morphology (Fig. <xref rid="Fig1" ref-type="fig">1</xref>c). However, vessels in the 4T1 cancer were poorly covered by VSMCs. Considering that α-SMA was reported to be abundantly expressed in cancer-associated fibroblasts, the pericyte coverage was further examined using a NG-2 antibody. Consistently, only few NG-2<sup>+</sup> pericytes (PCs) covered the vessel lumen (indicated by white triangles in Fig. <xref rid="Fig1" ref-type="fig">1</xref>d). These data suggested that vessels in metastatic breast cancers were structurally immature. It was worth noting that most of VSMCs and PCs were disassociated or detached from the vascular lumen (Fig. <xref rid="Fig1" ref-type="fig">1</xref>c and d).</p></sec><sec id="Sec14"><title>Metastatic breast cancers were hypoxic with leaky vessels</title><p id="Par23">Hypoxia and the vascular leakage of tumors were further investigated, since the poor vascular maturity contributes to both [<xref ref-type="bibr" rid="CR26">26</xref>, <xref ref-type="bibr" rid="CR27">27</xref>]. Vessel leakage was detected by the intravenous injection of the FITC-conjugated Dextran (70kD) and the counterstaining with CD31. In 4T1 cancer, a large amount of FITC-conjugated dextran was found to be located outside the CD31<sup>+</sup> vessel (Fig. <xref rid="Fig1" ref-type="fig">1</xref>e, white arrows), indicating that it was extravasated from the blood vessel to extravascular regions. To observe the hypoxic status, PIMO, a reagent for detecting hypoxia, was intravenously injected to tumor-bearing mice after 2 weeks of administration. Further IHC staining showed that 28.75 ± 5.58% areas were stained by the hypoxic marker PIMO in 4 T1 tumors (Fig. <xref rid="Fig1" ref-type="fig">1</xref>f), while the normal breast tissue was almost devoid of any hypoxic region. As a key regulator of angiogenesis in cancer, hypoxia was then investigated to show if there was a discrepancy in hypoxic areas (%) between hypo- and hyper-vascular regions. As shown in Additional file <xref rid="MOESM1" ref-type="media">1</xref>: Figure S1A and S1B, the hypoxic fraction of the hyper-vascular region was significantly higher than that of the hypo-vascular region. These evidences suggest metastatic breast cancer showed signs of leaky vessel and hypoxia, which were closely associated with the immature vasculature.</p></sec><sec id="Sec15"><title>The cell non-autonomous mechanism of metformin in inhibiting the growth and metastasis of tumors</title><p id="Par24">To bring out the clinical antitumor effect of metformin, its routine clinical dose (about 30 mg/kg•day) widely prescribed in antidiabetic use was increased to 225 mg/kg•day for anti-tumor use in the mice by the body surface area normalization [<xref ref-type="bibr" rid="CR28">28</xref>]. To exclude any low dose-associated hermetic response to metformin, low dose groups (0.1, 1 and 25 mg/kg•day) were concurrently set up. The dose of 225 mg/kg•day was referred to as the clinically relevant dose of metformin. As shown in Fig. <xref rid="Fig2" ref-type="fig">2</xref>a, 4T1 cancer did not respond to low doses of metformin (0.1, 1 and 25 mg/kg•day), indicating the absence of any hermetic dose response for taking metformin. Compared to the control, metformin at a dose of 225 mg/kg•day significantly reduced the growth of 4T1 cancers by 63.7% (Fig. <xref rid="Fig2" ref-type="fig">2</xref>a and b).<fig id="Fig2"><label>Fig. 2</label><caption><p>Effects of metformin on the growth and metastasis of the metastatic breast cancers. (<bold>a</bold> and <bold>b</bold>) Growth curve (cm<sup>3</sup>) and measurement of weight (g) of 4 T1 tumors from BALB/c mice untreated or treated with metformin at different concentrations (0.1, 1, 25 and 225 mg/kg•day; <italic>n</italic> = 8). (<bold>c</bold> and <bold>d</bold>) H&E staining for 4 T1 primary tumor lung metastasis, and quantification of 4 T1 metastatic index (metastatic nodules per gram of the primary tumor; n = 8). Blue arrows indicate metastatic nodules in lung. (<bold>e</bold>) Representative images of in vitro colonization of 4 T1 cancer cells, which were untreated or persistently treated with 50 μM or 100 μM metformin (repeated for 5 times). Cancer cells were inoculated into each well of a 6-well culture plate. (<bold>f</bold>) Bar graphs showing reduced lung weight, and comparable weights of liver and spleen of mice untreated or treated with metformin at concentration of 225 mg/kg•day or 25 mg/kg•day (<italic>n</italic> = 6). Organ weight was normalized for body weight. (<bold>g</bold>) In vitro proliferation curve of 4 T1 cancer cells untreated or treated with metformin at concentrations of 50 or 100 μM (repeated for 5 times). (<bold>h</bold>) Representative images showing 4 T1 cancer cell migration in vitro, and quantification of migrated cancer cells per 400 X field (<italic>n</italic> = 5). (I) H&E staining of paraffin-processed tumor tissues from metformin-treated or untreated mice, showing the comparably direct invasion of cancer cells to the peritumoral muscle. Black arrows indicate muscle fibers penetrating into the tumor. Bars: 200 μm. Quantitative data are indicated as mean ± SEM. **<italic>p</italic> < 0.01; ***p < 0.001</p></caption><graphic xlink:href="13046_2019_1211_Fig2_HTML" id="MO2"></graphic></fig></p><p id="Par25">Furthermore, the clinically relevant dose of metformin also greatly decreased the lung metastasis index by 53.9% (Fig. <xref rid="Fig2" ref-type="fig">2</xref>c and d). As the metastasis index indicates the number of metastatic nodules per gram of the primary tumor, the inhibition of tumor metastasis may be independent of the direct suppression of the primary tumor growth. Intriguingly, however, metformin did not alter the in vitro colonization of 4T1 cells (Fig. <xref rid="Fig2" ref-type="fig">2</xref>e), while inducing great suppression of the metastatic burden of the lungs (Fig. <xref rid="Fig2" ref-type="fig">2</xref>f), but not of the liver or the spleen.</p><p id="Par26">Then, it was explored whether metformin directly affected the proliferation and the metastasis of breast cancer cells. Since the plasma concentration of metformin was estimated to be approximately 60 μM in patients, both 50 μM and 100 μM concentrations were used for further in vitro analyses. At both doses, metformin did not alter the proliferation and the migration of breast cancer cells in vitro (Fig. <xref rid="Fig2" ref-type="fig">2</xref>g and h). In addition, metformin-treated 4 T1 cancers did not have the same sharp, demarcated borders as the control (Fig. <xref rid="Fig2" ref-type="fig">2</xref>i), indicating that metformin had no effect on the direct invasion of cancer cells to the peritumoral muscle. Overall, these data suggested that the antimetastatic and antiproliferative effects of metformin probably were not mediated by a cancerous cell-autonomous mechanism.</p></sec><sec id="Sec16"><title>Metformin enhanced the susceptibility of breast cancer cells to chemotherapy</title><p id="Par27">Vascular maturity and functionality have been reported to be associated with chemosensitization. Therefore, the effects of the metformin pretreatment on in vivo sensitivity of cancer cells to low-dose cyclophosphamide (CTX, 20 mg/kg•day) was investigated. Tumor-bearing mice were orally pretreated with metformin starting from the seventh day after inoculation. Compared to the single CTX treatment, the pretreatment combining of CTX and metformin resulted in a more significant anticancer effect and greatly prolonged the survival time of the tumor-bearing mice (Fig. <xref rid="Fig3" ref-type="fig">3</xref>a and b). This metformin-mediated chemosensitization was accompanied by the aggravation of tumor necrosis and hemorrhage (Fig. <xref rid="Fig3" ref-type="fig">3</xref>c-e).<fig id="Fig3"><label>Fig. 3</label><caption><p>The in vivo effects of metformin pretreatment on cancer responses to cyclophosphamide (CTX). (<bold>a</bold> and <bold>b</bold>) Growth curve and survival curve of 4 T1 cancers from mice untreated or treated with metformin (225 mg/kg•day), low dose CTX (Cyclophosphamide, 20 mg/kg•day) or the combined treatment (<italic>n</italic> = 8). Mice were pretreated with metformin for 5 days before receiving CTX. (C-E) (<bold>c</bold>) H&E staining of sections of 4 T1 cancers, and quantification of (<bold>d</bold>) necrotic and (<bold>e</bold>) hemorrhagic areas, revealing enhanced cancer responses to CTX by metformin pretreatment (n = 8). “N” indicates “Necrosis”; black arrows indicate hemorrhage; “C & M” indicates the combination of CTX and metformin. Bars: 200 μm. (<bold>f</bold>) Double staining for CD31 and PARP of 4 T1 tumor sections, and quantification of (<bold>g</bold>) PARP<sup>+</sup> CD31<sup>+</sup> cancer cells and (<bold>h</bold>) PARP<sup>+</sup> CD31<sup>+</sup> vessels (n = 8). Tumor-bearing mice were treated with metformin (pretreatment for 5 days), CTX or combined treatment. White arrows indicate PARP<sup>+</sup> endothelial cells (ECs); yellow triangles indicate PARP<sup>+</sup> cancer cells. (<bold>i</bold>) Representative images showed increased cisplatin-DNA adducts in 4 T1 tumors from metformin pre-treated mice (225 mg/kg•day, lasting for 5 days). After that, mice were treated with intraperitoneal injections of cisplatin (CPT, 5 mg/kg, every 2 days). The right column refers to the reverse-color image of the left column. Red arrows indicate the cells with positive cisplatin-DNA adducts. Magnification:200Х. (<bold>j</bold>) Quantification of cells with nuclear cisplatin adduct in 4 T1 cancers (<italic>n</italic> = 8). (<bold>k</bold>) Quantification of PI<sup>+</sup> necrotic ECs and 4 T1 cells in vitro upon combined 4-OH (activated CTX) treatment (n = 5). Quantitative data are indicated as mean ± SEM. *<italic>p</italic> < 0.05; **<italic>p</italic> < 0.01; ***<italic>p</italic> < 0.001</p></caption><graphic xlink:href="13046_2019_1211_Fig3_HTML" id="MO3"></graphic></fig></p><p id="Par28">Double staining for CD31 and cl-PARP further verified the phenomenon described above. Compared to single CTX group, the combined metformin pretreatment resulted in a significant increase of the number of cl-PARP<sup>+</sup> 4T1 cells (Fig. <xref rid="Fig3" ref-type="fig">3</xref>f-h). Interestingly, most of these apoptotic cancer cells were located close to CD31<sup>+</sup> vessels, suggesting the involvement of the vascular mechanism in the enhancement of the toxicity of chemo-drug. It is worth noting that the combined metformin pretreatment did not increase the proportion of PARP<sup>+</sup> vessels in 4T1 cancer (Fig. <xref rid="Fig3" ref-type="fig">3</xref>h). Furthermore, metformin pretreatment significantly increased the number of cisplatin-DNA adduct-positive 4T1 tumor cells (Red arrows; Fig. <xref rid="Fig3" ref-type="fig">3</xref>i and j), suggesting that more cytotoxic drugs were delivered to the tumor. More importantly, metformin did not have the potential to enhance CTX-induced cell necrosis (indicated by propidium iodide (PI)<sup>+</sup> cells, Fig. <xref rid="Fig3" ref-type="fig">3</xref>k) in vitro.</p></sec><sec id="Sec17"><title>Metformin inhibited angiogenesis and improved vascular maturity</title><p id="Par29">Angiogenesis inhibition is one of the mechanisms suppressing the tumor growth [<xref ref-type="bibr" rid="CR29">29</xref>, <xref ref-type="bibr" rid="CR30">30</xref>]. Therefore, it was then investigated whether metformin affects breast cancer angiogenesis. CD31 staining for microvessels showed that normal dose of metformin (225 mg/kg) significantly reduced the micro-vessel density (MVD) and vascular branching points (Fig. <xref rid="Fig4" ref-type="fig">4</xref>a-c). The sprouting ability of the micro-vessels in metformin-treated 4T1 tumors were weaker than in the control group (Fig. <xref rid="Fig4" ref-type="fig">4</xref>a), while the CD31 signal intensity did not differ between groups (Fig. <xref rid="Fig4" ref-type="fig">4</xref>d). In addition, metformin induced a shift of the size of the tumor vessels towards a smaller one (Fig. <xref rid="Fig4" ref-type="fig">4</xref>e).<fig id="Fig4"><label>Fig. 4</label><caption><p>Effects of the metformin administration on angiogenesis and the vascular maturity. (<bold>a</bold>) CD31 immunostaining in sections of 4T1 tumors from mice untreated or treated with metformin at concentrations of 25 mg/kg•day or 225 mg/kg•day. White arrows indicate vascular sprouts of microvessels. Bars: 100 μm. (B and C) quantifications of vascular (<bold>b</bold>) sprouts and (<bold>c</bold>) branches (per mm<sup>2</sup>; <italic>n</italic> = 8). (<bold>d</bold>) Quantification of mean fluorescent intensity of CD31 signaling of vessels in 4 T1 tumors (n = 8), revealing the unaffected CD31 expression level of vessels. (<bold>e</bold>) Analyzes of diameter distribution of vessels in 4T1 tumors from untreated or metformin-treated mice (<italic>n</italic> = 8). (<bold>f</bold>) Double immunostaining for CD31 (Green) and α-SMA (Red) in frozen sections of 4T1 tumors from untreated or metformin-treated mice, and (<bold>g</bold>) quantification of percentage of α-SMA<sup>+</sup> CD31<sup>+</sup> vessels (of CD31<sup>+</sup> vessels; n = 8). White arrows indicate vessels with VSMCs coverage; yellows arrows indicate VSMCs disassociated with vessels. Bars: 100 μm. (<bold>h</bold>) Double immunostaining for CD31 and VE-cadherin of 4T1 tumor sections, revealing continuous and more abundant in metformin-treated than untreated tumors. Bars: 50 μm. (<bold>i</bold>) Double staining for CD31 (green) and NG-2 (red), revealing more vessels with pericyte coverage in metformin-treated than untreated MDA-MB-231 (MM-231) tumors. White and yellow arrows indicate pericytes disassociated and associated with vessels, respectively; white triangles indicate pericytes that are partially associated with vessels. Bars: 100 μm. (<bold>j</bold>) Quantification of NG-2<sup>+</sup> CD31<sup>+</sup> vessels (of CD31<sup>+</sup> vessels) in MDA-MB-231 tumors (<italic>n</italic> = 8). Quantitative data are indicated as mean ± SEM. *<italic>p</italic> < 0.05; **<italic>p</italic> < 0.01; ***<italic>p</italic> < 0.001</p></caption><graphic xlink:href="13046_2019_1211_Fig4_HTML" id="MO4"></graphic></fig></p><p id="Par30">The inhibition of angiogenesis can often be accompanied by a change of vascular maturity [<xref ref-type="bibr" rid="CR31">31</xref>, <xref ref-type="bibr" rid="CR32">32</xref>]. VSMCs and pericytes coverage, the status of the vascular basement membrane and the signatures of vascular maturity [<xref ref-type="bibr" rid="CR4">4</xref>] were observed by the staining of α-SMA, NG-2 and VE-Cadherin. Metformin-treated 4T1 tumors exhibited a higher percentage of vessels with α-SMA<sup>+</sup> VSMCs coverage (White arrows, Fig. <xref rid="Fig4" ref-type="fig">4</xref>f and g). It is worth noting that metformin-treated 4T1 tumors had fewer VSMCs disassociated with vessels than those of the control (Yellow arrows, Fig. <xref rid="Fig4" ref-type="fig">4</xref>f). In addition, less VSMCs disassociated with vessels were found in 4T1 tumors of the metformin-treated mice. Metformin administration shifted the discontinuous VE-Cadherin<sup>+</sup> vascular basement membrane towards a continuous phenotype while increasing its abundance (Fig. <xref rid="Fig4" ref-type="fig">4</xref>h). Consistently, metformin treatment resulted in a significant increase of the percentage of vessels with the coverage of NG-2<sup>+</sup> pericytes in orthotopic MDA-MB-231 tumors (Fig. <xref rid="Fig4" ref-type="fig">4</xref>i and j).</p></sec><sec id="Sec18"><title>Metformin improved the vascular functionality of metastatic breast cancers</title><p id="Par31">Structural maturity is closely associated with the vascular functional status [<xref ref-type="bibr" rid="CR33">33</xref>]. We then focused on the effect of the administration of metformin on the perfusion status. A TRITC-conjugated Lectin, which can bind to the surface of ECs lining along the blood flow, was intravenously injected. Critically, both metformin-treated 4T1 and MDA-MB-231 tumors exhibited significantly higher percentage of Lectin<sup>+</sup> vessels than those of the control (White arrows, Fig. <xref rid="Fig5" ref-type="fig">5</xref>a-d). This functional improvement was further validated by the fact that metformin greatly decreased tumor hypoxia (Fig. <xref rid="Fig5" ref-type="fig">5</xref>e and f), indicated by reduced positive areas of pimonidazole (PIMO). Furthermore, vessels in metformin-treated tumors were less leaky than in the control group (Fig. <xref rid="Fig5" ref-type="fig">5</xref>g). Collectively, these findings suggested that metformin improved the vessel functionality by increasing the vascular perfusion and decreasing the vascular leakiness, thus serving as a mediator for the normalization of breast cancer vessels.<fig id="Fig5"><label>Fig. 5</label><caption><p>Effects of metformin administration on hypoxia and the vascular functionality. (<bold>a</bold>-<bold>d</bold>) Representative images showing more lectin-perfused CD31<sup>+</sup> vessels in metformin-treated than untreated (A) 4T1 and (<bold>c</bold>) MDA-MB-231 cancers (n = 8). TRITC-conjugated lectin (Red) was intravenously injected into tail veins 15 min before the sacrifice. Tumor sections were further immunostained with anti-CD31 antibody (Green). White arrows indicate CD31<sup>+</sup> vessels with lectin perfusion. Higher (B) percentage (of CD31<sup>+</sup> vessels) and (<bold>d</bold>) density (per mm<sup>2</sup>) of Lectin<sup>+</sup> CD31<sup>+</sup> vessels in metformin-treated than untreated tumors. Bars: 100 μm. (<bold>e</bold>) Immunohistochemical staining for pimonidazole (PIMO; brown) and (<bold>f</bold>) quantification of PIMO<sup>+</sup> hypoxic area in 4 T1 cancers from untreated or metformin-treated mice, revealing ameliorated tumor hypoxia by metformin (n = 8). Bars: 500 μm. (<bold>g</bold>) Representative images showing decreased vascular leakage in metformin-treated than untreated 4 T1 tumors. FITC-dextran (green) was injected through tail vein in advance. Tumor sections was counterstained with anti-CD31 antibody (Red). White triangles indicate the dextran leaking outside the vessel wall. Bars: 100 μm. Quantitative data are indicated as mean ± SEM. *<italic>p</italic> < 0.05</p></caption><graphic xlink:href="13046_2019_1211_Fig5_HTML" id="MO5"></graphic></fig></p></sec><sec id="Sec19"><title>Metformin downregulated tumoral PDGF-B and reduced the vascular compression</title><p id="Par32">Efforts were further devoted to the gaining of mechanistic insights into the metformin-induced vessel normalization. Excessive pro-angiogenic factors contributed to the abnormal angiogenesis [<xref ref-type="bibr" rid="CR34">34</xref>, <xref ref-type="bibr" rid="CR35">35</xref>], resulting in an immature vasculature [<xref ref-type="bibr" rid="CR36">36</xref>], which thus motivated us to investigate the underlying mechanism with a special focus on angiogenic factors. Results of the angiogenesis protein array showed that metformin treatment resulted in a great reduction of PDGF-B protein levels of 4T1 cancer cells in vitro (Fig. <xref rid="Fig6" ref-type="fig">6</xref>a and b), while the protein levels of some other factors were slightly affected. To validate this initial screening result, RNA sequencing was performed to detect the change of those affected factors in vivo. Expression levels of endoglin, endostatin, MMP-9 and osteopontin were higher than 50 FPKM (Fig. <xref rid="Fig6" ref-type="fig">6</xref>c), but not greatly affected. Among PDGFs, the expression of PDGF-B was the most significantly decreased (Fig. <xref rid="Fig6" ref-type="fig">6</xref>d), indicating the initial high PDGF-B expression in 4T1 cells. Consistently, metformin treatment resulted in a great reduction in the PDGF-B signal intensity of 4T1 tumors (Fig. <xref rid="Fig6" ref-type="fig">6</xref>e). These results were consistent with the finding of our previously published article that metformin reduced the PDGF-B signal intensity in the peri-necrotic regions of the 4 T1 tumor [<xref ref-type="bibr" rid="CR37">37</xref>]. Overall, these data suggested PDGF-B downregulation was deeply involved in metformin’s vascular remodeling effects.<fig id="Fig6"><label>Fig. 6</label><caption><p>Downregulation of PDGF-B by the metformin treatment. (<bold>a</bold>) Immunoblotting for cancer cell-derived angiogenic factors using mouse angiogenesis arrays, and (<bold>b</bold>) quantification of grey intensity of each factor (independent of 3 experiments). Cancer cells were treated with metformin (100 μM) for 48 h. (<bold>c</bold>) Column chart for showing the transcriptional levels of angiogenesis-related factors. FPKM indicates Fragments Per Kilobase of transcript per Million fragments mapped. Met indicates metformin; Met1, Met2 and Met3 indicate different reports of data of independent tumors in metformin group. (<bold>d</bold>) Heatmap analysis of the effect of metformin on transcriptional levels of top 9 angiogenesis-related genes of 4T1 tumors (<italic>n</italic> = 3). The fold change ranges from − 0.5 to 0.5. “Sig.” indicates “Significance”. (<bold>e</bold>) Double immunostaining for CD31 and PDGF-B in 4T1 orthotopically implanted tumors (Left). shRNA-PDGF-B- and shRNA-Control-transfected 4T1 tumor-bearing mice received control or metformin treatment (225 mg/kg•day). Quantification of PDGF-B fluorescent intensity and microvessel density (Right; n = 8). (<bold>f</bold>) Immunostaining for CD31 and α-SMA in 4T1 cancers, revealing increased percentage of patent microarteries (n = 8). White arrows indicate the compressed lumen of arteries distributed in 4T1 cancer stroma. (<bold>g</bold>-<bold>h</bold>) Survival curve for analyzing the association of PDGF-B mRNA expression in primary breast tumor with survival probability of patients with breast cancer (<bold>g</bold>). PDGF-B mRNA levels was positively correlated with mRNA level of CD31, but not PCNA and Ki-67. Data was obtained from TCGA dataset. 1064 samples were included. FPKM: Fragments Per Kilobase of transcript per Million fragments mapped. Quantitative data are indicated as mean ± SEM. “ns” indicates not statistically significant; *<italic>p</italic> < 0.05; **<italic>p</italic> < 0.01; ***<italic>p</italic> < 0.001</p></caption><graphic xlink:href="13046_2019_1211_Fig6_HTML" id="MO6"></graphic></fig></p><p id="Par33">PDGF-B has been demonstrated to increase the interstitial fluid pressure (IFP), which is assumed to compress the intratumoral vessels [<xref ref-type="bibr" rid="CR38">38</xref>], thus affecting the vascular functionality. In 4T1 tumors of the control group, those major arteries with multiple layers and VSMCs coverage were found to be severely compressed (Fig. <xref rid="Fig6" ref-type="fig">6</xref>f), with only very few arteries were patent with open lumen. Compared to the control group, the percentage of patent vessels was significantly elevated in 4T1 tumors of the metformin group (Fig. <xref rid="Fig6" ref-type="fig">6</xref>f). PDGF-B signaling has been reported to regulate the interstitial fluid pressure accompanied with the hyper-activated Hippo signaling. As was expected, the expression level of YAP was decreased by metformin in 4 T1 tumors (Additional file <xref rid="MOESM1" ref-type="media">1</xref>: Figure S1C). These evidences suggested that the down-regulation of PDGF-B by metformin might be contributed to reduce the compression of cancer cells to vessels.</p></sec><sec id="Sec20"><title>High PDGF-B expression was associated with poor prognosis and high CD31 expression</title><p id="Par34">To determine if PDGF-B expression is associated with prognosis in female patients with breast cancers, the published TCGA dataset containing both gene expression and survival data was employed. 1064 patients were divided into high (≥10.14 FPKM) and low (< 10.14 FPKM) PDGF-B expression groups. High PDGF-B mRNA expression levels were associated with a significantly decreased 5-year survival rate (Fig. <xref rid="Fig6" ref-type="fig">6</xref>g). Further analysis for the relationship between mRNA levels of PDGF-B, PCNA, Ki-67 and CD31 was performed to investigate what contributed to the poor prognosis. Both PCNA and Ki-67 mRNA levels were not correlated with PDGF-B mRNA levels (Fig. <xref rid="Fig6" ref-type="fig">6</xref>h). Interestingly, increased CD31 mRNA levels were associated with significantly increased PDGF-B mRNA levels (Fig. <xref rid="Fig6" ref-type="fig">6</xref>h). These evidences suggested the contribution of PDGF-B to poor prognosis was associated with the vascular mechanism, but not the direct proliferative promotion of breast cancer cells.</p></sec><sec id="Sec21"><title>PDGF-B knockdown in breast cancers with high PDGF-B expression improved vascular maturity and function</title><p id="Par35">To further validate if PDGF-B downregulation mediates the vessel normalization in cancers with PDGF-B expression, 4T1 cells were transfected by lentiviral shRNA-PDGF-B. As shown in Fig. <xref rid="Fig6" ref-type="fig">6</xref>e, PDGF-B knockdown greatly decreased the mean fluorescent PDGF-B intensity from 20.7 to 6.2 pixels in the sections of implanted tumors (Fig. <xref rid="Fig6" ref-type="fig">6</xref>e), indicating a successful knockdown of PDGF-B. Furthermore, PDGF-B knockdown markedly reduced the MVD and CD31<sup>+</sup> areas of 4T1 cancers compared with the control group (Fig. <xref rid="Fig7" ref-type="fig">7</xref>a and b), suggesting the angiogenic effect of tumoral PDGF-B level. Similar with metformin, PDGF-B knockdown significantly increased percentages of α-SMA<sup>+</sup> vessels and VSMCs, demonstrating the improved vascular maturity (Fig. <xref rid="Fig7" ref-type="fig">7</xref>a and b). In addition, vessels in shRNA-PDGF-B 4 T1 tumors were less leaky than those in shRNA-Con tumors (Fig. <xref rid="Fig7" ref-type="fig">7</xref>c), and there were more Lectin-perfused vessels in shRNA-PDGF-B 4 T1 tumors (Fig. <xref rid="Fig7" ref-type="fig">7</xref>d).<fig id="Fig7"><label>Fig. 7</label><caption><p>Effects of PDGF-B knockdown on metastasis, chemosensitization and vascular maturity and functionality. (<bold>a</bold>) Double staining for CD31 (green) and α-SMA (red) of 4T1 tumor sections. shRNA-PDGF-B- and shRNA-Control-transfected 4 T1 tumor-bearing mice received control, metformin (225 mg/kg), imatinib (60 mg/kg) for the combined treatment. Fluorescent signaling of series thin-layer scanning were reconstructed for 3D observation of VSMCs on vessels. VSMCs No. is at the bottom of the panel and indicated as mean ± SEM (n = 8). (<bold>b</bold>) Quantification of ratio of α-SMA<sup>+</sup> area/CD31<sup>+</sup> area (upper), CD31<sup>+</sup> area per μm<sup>2</sup> (middle) and percentage of α-SMA<sup>+</sup> VSMCs associated with vessels (bottom) in 4 T1 cancers (n = 8). (<bold>c</bold>) Representative images showing decreased vascular leakage in shRNA-PDGF-B- than shRNA-Con-transfected 4T1 tumors. Fitc-dextran (green) was injected through tail vein 10 mins before sacrifice. Tumor sections was counterstained with anti-CD31 antibody (Red). White arrows indicate the dextran leaking outside the vessel wall. Bars: 100 μm. (<bold>d</bold>) Representative images showing more lectin-perfused CD31<sup>+</sup> vessels in shRNA-PDGF-B- than shRNA-Con-transfected 4T1 tumors (n = 8). Red: perfused lectin; Green: CD31<sup>+</sup> vessels. White arrows indicate CD31<sup>+</sup> vessels with lectin perfusion. Percentage of Lectin<sup>+</sup>/CD31<sup>+</sup> vessels (of CD31<sup>+</sup> vessels) is indicated as mean ± SEM (at the bottom of the panel). (<bold>e</bold>) H&E staining of sections of 4T1 cancers (Left) and quantification of necrotic and hemorrhagic areas (Right; n = 8). shRNA-PDGF-B or shRNA-Con-transfected 4T1 tumor-bearing mice received low dose CTX (20 mg/kg•day). “N” indicates “necrosis”; black arrows indicate tumor hemorrhage. (<bold>f</bold>) Decreased primary tumor lung metastasis in mice bearing shRNA-PDGF-B 4T1 cancer cells than that in mice bearing shRNA-Con 4T1 cells. (Upper) H&E staining for 4T1 tumor sections; (Lower) quantification of 4T1 metastatic index (metastatic nodules per gram of primary tumor; n = 8). Red asterisk indicates lung metastasis nodule. Magnification: 200Х. (<bold>g</bold>) Schematic diagram of metformin-induced vascular remodeling in metastatic breast cancers. Metastatic breast cancers are angiogenic with hypoperfusion and vascular immaturity, which contribute to vascular leakage, chemoresistance, hypoxia and distant metastasis. By decreasing PDGF-B of those metastatic breast cancers, metformin inhibits angiogenesis and improved the vascular maturity and functionality, therefore improving the chemosensitivity and reducing the distant metastasis</p></caption><graphic xlink:href="13046_2019_1211_Fig7_HTML" id="MO7"></graphic></fig></p></sec><sec id="Sec22"><title>PDGF-Rβ blockade abrogated metformin’s vascular remodeling effects</title><p id="Par36">PDGFR-β is the receptor of PDGF-B and has been extensively studied for its critical role in vascular remodeling. Therefore, we then focused on exploring whether PDGF-Rβ was involved in metformin’s vascular remodeling effects. Imatinib, a drug that can specifically block PDGFR-β signaling, was used in this study. Similar to sh-PDGF-B and metformin, PDGFR-β blockade by imatinib led to decreased CD31<sup>+</sup> areas and an increased vascular coverage of VSMCs (Fig. <xref rid="Fig7" ref-type="fig">7</xref>a and b). Surprisingly, imatinib apparently abrogated the metformin-induced increase of the VSMCs coverage on vessels (Fig. <xref rid="Fig7" ref-type="fig">7</xref>a and d), indicating the involvement of PDGFR-β signaling in metformin’s vascular remodeling effects. Notably, the combination of imatinib and metformin decreased the percentage of VSMCs associated with vessels to a comparable level of the shRNA control group (Figure7B). These evidences suggested that PDGFR-β is indispensable for the subsequent vascular remodeling when PDGF-B was downregulated.</p></sec><sec id="Sec23"><title>PDGF-B knockdown improved the chemosensitization of CTX and reduced lung metastasis</title><p id="Par37">As PDGF-B knockdown induces the vessel normalization, we then investigated whether PDGF-B knockdown improves the chemosensitization and limits the primary lung metastasis of breast tumors. As shown in Fig. <xref rid="Fig7" ref-type="fig">7</xref>e, PDGF-B knockdown induced a slight reduction in 4T1 cancer necrosis without affecting hemorrhage. When treated with CTX, shRNA-PDGF-B 4T1 cancers exhibited a significant increase in both tumor necrosis and hemorrhage compared with those in the shRNA control group (Fig. <xref rid="Fig7" ref-type="fig">7</xref>e). Since increased blood perfusion can bring more drugs into the tumor tissue, these findings thus suggest that the inhibition of tumoral PDGF-B enhances chemosensitization by increasing the drug delivery owing to the improved vascular function. In further characterization of the primary lung metastasis (Fig. <xref rid="Fig7" ref-type="fig">7</xref>f), the metastatic index of the shRNA PDGF-B group was significantly reduced, compared to the shRNA control group.</p></sec></sec><sec id="Sec24"><title>Discussion</title><p id="Par38">Bevacizumab, an AAD approved at an early time, did not significantly improve the overall survival of patients with metastatic breast cancers [<xref ref-type="bibr" rid="CR9">9</xref>, <xref ref-type="bibr" rid="CR39">39</xref>]. Bevacizumab was initially designed to neutralize the VEGF, thus inhibiting VEGFR-2-mediated angiogenesis and tumor growth. However, as previously reported, metastatic breast cancer cells had high expressions of several other pro-angiogenic factors in addition to VEGF [<xref ref-type="bibr" rid="CR40">40</xref>], such as FGF-2, Ang-2 and PDGF-B [<xref ref-type="bibr" rid="CR37">37</xref>]. Thus, in theory, AADs designed for targeting a single factor may be not enough [<xref ref-type="bibr" rid="CR41">41</xref>], which offers an explanation for AAD’s ineffectiveness in treating cancers derived from some organ systems. Our laboratory previously found that metformin inhibited the expression of VEGF, Ang-2 and FGF-2 in a metastatic breast cancer model [<xref ref-type="bibr" rid="CR37">37</xref>]. Besides, PDGF-B was screened out by transcriptome sequencing, and angiogenesis was greatly inhibited by PDGF-B knockdown. This result was validated by the clinical data that the PDGF-B expression level was positively associated with the CD31 expression level. Due to these findings, metformin should be considered as a reagent with a broad range of targeted factors possibly more available than the conventional AADs.</p><p id="Par39">Another disadvantage of traditional AADs is the excessive pruning of the tumor vasculature [<xref ref-type="bibr" rid="CR20">20</xref>], thus leading to the hypoxia-mediated tumor cell dissemination [<xref ref-type="bibr" rid="CR42">42</xref>, <xref ref-type="bibr" rid="CR43">43</xref>]. Compared to AADs, metformin has more angiogenic targets, such as VEGF, PDGF-B and FGF-2. Therefore, metformin is assumed to prune the breast cancer vasculature more excessively. However, to date, it has not been reported that metformin aggravated tumor hypoxia [<xref ref-type="bibr" rid="CR44">44</xref>]. Consistently, metformin ameliorated the hypoxia of two metastatic breast cancers, while MVD was greatly reduced. These evidences suggest there exists a mechanism independent of affecting the vasculature, which is accountable for the ameliorated hypoxia. Metformin is an AMPK activator that induces energetic stress [<xref ref-type="bibr" rid="CR45">45</xref>]. In this condition, tumor cells were metabolically reprogrammed to consume less oxygen, thus counteracting or reversing the vascular pruning-induced hypoxia [<xref ref-type="bibr" rid="CR44">44</xref>].</p><p id="Par40">Currently, the issue of tumoral PDGF-B’s effect on the vascular maturity has become controversial [<xref ref-type="bibr" rid="CR46">46</xref>]. Platelet-derived growth factor B (PDGF-B), a member of the PDGFs family [<xref ref-type="bibr" rid="CR46">46</xref>], binds to its receptors, such as PDGF receptor β (PDGFR-β), to induce the cell survival, proliferation and migration [<xref ref-type="bibr" rid="CR47">47</xref>]. It is now widely accepted that the endothelial PDGF-B regulates the recruitment of PCs [<xref ref-type="bibr" rid="CR47">47</xref>]. Thus, the downregulation of PDGF-B should reduce the vascular maturity. However, PDGF-B was highly expressed by some tumors [<xref ref-type="bibr" rid="CR48">48</xref>, <xref ref-type="bibr" rid="CR49">49</xref>], which were inversely characterized by an excessively angiogenic and immature vasculature. Further blockade of PDGF-B/PDGFR-β significantly increased the vascular maturity of tumors with high PDGF-B expression [<xref ref-type="bibr" rid="CR49">49</xref>], but reduced that of tumors with low PDGF-B expression. These evidences indicated that high and low expression of PDGF-B in tumors might have opposite effects on vascular maturity. To date, this mechanism has not been reported in studies on metastatic breast cancers. Herein, it was found that high PDGF-B expression was detected in the metastatic breast cancer model. By reducing tumoral PDGF-B, the metformin treatment resulted in the suppression of angiogenesis and a more mature vasculature of metastatic breast cancers, thus limiting the distant metastasis and improving chemosensitization. These evidences are further supported by the poor prognosis of patients with breast cancers of high PDGF-B expression. These data indicate that the downregulation of PDGF-B in tumors with high expression of PDGF-B inhibits angiogenesis and improves the vascular functionality and maturity.</p><p id="Par41">As early as in 1970’s, biguanides were reported to potentiate the antitumor effects of CTX and other chemo-drugs in vivo [<xref ref-type="bibr" rid="CR21">21</xref>]. As shown in a recent clinical trial [<xref ref-type="bibr" rid="CR50">50</xref>], diabetic patients receiving metformin had a greater response rate to chemo-drug than non-diabetic patients. Despite the increasing efforts that have been made [<xref ref-type="bibr" rid="CR22">22</xref>], it was still unclear whether or how metformin sensitizes cancer cells to chemo-drugs. Recently, metformin has been demonstrated to directly enhance the toxicity of chemo-drugs [<xref ref-type="bibr" rid="CR51">51</xref>–<xref ref-type="bibr" rid="CR53">53</xref>]. However, concentrations used in those studies were higher than the blood concentration of patients. In the current paper, metformin was not found to significantly inhibit the proliferation and migration of 4 T1 cancer cells at the blood concentrations in vitro, indicating an indirect chemosensitization mechanism. Furthermore, our results suggest metformin-mediated chemosensitization resulted from the enhancement of drug delivery rather than the direct enhancement of the toxicity of chemo-drug.</p><p id="Par42">Interestingly, metformin pretreatment results in a response of metastatic breast cancer cells to CTX at a lower dose, which was further supported by the increased CPT nucleus adduct<sup>+</sup> cells. Critically, those CTX-induced apoptotic cells were located to the regions adjacent to vessels. Thus, metformin’s chemosensitization effect may be due to the increased delivery of chemo-drugs to the deep tumor. Vessel normalization activity increases the tumor oxygen and reduces the interstitial fluid pressure [<xref ref-type="bibr" rid="CR36">36</xref>, <xref ref-type="bibr" rid="CR54">54</xref>], thus enhancing the generation of oxygen radicals and promoting egress of cytotoxic agents to the perivascular region in tumors. Consistent with the results from other laboratories [<xref ref-type="bibr" rid="CR44">44</xref>], metformin treatment increased tumor oxygenation, reduced tumor hypoxia and improved radiotherapy response. Furthermore, metformin-induced chemosensitization may be contributed by the reduction in tumoral PDGF-B, which mediates resistance by PDGFR-β signaling and increasing IFP [<xref ref-type="bibr" rid="CR55">55</xref>]. It has also been reported that metformin’s chemosensitization effect was contributed by increased uptake of chemotherapeutic by tumor cells [<xref ref-type="bibr" rid="CR56">56</xref>].</p><p id="Par43">Given that metformin has long been used for the treatment of type 2 diabetes mellitus, the results of this research is remarkable in terms of drug re-positioning (DR) [<xref ref-type="bibr" rid="CR57">57</xref>]. DR is a screening for anti-cancer therapeutic effects of conventionally administered medications for non-malignant disorders, which has attracted a great deal of attention as the safety and frequency of side effects of these medicines have been already proven. For a typical instance, ticlopidine (purinergic receptor P2Y12 inhibitor), which is an anti-coagulant drug to prevent the transient ischemic attack (TIA) and stroke, and has been shown to be effective for low-grade glioma and high-grade astrocytoma. This P2Y12 inhibitor increases the intracellular cAMP level and promotes the autophagy flux [<xref ref-type="bibr" rid="CR58">58</xref>]. Notably, tricyclic antidepressants such as imipramine promote autophagy in glioma cells synergistically with this drug by further elevating the intracellular cAMP concentration [<xref ref-type="bibr" rid="CR59">59</xref>].</p><p id="Par44">Metformin activates AMPK signal pathway, which not only decreases insulin resistance in type 2 diabetes mellitus but also blocks AMPK-mediated mTOR activation even in cancer stem cells (CSCs) [<xref ref-type="bibr" rid="CR60">60</xref>]. mTOR signal is regulated by amino-acid transporters [<xref ref-type="bibr" rid="CR61">61</xref>], characterized by the L-type amino acid transporter 1 (LAT1; SLC7A5) and the glutamine/amino acid transporter (ASCT2; SLC1A5), which explains why the AMPK-mTOR axis functions as a sensor of the dynamic change in the nutrient/growth factor microenvironment. Particularly, the leucine uptake via LAT1 activates the mTOR signal pathway leading to poor prognosis. Because EpCAM is a functional CSC marker that forms a complex with amino-acid transporters such as LAT1 [<xref ref-type="bibr" rid="CR62">62</xref>], it is reasonable that the LAT1 expression level would be positively correlated with poor prognosis. Therefore, the LKB1-AMPK-mTOR axis is orchestrated by the amino-acid concentration in the tumor microenvironment, and this axis promotes the metabolic reprogramming of cancer cells in response to the microenvironment [<xref ref-type="bibr" rid="CR58">58</xref>, <xref ref-type="bibr" rid="CR63">63</xref>].</p><p id="Par45">More clinical and pre-clinical evidences should be provided to validate the vascular mechanism, and if metformin targets a broad range of angiogenesis-related factors. As metformin is a drug widely prescribed for metabolic disorder, further efforts should also be devoted to investigating the involvement of the metabolic mechanism and its contribution to ameliorated hypoxia.</p></sec><sec id="Sec25"><title>Conclusions</title><p id="Par46">Our current work provided the pre-clinical evidences for metformin’s effect in remodeling the abnormal breast cancer vasculature. Herein, the antidiabetic agent metformin inhibited the progression of metastatic breast cancers, and induced chemosensitization by a vascular mechanism. By decreasing tumoral PDGF-B, metformin inhibited the excessive angiogenesis and improved the vascular maturity and functionality. The normalized vasculature was with more mural cells coverage and better basement membrane [<xref ref-type="bibr" rid="CR30">30</xref>], thus limiting distant metastasis. As the structure determines the function, improved vascular maturity led to an increase in the blood perfusion of tumors, thus allowing more chemo-drugs or therapeutic particles to be delivered into the tumors [<xref ref-type="bibr" rid="CR64">64</xref>]. On the basis of that, the elucidated vascular mechanism of metformin is of great significance and value for the clinical treatment of metastatic breast cancers.</p></sec><sec sec-type="supplementary-material"><title>Additional file</title><sec id="Sec26"><p><supplementary-material content-type="local-data" id="MOESM1"><media xlink:href="13046_2019_1211_MOESM1_ESM.docx"><label>Additional file 1:</label><caption><p><bold>Figure S1.</bold> Effects of metformin on expression level of YAP and discrepancy in hypoxia between hypo-vascular and hyper-vascular regions. (DOCX 1571 kb)</p></caption></media></supplementary-material></p></sec></sec></body><back><ack><title>Acknowledgements</title><p>We thank Ruiqi Wang and He Chen for their help with section preparation; Pan Li for help with immunohistochemical and fluorescent staining; Nan Dong for help with mouse breeding; Yan Zhang and Mei Xue for their help with the technical support in confocal fluorescent imaging and 3D-reconstruction; Jun Lv and Jie Zheng for their assistance in statistical analysis.</p><sec id="FPar1"><title>Funding</title><p id="Par91">This work was financially supported by Grants from the National Natural Science Foundation of China (No.81672876, No.81602638, No.81602502 and No.81502413), Keypoint Research and Invention Program of Shaanxi Province (No.2017SF017 and No.2016SF196), Nature Science Foundation of Shaanxi Province (No.2016JM8125), and Fundamental Research Funds for the Central Universities (No. xjj2016104).</p></sec><sec id="FPar2" sec-type="data-availability"><title>Availability of data and materials</title><p id="Par92">The TCGA dataset obtained and/or analyzed in the current paper are available from TCGA official website and the corresponding author reasonably requested.</p></sec></ack><notes notes-type="author-contribution"><title>Authors’ contributions</title><p>J.C. Wang and G.Y. Li performed experiments and summarized the results. B. Wang and S.X. Han established the gene knockdown cancer models. X. Sun, Y.W. Shen and C. Zhou prepared cancer tissues and sections for staining. J. Feng, S.Y. Lu and J.L. Liu were in charge of dataset analysis. P.J. Liu and M.D. Wang designed the study, analyzed the results and wrote the manuscript. All authors read and approved the final manuscript.</p></notes><notes><title>Ethics approval and consent to participate</title><p id="Par93">All animal procedures were performed in accordance with animal care committee of Xi’an Jiaotong University. Informed consent for participation was not available.</p></notes><notes><title>Consent for publication</title><p id="Par94">Not applicable.</p></notes><notes notes-type="COI-statement"><title>Competing interests</title><p id="Par95">No potential conflicts of interest were disclosed by all the contributing authors.</p></notes><notes><title>Publisher’s Note</title><p id="Par96">Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.</p></notes><glossary><title>Abbreviations</title><def-list><def-item><term>3D</term><def><p id="Par47">3-dimension</p></def></def-item><def-item><term>4-OH-CTX</term><def><p id="Par48">4-hydroxy-cyclophosphamide</p></def></def-item><def-item><term>AADs</term><def><p id="Par49">Anti-angiogenic drugs</p></def></def-item><def-item><term>ATCC</term><def><p id="Par50">American Type Culture Collection</p></def></def-item><def-item><term>CD31</term><def><p id="Par51">Alternative name of PECAM-1, platelet endothelial adhesion molecule</p></def></def-item><def-item><term>CPT</term><def><p id="Par52">Cisplatin</p></def></def-item><def-item><term>CPT-1</term><def><p id="Par53">Carnitine acyltransferase 1</p></def></def-item><def-item><term>CTX</term><def><p id="Par54">Cyclophosphamide</p></def></def-item><def-item><term>DAB</term><def><p id="Par55">3,3′-diaminobenzidine</p></def></def-item><def-item><term>DAPI</term><def><p id="Par56">4′,6-diamidino-2-phenylindole</p></def></def-item><def-item><term>DMEM</term><def><p id="Par57">Dulbecco modified eagle medium</p></def></def-item><def-item><term>DR</term><def><p id="Par58">Drug re-positioning</p></def></def-item><def-item><term>ECL</term><def><p id="Par59">Enhanced chemiluminescence</p></def></def-item><def-item><term>ECs</term><def><p id="Par60">Endothelial cells</p></def></def-item><def-item><term>EpCAM</term><def><p id="Par61">Epithelial cell adhesion molecule</p></def></def-item><def-item><term>FBS</term><def><p id="Par62">Fetal bovine serum</p></def></def-item><def-item><term>FGF-2</term><def><p id="Par63">Fibroblast growth factor-2</p></def></def-item><def-item><term>GFP</term><def><p id="Par64">Green fluorescent protein</p></def></def-item><def-item><term>H&E staining</term><def><p id="Par65">Hematoxylin and eosin staining</p></def></def-item><def-item><term>HRP</term><def><p id="Par66">Horseradish peroxidase</p></def></def-item><def-item><term>ICLAC</term><def><p id="Par67">International Cell Line Authentication Committee</p></def></def-item><def-item><term>IF</term><def><p id="Par68">Immunofluorescence</p></def></def-item><def-item><term>IFP</term><def><p id="Par69">Interstitial fluid pressure</p></def></def-item><def-item><term>MM-231</term><def><p id="Par70">MDA-MB-231</p></def></def-item><def-item><term>MMP</term><def><p id="Par71">Metalloproteinase</p></def></def-item><def-item><term>MVD</term><def><p id="Par72">Microvessel density</p></def></def-item><def-item><term>OCT</term><def><p id="Par73">Optimal cutting temperature compound</p></def></def-item><def-item><term>PARP</term><def><p id="Par74">Poly-ADP-ribose polymerase</p></def></def-item><def-item><term>PBS</term><def><p id="Par75">Phosphate-buffered solution</p></def></def-item><def-item><term>PCNA</term><def><p id="Par76">Proliferating cell nuclear antigen</p></def></def-item><def-item><term>PCR</term><def><p id="Par77">Polymerase chain reaction</p></def></def-item><def-item><term>PDGF</term><def><p id="Par78">Platelet-derived growth factor</p></def></def-item><def-item><term>PDGFR-β</term><def><p id="Par79">Platelet-derived growth factor receptor-β</p></def></def-item><def-item><term>PFK</term><def><p id="Par80">Phosphofructokinase</p></def></def-item><def-item><term>PI</term><def><p id="Par81">Propidium iodide</p></def></def-item><def-item><term>PIMO</term><def><p id="Par82">Pimonidazole</p></def></def-item><def-item><term>shRNA</term><def><p id="Par83">Small hairpin RNA</p></def></def-item><def-item><term>STR</term><def><p 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