TY - JOUR
T1 - Multivalent bi-specific nanobioconjugate engager for targeted cancer immunotherapy
AU - Yuan, Hengfeng
AU - Jiang, Wen
AU - Von Roemeling, Christina A.
AU - Qie, Yaqing
AU - Liu, Xiujie
AU - Chen, Yuanxin
AU - Wang, Yifan
AU - Wharen, Robert E.
AU - Yun, Kyuson
AU - Bu, Guojun
AU - Knutson, Keith L.
AU - Kim, Betty Y.S.
N1 - Funding Information:
The authors thank P. Anastasiadis, L. Petrucelli, H. Crawford, J. Copland, D. Radisky, T. Gonwa and D. Page and his veterinary team for reagents and helpful discussions. We also thank L. Lewis-Tuffin for her help with flow cytometer and confocal experiments, J. A. Knight, R. Feathers, H.-J. Wen and E. E. Miller for their helpful discussions, and B. Edenfield for her assistance with immunohistological experiments. Finally, we thank C. Wogan from MD Anderson’s Division of Radiation Oncology for editorial contributions and AXS Studio for preparing Fig. 4d. Research reported here was supported by the James C. and Sara K. Kennedy Award from Mayo Clinic (B.Y.S.K), Jorge and Leslie Bacardi Fund for the study of Regenerative Medicine, Mayo Clinic Center for Regenerative Medicine (B.Y.S.K.), Mayo Clinic Center for Individualized Medicine Gerstner Family Award (B.Y.S.K.), Helene Houle Mayo Clinic Career Development Award in Neurologic Surgery (B.Y.S.K.), Mayo Clinic Neuroregenerative Medicine Initiative for Neuro-Oncology Research (B.Y.S.K.), China Scholarships Council (No. 201406100114, H.Y.), DeMars Family Mayo Clinic Development Fund (B.Y.S.K.) and Strawn Family Mayo Clinic Development Fund (B.Y.S.K.).
Funding Information:
The authors thank P. Anastasiadis, L. Petrucelli, H. Crawford, J. Copland, D. Radisky, T. Gonwa and D. Page and his veterinary team for reagents and helpful discussions.We also thank L. Lewis-Tuffin for her help with flow cytometer and confocal experiments, J. A. Knight, R. Feathers, H.-J. Wen and E. E. Miller for their helpful discussions, and B. Edenfield for her assistance with immunohistological experiments. Finally, we thank C.Wogan fromMDAnderson's Division of Radiation Oncology for editorial contributions and AXS Studio for preparing Fig. 4d. Research reported here was supported by the James C. and Sara K. Kennedy Award from Mayo Clinic (B.Y.S.K), Jorge and Leslie Bacardi Fund for the study of Regenerative Medicine, Mayo Clinic Center for Regenerative Medicine (B.Y.S.K.), Mayo Clinic Center for Individualized Medicine Gerstner Family Award (B.Y.S.K.), Helene Houle Mayo Clinic Career Development Award in Neurologic Surgery (B.Y.S.K.), Mayo Clinic Neuroregenerative Medicine Initiative for Neuro-Oncology Research (B.Y.S.K.), China Scholarships Council (No. 201406100114, H.Y.), DeMars Family Mayo Clinic Development Fund (B.Y.S.K.) and Strawn Family Mayo Clinic Development Fund (B.Y.S.K.).
PY - 2017/8/1
Y1 - 2017/8/1
N2 - Tumour-targeted immunotherapy offers the unique advantage of specific tumouricidal effects with reduced immune-associated toxicity. However, existing platforms suffer from low potency, inability to generate long-term immune memory and decreased activities against tumour-cell subpopulations with low targeting receptor levels. Here we adopted a modular design approach that uses colloidal nanoparticles as substrates to create a multivalent bi-specific nanobioconjugate engager (mBiNE) to promote selective, immune-mediated eradication of cancer cells. By simultaneously targeting the human epidermal growth factor receptor 2 (HER2) expressed by cancer cells and pro-phagocytosis signalling mediated by calreticulin, the mBiNE stimulated HER2-targeted phagocytosis and produced durable antitumour immune responses against HER2-expressing tumours. Interestingly, although the initial immune activation mediated by the mBiNE was receptor dependent, the subsequent antitumour immunity also generated protective effects against tumour-cell populations that lacked the HER2 receptor. Thus, the mBiNE represents a new targeted, nanomaterial-immunotherapy platform to stimulate innate and adaptive immunity and promote a universal antitumour response.
AB - Tumour-targeted immunotherapy offers the unique advantage of specific tumouricidal effects with reduced immune-associated toxicity. However, existing platforms suffer from low potency, inability to generate long-term immune memory and decreased activities against tumour-cell subpopulations with low targeting receptor levels. Here we adopted a modular design approach that uses colloidal nanoparticles as substrates to create a multivalent bi-specific nanobioconjugate engager (mBiNE) to promote selective, immune-mediated eradication of cancer cells. By simultaneously targeting the human epidermal growth factor receptor 2 (HER2) expressed by cancer cells and pro-phagocytosis signalling mediated by calreticulin, the mBiNE stimulated HER2-targeted phagocytosis and produced durable antitumour immune responses against HER2-expressing tumours. Interestingly, although the initial immune activation mediated by the mBiNE was receptor dependent, the subsequent antitumour immunity also generated protective effects against tumour-cell populations that lacked the HER2 receptor. Thus, the mBiNE represents a new targeted, nanomaterial-immunotherapy platform to stimulate innate and adaptive immunity and promote a universal antitumour response.
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UR - http://www.scopus.com/inward/citedby.url?scp=85018454897&partnerID=8YFLogxK
U2 - 10.1038/nnano.2017.69
DO - 10.1038/nnano.2017.69
M3 - Article
C2 - 28459470
AN - SCOPUS:85018454897
SN - 1748-3387
VL - 12
SP - 763
EP - 769
JO - Nature Nanotechnology
JF - Nature Nanotechnology
IS - 8
ER -