TY - JOUR
T1 - Stimulating TAM-mediated anti-tumor immunity with mannose-decorated nanoparticles in ovarian cancer
AU - Glass, Evan B.
AU - Hoover, Alyssa A.
AU - Bullock, Kennady K.
AU - Madden, Matthew Z.
AU - Reinfeld, Bradley I.
AU - Harris, Whitney
AU - Parker, Dominique
AU - Hufnagel, Demetra H.
AU - Crispens, Marta A.
AU - Khabele, Dineo
AU - Rathmell, W. Kimryn
AU - Rathmell, Jeffrey C.
AU - Wilson, Andrew J.
AU - Giorgio, Todd D.
AU - Yull, Fiona E.
N1 - Funding Information:
EBG, AAH, KKB, WH, DP, DHH, MAC, AJW, TDG, and FEY were supported in part by NCI/NIH grant R01 CA214043. DHH was also supported in part by a 2018 Burroughs Wellcome Fund Physician-Scientist Institutional Award to Vanderbilt University (ID: 1018894). MZZ was supported in part by NCI grant F30 CA239367 and BIR was supported in part by NCI grant F30 CA247202. JCR was supported in part by NCI/NIH grant R01 CA217987. This project was also supported by a generous gift from Mr. Chris Hill through Anglo-American Charity Ltd. The funding sources had no role in the design of the study, collection, analysis, and interpretation of data, or writing of the manuscript.
Funding Information:
The authors thank Dr. Dmitry Koktysh from VINSE for assistance with FTIR and DLS/zeta potential measurements and Dr. Donald Stec from the Small Molecule NMR Facility Core for assistance with NMR training and analysis. From the lab of Fiona Yull, the authors thank former Research Assistant Richard Maynard for assistance with mouse colony maintenance and sample collection. From the lab of Dr. Todd Giorgio, the authors thank former lab members Dr. Meredith Jackson for initial training on polymer fabrication and Abigail Manning for assistance in experimental preparation. The authors also thank the Translational Pathology Shared Resource core for sectioning and H&E staining of fixed tumor tissue, which is supported by NCI/NIH Cancer Center Support Grant 2P30 CA068485-14. The authors thank the lab of Dr. Craig Duvall for use of equipment, including the Nikon confocal microscope for fluorescent imaging. Members of the Vanderbilt Ovarian Cancer Alliance (VOCAL) are also acknowledged for their support of this work.
Funding Information:
The authors thank Dr. Dmitry Koktysh from VINSE for assistance with FTIR and DLS/zeta potential measurements and Dr. Donald Stec from the Small Molecule NMR Facility Core for assistance with NMR training and analysis. From the lab of Fiona Yull, the authors thank former Research Assistant Richard Maynard for assistance with mouse colony maintenance and sample collection. From the lab of Dr. Todd Giorgio, the authors thank former lab members Dr. Meredith Jackson for initial training on polymer fabrication and Abigail Manning for assistance in experimental preparation. The authors also thank the Translational Pathology Shared Resource core for sectioning and H&E staining of fixed tumor tissue, which is supported by NCI/NIH Cancer Center Support Grant 2P30 CA068485-14. The authors thank the lab of Dr. Craig Duvall for use of equipment, including the Nikon confocal microscope for fluorescent imaging. Members of the Vanderbilt Ovarian Cancer Alliance (VOCAL) are also acknowledged for their support of this work.
Publisher Copyright:
© 2022, The Author(s).
PY - 2022/12
Y1 - 2022/12
N2 - Background: Current cancer immunotherapies have made tremendous impacts but generally lack high response rates, especially in ovarian cancer. New therapies are needed to provide increased benefits. One understudied approach is to target the large population of immunosuppressive tumor-associated macrophages (TAMs). Using inducible transgenic mice, we recently reported that upregulating nuclear factor-kappaB (NF-κB) signaling in TAMs promotes the M1, anti-tumor phenotype and limits ovarian cancer progression. We also developed a mannose-decorated polymeric nanoparticle system (MnNPs) to preferentially deliver siRNA payloads to M2, pro-tumor macrophages in vitro. In this study, we tested a translational strategy to repolarize ovarian TAMs via MnNPs loaded with siRNA targeting the inhibitor of NF-κB alpha (IκBα) using mouse models of ovarian cancer. Methods: We evaluated treatment with MnNPs loaded with IκBα siRNA (IκBα-MnNPs) or scrambled siRNA in syngeneic ovarian cancer models. ID8 tumors in C57Bl/6 mice were used to evaluate consecutive-day treatment of late-stage disease while TBR5 tumors in FVB mice were used to evaluate repetitive treatments in a faster-developing disease model. MnNPs were evaluated for biodistribution and therapeutic efficacy in both models. Results: Stimulation of NF-κB activity and repolarization to an M1 phenotype via IκBα-MnNP treatment was confirmed using cultured luciferase-reporter macrophages. Delivery of MnNPs with fluorescent payloads (Cy5-MnNPs) to macrophages in the solid tumors and ascites was confirmed in both tumor models. A three consecutive-day treatment of IκBα-MnNPs in the ID8 model validated a shift towards M1 macrophage polarization in vivo. A clear therapeutic effect was observed with biweekly treatments over 2-3 weeks in the TBR5 model where significantly reduced tumor burden was accompanied by changes in immune cell composition, indicative of reduced immunosuppressive tumor microenvironment. No evidence of toxicity associated with MnNP treatment was observed in either model. Conclusions: In mouse models of ovarian cancer, MnNPs were preferentially associated with macrophages in ascites fluid and solid tumors. Evidence of macrophage repolarization, increased inflammatory cues, and reduced tumor burden in IκBα-MnNP-treated mice indicate beneficial outcomes in models of established disease. We have provided evidence of a targeted, TAM-directed approach to increase anti-tumor immunity in ovarian cancer with strong translational potential for future clinical studies.
AB - Background: Current cancer immunotherapies have made tremendous impacts but generally lack high response rates, especially in ovarian cancer. New therapies are needed to provide increased benefits. One understudied approach is to target the large population of immunosuppressive tumor-associated macrophages (TAMs). Using inducible transgenic mice, we recently reported that upregulating nuclear factor-kappaB (NF-κB) signaling in TAMs promotes the M1, anti-tumor phenotype and limits ovarian cancer progression. We also developed a mannose-decorated polymeric nanoparticle system (MnNPs) to preferentially deliver siRNA payloads to M2, pro-tumor macrophages in vitro. In this study, we tested a translational strategy to repolarize ovarian TAMs via MnNPs loaded with siRNA targeting the inhibitor of NF-κB alpha (IκBα) using mouse models of ovarian cancer. Methods: We evaluated treatment with MnNPs loaded with IκBα siRNA (IκBα-MnNPs) or scrambled siRNA in syngeneic ovarian cancer models. ID8 tumors in C57Bl/6 mice were used to evaluate consecutive-day treatment of late-stage disease while TBR5 tumors in FVB mice were used to evaluate repetitive treatments in a faster-developing disease model. MnNPs were evaluated for biodistribution and therapeutic efficacy in both models. Results: Stimulation of NF-κB activity and repolarization to an M1 phenotype via IκBα-MnNP treatment was confirmed using cultured luciferase-reporter macrophages. Delivery of MnNPs with fluorescent payloads (Cy5-MnNPs) to macrophages in the solid tumors and ascites was confirmed in both tumor models. A three consecutive-day treatment of IκBα-MnNPs in the ID8 model validated a shift towards M1 macrophage polarization in vivo. A clear therapeutic effect was observed with biweekly treatments over 2-3 weeks in the TBR5 model where significantly reduced tumor burden was accompanied by changes in immune cell composition, indicative of reduced immunosuppressive tumor microenvironment. No evidence of toxicity associated with MnNP treatment was observed in either model. Conclusions: In mouse models of ovarian cancer, MnNPs were preferentially associated with macrophages in ascites fluid and solid tumors. Evidence of macrophage repolarization, increased inflammatory cues, and reduced tumor burden in IκBα-MnNP-treated mice indicate beneficial outcomes in models of established disease. We have provided evidence of a targeted, TAM-directed approach to increase anti-tumor immunity in ovarian cancer with strong translational potential for future clinical studies.
UR - http://www.scopus.com/inward/record.url?scp=85129392427&partnerID=8YFLogxK
U2 - 10.1186/s12885-022-09612-2
DO - 10.1186/s12885-022-09612-2
M3 - Article
C2 - 35513776
AN - SCOPUS:85129392427
SN - 1471-2407
VL - 22
JO - BMC Cancer
JF - BMC Cancer
IS - 1
M1 - 497
ER -