Your search keyword '"Gregory C. Fox"' showing total 30 results

1. #22. Investigating the TGF-β/integrin β3 signaling axis as a mediator of chemoresistance in breast cancer bone metastasis

Author

Kristin A. Kwakwa, Gregory C. Fox, Michael H. Ross, Xinming Su, Yalin Xu, Netra Navadkar, Gregory M. Lanza, Christopher A. Maher, and Katherine N. Weilbaecher

Subjects

Diseases of the musculoskeletal system, RC925-935, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2024

2. Supplementary Figure S6 from Targeted Therapy to β3 Integrin Reduces Chemoresistance in Breast Cancer Bone Metastases

Author

Katherine N. Weilbaecher, Gregory M. Lanza, Deborah J. Veis, Samuel Achilefu, Vijay Sharma, James A.J. Fitzpatrick, Suzanne J. Bakewell, Christopher A. Maher, Sheila A. Stewart, Jothilingam Sivapackiam, Ha X. Dang, Kristen Pagliai, Elizabeth Cordell, Alison K. Esser, Jingyu Xiang, Francesca Fontana, Michael H. Ross, Kristin A. Kwakwa, Yalin Xu, Jennifer L. Davis, Xinming Su, and Gregory C. Fox

Abstract

Evaluation of cellular response to mTORC1 inhibition, BLI analysis of visceral metastases in PyMT-BO1 tumor-bearing mice receiving combination therapies, and αvβ3-NP-RAPA toxicity studies.

Published

2023

3. Data from Targeted Therapy to β3 Integrin Reduces Chemoresistance in Breast Cancer Bone Metastases

Author

Katherine N. Weilbaecher, Gregory M. Lanza, Deborah J. Veis, Samuel Achilefu, Vijay Sharma, James A.J. Fitzpatrick, Suzanne J. Bakewell, Christopher A. Maher, Sheila A. Stewart, Jothilingam Sivapackiam, Ha X. Dang, Kristen Pagliai, Elizabeth Cordell, Alison K. Esser, Jingyu Xiang, Francesca Fontana, Michael H. Ross, Kristin A. Kwakwa, Yalin Xu, Jennifer L. Davis, Xinming Su, and Gregory C. Fox

Abstract

Breast cancer bone metastases are common and incurable. Tumoral integrin β3 (β3) expression is induced through interaction with the bone microenvironment. Although β3 is known to promote bone colonization, its functional role during therapy of established bone metastases is not known. We found increased numbers of β3+ tumor cells in murine bone metastases after docetaxel chemotherapy. β3+ tumor cells were present in 97% of post-neoadjuvant chemotherapy triple-negative breast cancer patient samples (n = 38). High tumoral β3 expression was associated with worse outcomes in both pre- and postchemotherapy triple-negative breast cancer groups. Genetic deletion of tumoral β3 had minimal effect in vitro, but significantly enhanced in vivo docetaxel activity, particularly in the bone. Rescue experiments confirmed that this effect required intact β3 signaling. Ultrastructural, transcriptomic, and functional analyses revealed an alternative metabolic response to chemotherapy in β3-expressing cells characterized by enhanced oxygen consumption, reactive oxygen species generation, and protein production. We identified mTORC1 as a candidate for therapeutic targeting of this β3-mediated, chemotherapy-induced metabolic response. mTORC1 inhibition in combination with docetaxel synergistically attenuated murine bone metastases. Furthermore, micelle nanoparticle delivery of mTORC1 inhibitor to cells expressing activated αvβ3 integrins enhanced docetaxel efficacy in bone metastases. Taken together, we show that β3 integrin induction by the bone microenvironment promotes resistance to chemotherapy through an altered metabolic response that can be defused by combination with αvβ3-targeted mTORC1 inhibitor nanotherapy. Our work demonstrates the importance of the metastatic microenvironment when designing treatments and presents new, bone-specific strategies for enhancing chemotherapeutic efficacy.

Published

2023

4. Supplementary Methods from Targeted Therapy to β3 Integrin Reduces Chemoresistance in Breast Cancer Bone Metastases

Author

Katherine N. Weilbaecher, Gregory M. Lanza, Deborah J. Veis, Samuel Achilefu, Vijay Sharma, James A.J. Fitzpatrick, Suzanne J. Bakewell, Christopher A. Maher, Sheila A. Stewart, Jothilingam Sivapackiam, Ha X. Dang, Kristen Pagliai, Elizabeth Cordell, Alison K. Esser, Jingyu Xiang, Francesca Fontana, Michael H. Ross, Kristin A. Kwakwa, Yalin Xu, Jennifer L. Davis, Xinming Su, and Gregory C. Fox

Abstract

Additional details for methods and materials.

Published

2023

5. Supplemental Figure S1 from Bone-Induced Expression of Integrin β3 Enables Targeted Nanotherapy of Breast Cancer Metastases

Author

Katherine N. Weilbaecher, Gregory M. Lanza, Theresa A. Guise, Khalid S. Mohammad, David L. Waning, James A. J. Fitzpatrick, Joshua Novack, Elizabeth Cordell, Gabriel H. Lukaszewicz, Graham A. Colditz, Thomas Walsh, Deborah V. Novack, Yalin Xu, Xinming Su, Dipanjan Pan, Grace Hu, Xiaoxia Yang, Anne H. Schmieder, Gregory C. Fox, Alison K. Esser, and Michael H. Ross

Abstract

Immunohistochemistry and flow cytometry of tumor cells for integrin expression

Published

2023

6. Supplemental Information from Bone-Induced Expression of Integrin β3 Enables Targeted Nanotherapy of Breast Cancer Metastases

Author

Katherine N. Weilbaecher, Gregory M. Lanza, Theresa A. Guise, Khalid S. Mohammad, David L. Waning, James A. J. Fitzpatrick, Joshua Novack, Elizabeth Cordell, Gabriel H. Lukaszewicz, Graham A. Colditz, Thomas Walsh, Deborah V. Novack, Yalin Xu, Xinming Su, Dipanjan Pan, Grace Hu, Xiaoxia Yang, Anne H. Schmieder, Gregory C. Fox, Alison K. Esser, and Michael H. Ross

Abstract

Supplemental Figure Legends

Published

2023

7. Data from Bone-Induced Expression of Integrin β3 Enables Targeted Nanotherapy of Breast Cancer Metastases

Author

Katherine N. Weilbaecher, Gregory M. Lanza, Theresa A. Guise, Khalid S. Mohammad, David L. Waning, James A. J. Fitzpatrick, Joshua Novack, Elizabeth Cordell, Gabriel H. Lukaszewicz, Graham A. Colditz, Thomas Walsh, Deborah V. Novack, Yalin Xu, Xinming Su, Dipanjan Pan, Grace Hu, Xiaoxia Yang, Anne H. Schmieder, Gregory C. Fox, Alison K. Esser, and Michael H. Ross

Abstract

Bone metastases occur in approximately 70% of metastatic breast cancer patients, often leading to skeletal injuries. Current treatments are mainly palliative and underscore the unmet clinical need for improved therapies. In this study, we provide preclinical evidence for an antimetastatic therapy based on targeting integrin β3 (β3), which is selectively induced on breast cancer cells in bone by the local bone microenvironment. In a preclinical model of breast cancer, β3 was strongly expressed on bone metastatic cancer cells, but not primary mammary tumors or visceral metastases. In tumor tissue from breast cancer patients, β3 was significantly elevated on bone metastases relative to primary tumors from the same patient (n = 42). Mechanistic investigations revealed that TGFβ signaling through SMAD2/SMAD3 was necessary for breast cancer induction of β3 within the bone. Using a micelle-based nanoparticle therapy that recognizes integrin αvβ3 (αvβ3-MPs of ∼12.5 nm), we demonstrated specific localization to breast cancer bone metastases in mice. Using this system for targeted delivery of the chemotherapeutic docetaxel, we showed that bone tumor burden could be reduced significantly with less bone destruction and less hepatotoxicity compared with equimolar doses of free docetaxel. Furthermore, mice treated with αvβ3-MP-docetaxel exhibited a significant decrease in bone-residing tumor cell proliferation compared with free docetaxel. Taken together, our results offer preclinical proof of concept for a method to enhance delivery of chemotherapeutics to breast cancer cells within the bone by exploiting their selective expression of integrin αvβ3 at that metastatic site. Cancer Res; 77(22); 6299–312. ©2017 AACR.

Published

2023

8. Supplementary Figure 9 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Integrin beta3 antagonist treatment on tumor cells and BMMs in culture

Published

2023

9. Supplementary Figure 8 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Anti-CSF1 treatment on β3KOM mice

Published

2023

10. Supplementary Figure 1 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Blood vessel density analysis of tumor tissue

Published

2023

11. Supplementary information from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Supplementary methods and figure legends

Published

2023

12. Supplementary Figure 2 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Flow cytometric analysis of leukocyte infiltration in tumor tissue

Published

2023

13. Supplementary Table 3 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Antibody list for FACS

Published

2023

14. Supplementary Table 2 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

The differentially expressed genes (DEG) lists

Published

2023

15. Supplementary Figure 4 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

STAT1 and STAT6 downstream gene expression

Published

2023

16. Data from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Integrin β3 is critical for tumor invasion, neoangiogenesis, and inflammation, making it a promising cancer target. However, preclinical and clinical data of integrin β3 antagonists have demonstrated no benefit or worse outcomes. We hypothesized that integrin β3 could affect tumor immunity and evaluated tumors in mice with deletion of integrin β3 in macrophage lineage cells (β3KOM). β3KOM mice had increased melanoma and breast cancer growth with increased tumor-promoting M2 macrophages and decreased CD8+ T cells. Integrin β3 antagonist, cilengitide, also enhanced tumor growth and increased M2 function. We uncovered a negative feedback loop in M2 myeloid cells, wherein integrin β3 signaling favored STAT1 activation, an M1-polarizing signal, and suppressed M2-polarizing STAT6 activation. Finally, disruption of CD8+ T cells, macrophages, or macrophage integrin β3 signaling blocked the tumor-promoting effects of integrin β3 antagonism. These results suggest that effects of integrin β3 therapies on immune cells should be considered to improve outcomes. Cancer Res; 76(12); 3484–95. ©2016 AACR.

Published

2023

17. Supplementary Figure 5 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

LPS treatment enhances integrin beta3 ligand binding

Published

2023

18. Supplementary Table 4 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Primers for qPCR

Published

2023

19. Supplementary Table 1 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

The percentage of infiltrating immune cells in B16 tumor tissue

Published

2023

20. Supplementary Figure 3 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Integrin beta3 antagonist treatment on early stage breast tumor growth

Published

2023

21. Supplementary Figure 7 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Integrin beta3 regulates STAT6 signaling

Published

2023

22. Supplementary Figure 6 from Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

Katherine N. Weilbaecher, Jochen G. Schneider, David G. DeNardo, Steven L. Teitelbaum, Stephen D. Robinson, Deborah V. Novack, Roberta Faccio, Wei Zou, Joshua S. Novack, Julia C. Tomasson, Elizabeth A. Morgan, Melissa A. Meyer, Brett L. Knolhoff, Michelle A. Hurchla, Francesca Fontana, Kirsten Roomp, Veronica Steri, Takayuki Kobayashi, Gregory C. Fox, Michael H. Ross, Yalin Xu, Jingyu Xiang, Sarah R. Amend, Alison K. Esser, and Xinming Su

Abstract

Integrin gene expression of WT and Itgb3-/- BMMs after M1 or M2 polarization

Published

2023

23. Targeted Therapy to β3 Integrin Reduces Chemoresistance in Breast Cancer Bone Metastases

Author

Samuel Achilefu, Michael H. Ross, Jingyu Xiang, Kristin A. Kwakwa, Elizabeth Cordell, Alison K. Esser, Vivek Sharma, Kristen Pagliai, Francesca Fontana, Jennifer L. Davis, Deborah J. Veis, Suzanne J. Bakewell, Xinming Su, Gregory M. Lanza, Katherine N. Weilbaecher, Gregory C. Fox, Christopher G. Maher, Jothilingam Sivapackiam, James A. J. Fitzpatrick, Yalin Xu, Ha X. Dang, and Sheila A. Stewart

Subjects

0301 basic medicine, Cancer Research, medicine.medical_treatment, Integrin, Antineoplastic Agents, Bone Neoplasms, Breast Neoplasms, Docetaxel, mTORC1, Article, Targeted therapy, Transcriptome, Mice, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, In vivo, Cell Line, Tumor, medicine, Animals, Humans, Molecular Targeted Therapy, Chemotherapy, biology, business.industry, Integrin beta3, medicine.disease, Survival Analysis, Mice, Inbred C57BL, 030104 developmental biology, Oncology, Drug Resistance, Neoplasm, 030220 oncology & carcinogenesis, Cancer research, biology.protein, Female, business, medicine.drug

Abstract

Breast cancer bone metastases are common and incurable. Tumoral integrin β3 (β3) expression is induced through interaction with the bone microenvironment. Although β3 is known to promote bone colonization, its functional role during therapy of established bone metastases is not known. We found increased numbers of β3+ tumor cells in murine bone metastases after docetaxel chemotherapy. β3+ tumor cells were present in 97% of post-neoadjuvant chemotherapy triple-negative breast cancer patient samples (n = 38). High tumoral β3 expression was associated with worse outcomes in both pre- and postchemotherapy triple-negative breast cancer groups. Genetic deletion of tumoral β3 had minimal effect in vitro, but significantly enhanced in vivo docetaxel activity, particularly in the bone. Rescue experiments confirmed that this effect required intact β3 signaling. Ultrastructural, transcriptomic, and functional analyses revealed an alternative metabolic response to chemotherapy in β3-expressing cells characterized by enhanced oxygen consumption, reactive oxygen species generation, and protein production. We identified mTORC1 as a candidate for therapeutic targeting of this β3-mediated, chemotherapy-induced metabolic response. mTORC1 inhibition in combination with docetaxel synergistically attenuated murine bone metastases. Furthermore, micelle nanoparticle delivery of mTORC1 inhibitor to cells expressing activated αvβ3 integrins enhanced docetaxel efficacy in bone metastases. Taken together, we show that β3 integrin induction by the bone microenvironment promotes resistance to chemotherapy through an altered metabolic response that can be defused by combination with αvβ3-targeted mTORC1 inhibitor nanotherapy. Our work demonstrates the importance of the metastatic microenvironment when designing treatments and presents new, bone-specific strategies for enhancing chemotherapeutic efficacy.

Published

2021

24. Breast cancer–derived GM-CSF regulates arginase 1 in myeloid cells to promote an immunosuppressive microenvironment

Author

Jingyu Xiang, Wen-Chih Lee, Junyi Su, Leonel Hernandez-Aya, Jad I. Belle, Gregory M. Lanza, Christopher Egbulefu, Gregory C. Fox, Deborah J. Veis, Katherine N. Weilbaecher, Samuel Achilefu, Yalin Xu, Kristin A. Kwakwa, Xinming Su, Jennifer L. Davis, Wing Hing Wong, Helen M Tomasson, Partha Karmakar, David G. DeNardo, Melisa A Meyer, Sheila A. Stewart, Takayuki Kobayashi, Francesca Fontana, and Suzanne J. Bakewell

Subjects

Myeloid, medicine.medical_treatment, T cell, Breast Neoplasms, complex mixtures, Mice, Breast cancer, Cancer immunotherapy, Cell Line, Tumor, Cyclic AMP, Immune Tolerance, Tumor Microenvironment, Medicine, Animals, Humans, Myeloid Cells, Tumor microenvironment, Arginase, business.industry, Granulocyte-Macrophage Colony-Stimulating Factor, General Medicine, Immunotherapy, medicine.disease, Immune checkpoint, Mice, Inbred C57BL, medicine.anatomical_structure, Tumor progression, Cancer research, Female, business, Research Article

Abstract

Tumor-infiltrating myeloid cells contribute to the development of the immunosuppressive tumor microenvironment. Myeloid cell expression of arginase 1 (ARG1) promotes a protumor phenotype by inhibiting T cell function and depleting extracellular l-arginine, but the mechanism underlying this expression, especially in breast cancer, is poorly understood. In breast cancer clinical samples and in our mouse models, we identified tumor-derived GM-CSF as the primary regulator of myeloid cell ARG1 expression and local immune suppression through a gene-KO screen of breast tumor cell-produced factors. The induction of myeloid cell ARG1 required GM-CSF and a low pH environment. GM-CSF signaling through STAT3 and p38 MAPK and acid signaling through cAMP were required to activate myeloid cell ARG1 expression in a STAT6-independent manner. Importantly, breast tumor cell-derived GM-CSF promoted tumor progression by inhibiting host antitumor immunity, driving a significant accumulation of ARG1-expressing myeloid cells compared with lung and melanoma tumors with minimal GM-CSF expression. Blockade of tumoral GM-CSF enhanced the efficacy of tumor-specific adoptive T cell therapy and immune checkpoint blockade. Taken together, we show that breast tumor cell-derived GM-CSF contributes to the development of the immunosuppressive breast cancer microenvironment by regulating myeloid cell ARG1 expression and can be targeted to enhance breast cancer immunotherapy.

Published

2021

25. N-cadherin in osteolineage cells modulates stromal support of tumor growth

Author

Xinming Su, Katherine N. Weilbaecher, Roberto Civitelli, Francesca Fontana, Gregory C. Fox, Jingyu Xiang, Rachel Nassau, Eric Tycksen, and Giulia Leanza

Subjects

0301 basic medicine, Osteolysis, Stromal cell, Population, Diseases of the musculoskeletal system, Bone-tumor cell interactions, 03 medical and health sciences, 0302 clinical medicine, medicine, Transcriptomics, education, RC254-282, N-cadherin, education.field_of_study, Tumor microenvironment, Cadherin, business.industry, musculoskeletal, neural, and ocular physiology, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, medicine.disease, 030104 developmental biology, medicine.anatomical_structure, RC925-935, Oncology, Cell culture, 030220 oncology & carcinogenesis, Cancer cell, Cancer research, Bone marrow, business, Research Article

Abstract

Highlights • N-cadherin in osteolineage, Osterix+ cells restrains extraskeletal tumor growth. • Osterix+ cells are present in the stromal microenvironment of extraskeletal tumors. • Osterix+ cells are present in normal tissues frequent sites of metastasis. • N-cadherin modulates pro-tumorigenic signaling in tumor associated Osterix+ cells., Tumor growth and metastases are dependent on interactions between cancer cells and the local environment. Expression of the cell–cell adhesion molecule N-cadherin (Ncad) is associated with highly aggressive cancers, and its expression by osteogenic cells has been proposed to provide a molecular “dock” for disseminated tumor cells to establish in pre-metastatic niches within the bone. To test this biologic model, we conditionally deleted the Ncad gene (Cdh2) in osteolineage cells using Osx-cre (cKO). Contrary to expectations, the metastatic breast cancer cell line PyMT-BO1 was able to form tumors in bone and to induce osteolysis in cKO as well as in control mice. Despite absence of Ncad, bone marrow stromal cells isolated from cKO mice were able to engage in direct cell–cell interactions with tumor cells expressing either N- or E-cadherin. However, subcutaneous PyMT-BO1 and B16F10 tumors grew larger in cKO relative to control littermates. Cell tracking experiments using the Ai9 reporter revealed the presence of Osx+ and Ncad+ cells in the stroma of extra-skeletal tumors and in a small population of lung cells. Gene expression analysis by RNAseq of Osx+ cells isolated from extra-skeletal tumors revealed alterations of pro-tumorigenic signaling pathways in cKO cells relative to control Osx+ cells. Thus, Ncad in Osx+ cells is not necessary for the establishment of bone metastases, but in extra-skeletal tumors it regulates pro-tumorigenic support by the microenvironment.

Published

2021

26. Antagonizing Integrin β3 Increases Immunosuppression in Cancer

Author

David G. DeNardo, Melissa A. Meyer, Joshua S. Novack, Alison K. Esser, Roberta Faccio, Steven L. Teitelbaum, Michelle A. Hurchla, Jingyu Xiang, Jochen G. Schneider, Francesca Fontana, Michael H. Ross, Kirsten Roomp, Stephen D. Robinson, Deborah V. Novack, Veronica Steri, Julia C. Tomasson, Wei Zou, Gregory C. Fox, Brett L. Knolhoff, Xinming Su, Yalin Xu, Elizabeth A. Morgan, Katherine N. Weilbaecher, Takayuki Kobayashi, and Sarah R. Amend

Subjects

0301 basic medicine, Cancer Research, Inflammation, Cilengitide, Article, Immune tolerance, Mice, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Immune system, stomatognathic system, Neoplasms, Immune Tolerance, Tumor Microenvironment, medicine, Animals, Syk Kinase, Macrophage, Tumor microenvironment, biology, Macrophages, Integrin beta3, Cancer, medicine.disease, Mice, Inbred C57BL, stomatognathic diseases, STAT1 Transcription Factor, 030104 developmental biology, Oncology, Integrin alpha M, chemistry, 030220 oncology & carcinogenesis, biology.protein, Cancer research, medicine.symptom, STAT6 Transcription Factor

Abstract

Integrin β3 is critical for tumor invasion, neoangiogenesis, and inflammation, making it a promising cancer target. However, preclinical and clinical data of integrin β3 antagonists have demonstrated no benefit or worse outcomes. We hypothesized that integrin β3 could affect tumor immunity and evaluated tumors in mice with deletion of integrin β3 in macrophage lineage cells (β3KOM). β3KOM mice had increased melanoma and breast cancer growth with increased tumor-promoting M2 macrophages and decreased CD8+ T cells. Integrin β3 antagonist, cilengitide, also enhanced tumor growth and increased M2 function. We uncovered a negative feedback loop in M2 myeloid cells, wherein integrin β3 signaling favored STAT1 activation, an M1-polarizing signal, and suppressed M2-polarizing STAT6 activation. Finally, disruption of CD8+ T cells, macrophages, or macrophage integrin β3 signaling blocked the tumor-promoting effects of integrin β3 antagonism. These results suggest that effects of integrin β3 therapies on immune cells should be considered to improve outcomes. Cancer Res; 76(12); 3484–95. ©2016 AACR.

Published

2016

27. Abstract 2613: Integrin beta-3 signaling links chemoresistance and mitochondrial metabolism in breast cancer bone metastases

Author

Gregory C. Fox, Barbara Muz, Yalin Xu, Samuel Achilefu, Alison K. Esser, Michael H. Ross, Deborah J. Veis, Gregory M. Lanza, Katherine N. Weilbaecher, Ha X. Dang, Abdel Kareem Azab, Christopher G. Maher, Elizabeth Cordell, Xinming Su, and Elizabeth Wilson

Subjects

Cancer Research, Chemotherapy, business.industry, medicine.medical_treatment, Cancer, mTORC1, medicine.disease, Metastasis, Breast cancer, Oncology, Mitochondrial biogenesis, Docetaxel, medicine, Cancer research, business, PI3K/AKT/mTOR pathway, medicine.drug

Abstract

We have previously demonstrated that expression of the integrin β3 (β3) subunit is consistently increased in breast cancer (BC) bone metastases across clinical samples and preclinical models. Bone metastases frequently exhibit resistance to chemotherapy. Based on evidence that integrin β3 can function as a promoter of tumor survival and metastasis, we asked whether increased β3 signaling in bone metastases promotes chemoresistance. In established murine bone metastases, the proportion of integrin β3+ tumor cells was increased after docetaxel administration. Genetic deletion of β3 in either MMTV-PyMT-derived BC cells (BO1-FL-GFP, modeling luminal B disease) or 4T1 BC cells (4T1-FL-GFP, modeling triple-negative disease) yielded bone metastases with increased sensitivity to docetaxel treatment in vivo. Retroviral rescue of β3 expression in β3-/- BO1-FL-GFP cells by a signaling-competent human integrin β3 construct (hβ3) restored relative docetaxel chemoresistance in bone metastases. By contrast, expression of a signaling-deficient mutant β3 (Δβ3) failed to restore chemoresistance, suggesting that signaling through β3 is critical to its capacity to promote docetaxel chemoresistance in bone-residing BC cells. Mechanistically, RNAseq analysis of docetaxel response in β3-/- and hβ3-rescued cells revealed β3-mediated enrichment in transcriptional pathways associated with oxidative phosphorylation and metabolism. Direct imaging of mitochondria by super-resolution microscopy and extracellular flux analysis of oxygen consumption rate further confirmed an alternative metabolic response to docetaxel in resistant, β3-expressing tumor cells. mTORC1 plays an important role in mitochondrial biogenesis and cellular metabolism, and can be activated downstream of integrin signaling in certain contexts. Based on transcriptomic data identifying enhanced mTORC1 activity as a possible mediator of β3-dependent metabolic changes, we asked whether mTOR inhibition could restore chemosensitivity in BC bone metastases. In mice bearing chemoresistant, β3-WT metastases, combination of the mTORC1 inhibitor rapamycin with docetaxel yielded synergistic, site-specific attenuation of bone tumor burden. Taken together, our data 1) establish integrin β3 as a mediator of chemoresistance in breast cancer bone metastases, 2) demonstrate a mechanistic link between integrin β3 expression and an alternative metabolic response to docetaxel in resistant cells, and 3) suggest mTORC1 inhibition as a candidate for rational combination with chemotherapy to interrupt treatment resistance in breast cancer bone metastases. Citation Format: Gregory C. Fox, Michael H. Ross, Xinming Su, Yalin Xu, Alison Esser, Elizabeth Cordell, Elizabeth Wilson, Barbara Muz, Ha Dang, Christopher A. Maher, Abdel Kareem Azab, Deborah Veis, Samuel Achilefu, Gregory M. Lanza, Katherine N. Weilbaecher. Integrin beta-3 signaling links chemoresistance and mitochondrial metabolism in breast cancer bone metastases [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 2613.

Published

2020

28. HTLV-1 viral oncogene HBZ drives bone destruction in adult T cell leukemia

Author

Xiaogang Cheng, Xinming Su, Gregory C. Fox, Deborah J. Veis, Francesca Fontana, Junyi Su, John C. S. Harding, Hemalatha Sundaramoorthi, Alison K. Esser, Takayuki Kobayashi, Stefan Niewiesk, Yizhen Jia, Patrick L. Green, Yalin Xu, Jingyu Xiang, Amanda R. Panfil, Thomas J. Rosol, Wing Hing Wong, Devra Huey, Katherine N. Weilbaecher, Lee Ratner, and Daniel Rauch

Subjects

0301 basic medicine, Male, Bone disease, viruses, T-cell leukemia, Viral Oncogene, Retroviridae Proteins, Osteoclasts, Kaplan-Meier Estimate, medicine.disease_cause, Mice, 0302 clinical medicine, immune system diseases, hemic and lymphatic diseases, Medicine, Leukemia-Lymphoma, Adult T-Cell, 610 Medicine & health, Mice, Knockout, Human T-lymphotropic virus 1, biology, General Medicine, Gene Expression Regulation, Neoplastic, Denosumab, medicine.anatomical_structure, Basic-Leucine Zipper Transcription Factors, RANKL, 030220 oncology & carcinogenesis, Disease Progression, Heterografts, Female, medicine.drug, Research Article, Adult, T cell, Bone and Bones, 03 medical and health sciences, Animals, Humans, Bone Resorption, business.industry, RANK Ligand, medicine.disease, Lymphoma, Mice, Inbred C57BL, Disease Models, Animal, 030104 developmental biology, Cancer research, biology.protein, business, Carcinogenesis, Transcriptome

Abstract

Osteolytic bone lesions and hypercalcemia are common, serious complications in adult T cell leukemia/lymphoma (ATL), an aggressive T cell malignancy associated with human T cell leukemia virus type 1 (HTLV-1) infection. The HTLV-1 viral oncogene HBZ has been implicated in ATL tumorigenesis and bone loss. In this study, we evaluated the role of HBZ on ATL-associated bone destruction using HTLV-1 infection and disease progression mouse models. Humanized mice infected with HTLV-1 developed lymphoproliferative disease and continuous, progressive osteolytic bone lesions. HTLV-1 lacking HBZ displayed only modest delays to lymphoproliferative disease but significantly decreased disease-associated bone loss compared with HTLV-1-infected mice. Gene expression array of acute ATL patient samples demonstrated increased expression of RANKL, a critical regulator of osteoclasts. We found that HBZ regulated RANKL in a c-Fos-dependent manner. Treatment of HTLV-1-infected humanized mice with denosumab, a monoclonal antibody against human RANKL, alleviated bone loss. Using patient-derived xenografts from primary human ATL cells to induce lymphoproliferative disease, we also observed profound tumor-induced bone destruction and increased c-Fos and RANKL gene expression. Together, these data show the critical role of HBZ in driving ATL-associated bone loss through RANKL and identify denosumab as a potential treatment to prevent bone complications in ATL patients.

Published

2019

29. Bone-induced expression of integrin β3 enables targeted nanotherapy of breast cancer metastases

Author

Yalin Xu, Dipanjan Pan, Grace Hu, Gregory C. Fox, Khalid S. Mohammad, Xiaoxia Yang, Joshua S. Novack, Deborah V. Novack, Alison K. Esser, Thomas J. Walsh, James A. J. Fitzpatrick, Anne H. Schmieder, Graham A. Colditz, Gabriel H. Lukaszewicz, David L. Waning, Katherine N. Weilbaecher, Gregory M. Lanza, Elizabeth Cordell, Xinming Su, Theresa A. Guise, and Michael H. Ross

Subjects

0301 basic medicine, CA15-3, Oncology, Cancer Research, medicine.medical_specialty, Mice, Nude, Bone Neoplasms, Breast Neoplasms, Docetaxel, Article, Metastasis, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, Transforming Growth Factor beta, Internal medicine, Cell Line, Tumor, medicine, Animals, Humans, Molecular Targeted Therapy, Mice, Inbred BALB C, biology, business.industry, Integrin beta3, Cancer, Transforming growth factor beta, medicine.disease, Integrin alphaVbeta3, Metastatic breast cancer, Xenograft Model Antitumor Assays, Gene Expression Regulation, Neoplastic, Mice, Inbred C57BL, 030104 developmental biology, 030220 oncology & carcinogenesis, Cancer cell, biology.protein, Nanoparticles, Female, Taxoids, business, medicine.drug, Signal Transduction

Abstract

Bone metastases occur in approximately 70% of metastatic breast cancer patients, often leading to skeletal injuries. Current treatments are mainly palliative and underscore the unmet clinical need for improved therapies. In this study, we provide preclinical evidence for an antimetastatic therapy based on targeting integrin β3 (β3), which is selectively induced on breast cancer cells in bone by the local bone microenvironment. In a preclinical model of breast cancer, β3 was strongly expressed on bone metastatic cancer cells, but not primary mammary tumors or visceral metastases. In tumor tissue from breast cancer patients, β3 was significantly elevated on bone metastases relative to primary tumors from the same patient (n = 42). Mechanistic investigations revealed that TGFβ signaling through SMAD2/SMAD3 was necessary for breast cancer induction of β3 within the bone. Using a micelle-based nanoparticle therapy that recognizes integrin αvβ3 (αvβ3-MPs of ∼12.5 nm), we demonstrated specific localization to breast cancer bone metastases in mice. Using this system for targeted delivery of the chemotherapeutic docetaxel, we showed that bone tumor burden could be reduced significantly with less bone destruction and less hepatotoxicity compared with equimolar doses of free docetaxel. Furthermore, mice treated with αvβ3-MP-docetaxel exhibited a significant decrease in bone-residing tumor cell proliferation compared with free docetaxel. Taken together, our results offer preclinical proof of concept for a method to enhance delivery of chemotherapeutics to breast cancer cells within the bone by exploiting their selective expression of integrin αvβ3 at that metastatic site. Cancer Res; 77(22); 6299–312. ©2017 AACR.

Published

2017

30. Making Music Festivals Work

Author

Gregory C. Fox

Subjects

Work (electrical), Pedagogy, Psychology, Assistant professor, Adjudication

Abstract

Festivals and contests must have clear goals reflected in good organization and thoughtful adjudication. Gregory C. Fox, assistant professor of music and education at the University of Missouri-St. Louis, explores five suggestions that can help ensure a valuable experience for all participants.

Published

1990