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1. Intratumoral in vivo staging of breast cancer by multi-tracer PET and advanced analysis

Author

Jennifer Griessinger, Julian Schwab, Qian Chen, Anna Kühn, Jonathan Cotton, Gregory Bowden, Heike Preibsch, Gerald Reischl, Leticia Quintanilla-Martinez, Hidetoshi Mori, An Nguyen Dang, Ursula Kohlhofer, Olulanu H. Aina, Alexander D. Borowsky, Bernd J. Pichler, Robert D. Cardiff, and Andreas M. Schmid

Subjects
Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Abstract The staging and local management of breast cancer involves the evaluation of the extent and completeness of excision of both the invasive carcinoma component and also the intraductal component or ductal carcinoma in situ. When both invasive ductal carcinoma and coincident ductal carcinoma in situ are present, assessment of the extent and localization of both components is required for optimal therapeutic planning. We have used a mouse model of breast cancer to evaluate the feasibility of applying molecular imaging to assess the local status of cancers in vivo. Multi-tracer positron emission tomography (PET) and magnetic resonance imaging (MRI) characterize the transition from premalignancy to invasive carcinoma. PET tracers for glucose consumption, membrane synthesis, and neoangiogenesis in combination with a Gaussian mixture model-based analysis reveal image-derived thresholds to separate the different stages within the whole-lesion. Autoradiography, histology, and quantitative image analysis of immunohistochemistry further corroborate our in vivo findings. Finally, clinical data further support our conclusions and demonstrate translational potential. In summary, this preclinical model provides a platform for characterizing multistep tumor progression and provides proof of concept that supports the utilization of advanced protocols for PET/MRI in clinical breast cancer imaging.

Published
2022
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2. Highly metastatic claudin-low mammary cancers can originate from luminal epithelial cells

Author

Patrick D. Rädler, Barbara L. Wehde, Aleata A. Triplett, Hridaya Shrestha, Jonathan H. Shepherd, Adam D. Pfefferle, Hallgeir Rui, Robert D. Cardiff, Charles M. Perou, and Kay-Uwe Wagner

Subjects
Science
Abstract

The cellular origin and oncogenic drivers promoting claudin-low breast cancer are undefined. Here, the authors report that the consistent activation of oncogenic RAS signaling, as well as regulators of EMT, play a crucial role in the cellular plasticity and maintenance of the mesenchymal and stem cell characteristics of claudin-low mammary cancer cells.

Published
2021
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3. The atypical cyclin-like protein Spy1 overrides p53-mediated tumour suppression and promotes susceptibility to breast tumourigenesis

Author

Bre-Anne Fifield, Ingrid Qemo, Evie Kirou, Robert D. Cardiff, and Lisa Ann Porter

Subjects
Cdk, Cyclin, Cell cycle, Tumour suppressor, Mammary gland, DNA damage, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Abstract Background Breast cancer is the most common cancer to affect women and one of the leading causes of cancer-related deaths. Proper regulation of cell cycle checkpoints plays a critical role in preventing the accumulation of deleterious mutations. Perturbations in the expression or activity of mediators of cell cycle progression or checkpoint activation represent important events that may increase susceptibility to the onset of carcinogenesis. The atypical cyclin-like protein Spy1 was isolated in a screen for novel genes that could bypass the DNA damage response. Clinical data demonstrates that protein levels of Spy1 are significantly elevated in ductal and lobular carcinoma of the breast. We hypothesized that elevated Spy1 would override protective cell cycle checkpoints and support the onset of mammary tumourigenesis. Methods We generated a transgenic mouse model driving expression of Spy1 in the mammary epithelium. Mammary development, growth characteristics and susceptibility to tumourigenesis were studied. In vitro studies were conducted to investigate the relationship between Spy1 and p53. Results We found that in the presence of wild-type p53, Spy1 protein is held ‘in check’ via protein degradation, representing a novel endogenous mechanism to ensure protected checkpoint control. Regulation of Spy1 by p53 is at the protein level and is mediated in part by Nedd4. Mutation or abrogation of p53 is sufficient to allow for accumulation of Spy1 levels resulting in mammary hyperplasia. Sustained elevation of Spy1 results in elevated proliferation of the mammary gland and susceptibility to tumourigenesis. Conclusions This mouse model demonstrates for the first time that degradation of the cyclin-like protein Spy1 is an essential component of p53-mediated tumour suppression. Targeting cyclin-like protein activity may therefore represent a mechanism of re-sensitizing cells to important cell cycle checkpoints in a therapeutic setting.

Published
2019
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4. A cancer rainbow mouse for visualizing the functional genomics of oncogenic clonal expansion

Author

Peter G. Boone, Lauren K. Rochelle, Joshua D. Ginzel, Veronica Lubkov, Wendy L. Roberts, P. J. Nicholls, Cheryl Bock, Mei Lang Flowers, Richard J. von Furstenberg, Barry R. Stripp, Pankaj Agarwal, Alexander D. Borowsky, Robert D. Cardiff, Larry S. Barak, Marc G. Caron, H. Kim Lyerly, and Joshua C. Snyder

Subjects
Science
Abstract

Pre-malignant cells harbouring oncogenic mutations can populate and spread throughout a tissue. Here, using a rainbow mouse system, the authors explore how clonal expansion in the mouse intestine might explain high levels of intra-tumoural heterogeneity observed in the disease.

Published
2019
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5. Rheb1-Independent Activation of mTORC1 in Mammary Tumors Occurs through Activating Mutations in mTOR

Author

Bin Xiao, Dongmei Zuo, Alison Hirukawa, Robert D. Cardiff, Richard Lamb, Nahum Sonenberg, and William J. Muller

Subjects
Biology (General), QH301-705.5
Abstract

Summary: Mechanistic target of rapamycin complex 1 (mTORC1) is a master modulator of cellular growth, and its aberrant regulation is recurrently documented within breast cancer. While the small GTPase Rheb1 is the canonical activator of mTORC1, Rheb1-independent mechanisms of mTORC1 activation have also been reported but have not been fully understood. Employing multiple transgenic mouse models of breast cancer, we report that ablation of Rheb1 significantly impedes mammary tumorigenesis. In the absence of Rheb1, a block in tumor initiation can be overcome by multiple independent mutations in Mtor to allow Rheb1-independent reactivation of mTORC1. We further demonstrate that the mTOR kinase is indispensable for tumor initiation as the genetic ablation of mTOR abolishes mammary tumorigenesis. Collectively, our findings demonstrate that mTORC1 activation is indispensable for mammary tumor initiation and that tumors acquire alternative mechanisms of mTORC1 activation. : While Rheb1-dependent mTORC1 activation is well established within mammalian context, Xiao et al. highlight its contribution in mammary tumorigenesis using breast cancer mouse models. Driven by the evolutionary nature of tumorigenesis, tumors devoid of Rheb1 develop with hyperactivating mTOR mutations to restore mTORC1 activity, thus emphasizing alternative mechanisms of activation. Keywords: Rheb, mTOR, tumorigenesis, breast, cancer, mutation

Published
2020
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6. Pathobiology of the 129:Stat1 −/− mouse model of human age-related ER-positive breast cancer with an immune infiltrate-excluded phenotype

Author

Hidetoshi Mori, Jane Q. Chen, Robert D. Cardiff, Zsófia Pénzváltó, Neil E. Hubbard, Louis Schuetter, Russell C. Hovey, Josephine F. Trott, and Alexander D. Borowsky

Subjects
Estrogen receptor, Luminal breast cancer, Stat1-knockout mouse, Pathobiology, Tumor microenvironment, Tumor immunology, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Abstract Background Stat1 gene-targeted knockout mice (129S6/SvEvTac-Stat1 tm1Rds) develop estrogen receptor-positive (ER+), luminal-type mammary carcinomas at an advanced age. There is evidence for both host environment as well as tumor cell-intrinsic mechanisms to initiate tumorigenesis in this model. In this report, we summarize details of the systemic and mammary pathology at preneoplastic and tumor-bearing time points. In addition, we investigate tumor progression in the 129:Stat1 −/− host compared with wild-type 129/SvEv, and we describe the immune cell reaction to the tumors. Methods Mice housed and treated according to National Institutes of Health guidelines and Institutional Animal Care and Use Committee-approved methods were evaluated by histopathology, and their tissues were subjected to immunohistochemistry with computer-assisted quantitative image analysis. Tumor cell culture and conditioned media from cell culture were used to perform macrophage (RAW264.7) cell migration assays, including the 129:Stat1 −/−-derived SSM2 cells as well as control Met1 and NDL tumor cells and EpH4 normal cells. Results Tumorigenesis in 129:Stat1 −/− originates from a population of FoxA1+ large oval pale cells that initially appear and accumulate along the mammary ducts in segments or regions of the gland prior to giving rise to mammary intraepithelial neoplasias. Progression to invasive carcinoma is accompanied by a marked local stromal and immune cell response composed predominantly of T cells and macrophages. In conditioned media experiments, cells derived from 129:Stat1 −/− tumors secrete both chemoattractant and chemoinhibitory factors, with greater attraction in the extracellular vesicular fraction and inhibition in the soluble fraction. The result appears to be recruitment of the immune reaction to the periphery of the tumor, with exclusion of immune cell infiltration into the tumor. Conclusions 129:Stat1 −/− is a unique model for studying the critical origins and risk reduction strategies in age-related ER+ breast cancer. In addition, it can be used in preclinical trials of hormonal and targeted therapies as well as immunotherapies.

Published
2017
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7. Aging Mouse Models Reveal Complex Tumor-Microenvironment Interactions in Cancer Progression

Author

Hidetoshi Mori, Robert D. Cardiff, and Alexander D. Borowsky

Subjects
genetically engineered mouse models (GEMMs), gene knockout mice, aging, mammary tumorigenesis, mouse strain, Biology (General), QH301-705.5
Abstract

Mouse models and genetically engineered mouse models (GEMM) are essential experimental tools for the understanding molecular mechanisms within complex biological systems. GEMM are especially useful for inferencing phenocopy information to genetic human diseases such as breast cancer. Human breast cancer modeling in mice most commonly employs mammary epithelial-specific promoters to investigate gene function(s) and, in particular, putative oncogenes. Models are specifically useful in the mammary epithelial cell in the context of the complete mammary gland environment. Gene targeted knockout mice including conditional targeting to specific mammary cells can reveal developmental defects in mammary organogenesis and demonstrate the importance of putative tumor suppressor genes. Some of these models demonstrate a non-traditional type of tumor suppression which involves interplay between the tumor susceptible cell and its host/environment. These GEMM help to reveal the processes of cancer progression beyond those intrinsic to cancer cells. Furthermore, the, analysis of mouse models requires appropriate consideration of mouse strain, background, and environmental factors. In this review, we compare aging-related factors in mouse models for breast cancer. We introduce databases of GEMM attributes and colony functional variations.

Published
2018
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8. Inflammation and Atrophy Precede Prostatic Neoplasia in a PhIP-Induced Rat Model

Author

Alexander D. Borowsky, Karen H. Dingley, Esther Ubick, Kenneth W. Turteltaub, Robert D. Cardiff, and Ralph DeVere-White

Subjects
Prostate cancer, rat model, PhIP carcinogen, prostate inflammation, prostatic intraepithelial neoplasia, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

2-Amino-1-methyl-6-phenylimidazo(4,5-b)pyridine (PhIP) has been implicated as a major mutagenic heterocyclicamine in the human diet and is carcinogenic in the rat prostate. To validate PhIP-induced rat prostatic neoplasia as a model of human prostate cancer progression, we sought to study the earliest histologic and morphologic changes in the prostate and to follow progressive changes over time. We fed sixty-seven 5-week-old male Fischer F344 rats with PhIP (400 ppm) or control diets for 20 weeks, and then sacrificed animals for histomorphologic examination at the ages of 25, 45, and 65 weeks. Animals treated with PhIP showed significantly more inflammation (P = .002, > .001, and .016 for 25, 45, and 65 weeks, respectively) and atrophy (P = .003, > .001, and .006 for 25, 45, and 65 weeks, respectively) in their prostate glands relative to controls. Prostatic intraepithelial neoplasia (PIN) occurred only in PhIP-treated rats. PIN lesions arose in areas of glandular atrophy, most often in the ventral prostate. Atypical cells in areas of atrophy show loss of glutathione S-transferase π immunostaining preceding the development of PIN.None of the animals in this study developed invasive carcinomas, differing from those in previous reports. Overall, these findings suggest that the pathogenesis of prostatic neoplasia in the PhIP-treated rat prostate proceeds from inflammation to postinflammatory proliferative atrophy to PIN.

Published
2006
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9. Supplementary Figure 7 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

mRNA FISH of cell state markers

Published
2023

11. Movie 2 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

d16HER2 labelled sidebuds. d16HER2 shown in yellow. Krt14 antibody staining shown in green.

Published
2023

12. Supplementary Figure 2 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

Analysis of HER2BOW tumors

Published
2023

13. Movie 3 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

p95HER2 invasive carcinoma. p95HER2 shown in magenta. Krt14 antibody staining shown in green.

Published
2023

14. Data from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

HER2-positive breast cancers are among the most heterogeneous breast cancer subtypes. The early amplification of HER2 and its known oncogenic isoforms provide a plausible mechanism in which distinct programs of tumor heterogeneity could be traced to the initial oncogenic event. Here a Cancer rainbow mouse simultaneously expressing fluorescently barcoded wildtype (WTHER2), exon-16 null (d16HER2), and N-terminally truncated (p95HER2) HER2 isoforms is used to trace tumorigenesis from initiation to invasion. Tumorigenesis was visualized using whole-gland fluorescent lineage tracing and single-cell molecular pathology. We demonstrate that within weeks of expression, morphologic aberrations were already present and unique to each HER2 isoform. Although WTHER2 cells were abundant throughout the mammary ducts, detectable lesions were exceptionally rare. In contrast, d16HER2 and p95HER2 induced rapid tumor development. d16HER2 incited homogenous and proliferative luminal-like lesions which infrequently progressed to invasive phenotypes whereas p95HER2 lesions were heterogenous and invasive at the smallest detectable stage. Distinct cancer trajectories were observed for d16HER2 and p95HER2 tumors as evidenced by oncogene-dependent changes in epithelial specification and the tumor microenvironment. These data provide direct experimental evidence that intratumor heterogeneity programs begin very early and well in advance of screen or clinically detectable breast cancer.Implications:Although all HER2 breast cancers are treated equally, we show a mechanism by which clinically undetected HER2 isoforms program heterogenous cancer phenotypes through biased epithelial specification and adaptations within the tumor microenvironment.

Published
2023

15. Supplementary Data from Ecdysoneless Overexpression Drives Mammary Tumorigenesis through Upregulation of C-MYC and Glucose Metabolism

Author

Vimla Band, Hamid Band, Robert D. Cardiff, Pankaj K. Singh, Chittibabu Guda, Emad A. Rakha, Mansour A. Alsaleem, Subodh M. Lele, Fang Qiu, Kay-Uwe Wagner, Siddesh Southekal, Surendra K. Shukla, Sai Sundeep Kollala, Aniruddha Sarkar, Matthew D. Storck, Irfana Saleem, Mohsin Raza, Channabasavaiah B. Gurumurthy, Aditya Bele, Sameer Mirza, and Bhopal C. Mohapatra

Abstract

Supplementary Data from Ecdysoneless Overexpression Drives Mammary Tumorigenesis through Upregulation of C-MYC and Glucose Metabolism

Published
2023

17. Supplementary File 1 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

Supplementary File 1.

Published
2023

19. Supplementary Figure 3 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

UMAP clustering of sequenced cells and cluster identification

Published
2023

20. Supplementary Figure 5 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

TruRegistry of HER2BOW tissues

Published
2023

21. Movie 5 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

d16HER2 mammary intraepithelial neoplasm. d16HER2 shown in magenta. Krt14 antibody staining shown in green.

Published
2023

22. Movie 4 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

p95HER2 microinvasive carcinoma. p95HER2 shown in magenta. Krt14 antibody staining shown in green.

Published
2023

23. Supplementary Tables 1-5 for scRNAseq marker genes from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

Supplementary Table 1: Cluster-specific markers from all cells (8,486 cells) Supplementary Table 2: Cluster-specific markers from all epithelial cells (3,843 cells) Supplementary Table 3: Cluster-specific markers from all immune cells (1,803 cells) Supplementary Table 4: Cluster-specific markers from all fibroblast cells (922 cells) Supplementary Table 5a: State-specific markers from all d16:HBOW epithelial cells (1,421 cells) Supplementary Table 5b: State-specific markers from all p95:HBOW epithelial cells (1,258 cells)

Published
2023

24. Supplementary Figure 6 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

Geneset analysis of HER2BOW trajectory mapping

Published
2023

25. Movie 1 from HER2 Isoforms Uniquely Program Intratumor Heterogeneity and Predetermine Breast Cancer Trajectories During the Occult Tumorigenic Phase

Author

Joshua C. Snyder, H. Kim Lyerly, Alexander D. Borowsky, Robert D. Cardiff, Neil E. Hubbard, Jane Q. Chen, Marc G. Caron, Lawrence S. Barak, Erika J. Crosby, Zachary C. Hartman, Jeffrey I. Everitt, Wendy L. Roberts, Lauren K. Rochelle, Peter G. Boone, Hidetoshi Mori, Veronica Lubkov, Chaitanya R. Acharya, and Joshua D. Ginzel

Abstract

p95HER2 labelled sidebuds. p95HER2 shown in magenta. Krt14 antibody staining shown in green.

Published
2023

26. Data from Molecular Characterization of the Transition to Malignancy in a Genetically Engineered Mouse-Based Model of Ductal Carcinoma In situ1

Author

Jeffrey P. Gregg, Carol L. MacLeod, Robert D. Cardiff, Alexander D. Borowsky, Lawrence J.T. Young, Jeannie E. Maglione, and Ruria Namba

Abstract

A transplantable model of human ductal carcinoma in situ that progresses to invasive carcinoma was developed from a genetically engineered mouse (GEM). Additional lines were established using early mammary premalignant lesions from transgenic MMTV-PyV-mT mice. These lines were verified to be premalignant and transplanted repeatedly to establish stable and predictable properties. Here, we report the first in-depth molecular analysis of neoplastic progression occurring in one premalignant transplantable GEM-derived line. Oligonucleotide microarrays showed that many genes are differentially expressed between the quiescent and prelactating mammary gland and the premalignant GEM outgrowth. In contrast, a small but consistent group of genes was associated with the transformation from premalignancy to tumor. This suggests that the majority of gene expression changes occur during the premalignant transition from normal to premalignancy, whereas many fewer changes occur during the malignant transition from premalignancy to invasive carcinoma. The premalignant transition is associated with several cell cycle–related genes and the up-regulation of oncogenes is associated with various cancers (Ccnd11, Cdk4, Myb, and Ect2). The changes identified in the malignant transition included genes previously associated with human breast cancer progression. Misregulation of the insulin-like growth factor and transforming growth factor-β signaling pathways and the stromal-epithelial interaction were implicated. Our results suggest that this transplantable GEM-based model recapitulates human ductal carcinoma in situ at both histologic and molecular levels. With consistent tumor latency and molecular profiles, this model provides an experimental platform that can be used to assess functional genomics and molecular pharmacology and to test promising chemoprevention strategies.

Published
2023

29. Data from Adiponectin Deficiency Limits Tumor Vascularization in the MMTV-PyV-mT Mouse Model of Mammary Cancer

Author

Barbara Ranscht, Robert D. Cardiff, Lawrence Shapiro, Gregory Shostak, Lionel W. Hebbard, and Martin S. Denzel

Abstract

Purpose: High levels of the fat-secreted cytokine adiponectin (APN) are present in the circulation of healthy people, whereas low levels correlate with an increased incidence of breast cancer in women. The current study experimentally probes the physiologic functions of APN in mammary cancer in a newly generated genetic mouse model.Experimental Design: We established an APN null mouse model of mammary cancer by introducing the polyoma virus middle T (PyV-mT) oncogene expressed from mouse mammary tumor virus (MMTV) regulatory elements into APN null mice. MMTV-PyV-mT–induced tumors resemble ErbB2–amplified human breast cancers. We monitored tumor onset, kinetics, and animal survival, and analyzed vascular coverage, apoptosis, and hypoxia in sections from the primary tumors. Metastatic spreading was evaluated by analyses of the lungs.Results: APN prominently localized to the vasculature in human and mouse mammary tumors. In APN null mice, MMTV-PyV-mT–induced tumors appeared with delayed onset and exhibited reduced growth rates. Affected animals survived control tumor-bearing mice by an average of 21 days. Pathologic analyses revealed reduced vascularization of APN null tumors along with increased hypoxia and apoptosis. At the experimental end point, APN null transgenic mice showed increased frequency of pulmonary metastases.Conclusion: The current work identifies a proangiogenic contribution of APN in mammary cancer that, in turn, affects tumor progression. APN interactions with vascular receptors may be useful targets for developing therapies aimed at controlling tumor vascularization in cancer patients.

Published
2023

30. Data from Longitudinal Investigation of Permeability and Distribution of Macromolecules in Mouse Malignant Transformation Using PET

Author

Katherine W. Ferrara, Fitz-Roy E. Curry, Rolf K. Reed, Robert D. Cardiff, Alexander D. Borowsky, Jane Q. Chen, Roger Adamson, Hua Zhang, Lisa M. Mahakian, Jai W. Seo, Shengping Qin, and Cecilie B. Rygh

Abstract

Purpose: We apply positron emission tomography (PET) to elucidate changes in nanocarrier extravasation during the transition from premalignant to malignant cancer, providing insight into the use of imaging to characterize early cancerous lesions and the utility of nanoparticles in early disease.Experimental Design: Albumin and liposomes were labeled with 64Cu (half-life 12.7 hours), and longitudinal PET and CT imaging studies were conducted in a mouse model of ductal carcinoma in situ. A pharmacokinetic model was applied to estimate the tumor vascular volume and permeability.Results: From early time points characterized by disseminated hyperproliferation, the enhanced vascular permeability facilitated lesion detection. During disease progression, the vascular volume fraction increased 1.6-fold and the apparent vascular permeability to albumin and liposomes increased ∼2.5-fold to 6.6 × 10−8 and 1.3 × 10−8 cm/s, respectively, with the accumulation of albumin increasing earlier in the disease process. In the malignant tumor, both tracers reached similar mean intratumoral concentrations of ∼6% ID/cc but the distribution of liposomes was more heterogeneous, ranging from 1% to 18% ID/cc compared with 1% to 9% ID/cc for albumin. The tumor-to-muscle ratio was 17.9 ± 8.1 and 7.1 ± 0.5 for liposomes and albumin, respectively, indicating a more specific delivery of liposomes than with albumin.Conclusions: PET imaging of radiolabeled particles, validated by confocal imaging and histology, detected the transition from premalignant to malignant lesions and effectively quantified the associated changes in vascular permeability. Clin Cancer Res; 17(3); 550–9. ©2010 AACR.

Published
2023

32. Supplementary Figure 7 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 7894K, Supplementary Figure 7. Xenograft models of aggressive prostate cancer.

Published
2023

33. Supplemental Table 2 from Fibroblast Growth Factor Receptor Signaling Dramatically Accelerates Tumorigenesis and Enhances Oncoprotein Translation in the Mouse Mammary Tumor Virus–Wnt-1 Mouse Model of Breast Cancer

Author

Jeffrey M. Rosen, Richard E. Lloyd, Chad J. Creighton, Charles M. Perou, Susan Hilsenbeck, Robert D. Cardiff, Brian York, Yiqun Zhang, Bryan Welm, Kathryn L. Schwertfeger, Jason I. Herschkowitz, and Adam C. Pond

Abstract

Supplemental Table 2 from Fibroblast Growth Factor Receptor Signaling Dramatically Accelerates Tumorigenesis and Enhances Oncoprotein Translation in the Mouse Mammary Tumor Virus–Wnt-1 Mouse Model of Breast Cancer

Published
2023

35. Supplementary Figure Legends 1-8 from Phosphatase and Tensin Homologue Deleted on Chromosome 10 Deficiency Accelerates Tumor Induction in a Mouse Model of ErbB-2 Mammary Tumorigenesis

Author

William J. Muller, Robert D. Cardiff, Robert J. Munn, Michael Hallett, Robert Lesurf, Babette Schade, and Nathalie Dourdin

Abstract

Supplementary Figure Legends 1-8 from Phosphatase and Tensin Homologue Deleted on Chromosome 10 Deficiency Accelerates Tumor Induction in a Mouse Model of ErbB-2 Mammary Tumorigenesis

Published
2023

36. Supplementary Table 4 from B-Raf Activation Cooperates with PTEN Loss to Drive c-Myc Expression in Advanced Prostate Cancer

Author

Cory Abate-Shen, Michael M. Shen, Andrea Califano, Martin McMahon, Robert D. Cardiff, Antonina Mitrofanova, Celine Lefebvre, David Dankort, Alvaro Aytes, Carolyn Waugh Kinkade, Nicolas Floc'h, Takashi Kobayashi, and Jingqiang Wang

Abstract

XLS file - 58K, List of differentially expressed genes between Nkx3.1CE2/+; Ptenf/f; BrafCA/+ and Nkx3.1CE2/+; Ptenf/f mouse prostate tumors (p-value

Published
2023

38. Supplemental Fig 5 from Fibroblast Growth Factor Receptor Signaling Dramatically Accelerates Tumorigenesis and Enhances Oncoprotein Translation in the Mouse Mammary Tumor Virus–Wnt-1 Mouse Model of Breast Cancer

Author

Jeffrey M. Rosen, Richard E. Lloyd, Chad J. Creighton, Charles M. Perou, Susan Hilsenbeck, Robert D. Cardiff, Brian York, Yiqun Zhang, Bryan Welm, Kathryn L. Schwertfeger, Jason I. Herschkowitz, and Adam C. Pond

Abstract

Supplemental Fig 5 from Fibroblast Growth Factor Receptor Signaling Dramatically Accelerates Tumorigenesis and Enhances Oncoprotein Translation in the Mouse Mammary Tumor Virus–Wnt-1 Mouse Model of Breast Cancer

Published
2023

39. Data from Classification of Proliferative Pulmonary Lesions of the Mouse

Author

Tyler Jacks, Jerrold M. Ward, William D. Travis, Elena N. Shmidt, Hildegard M. Schuller, Nora Rozengurt, Sabine Rehm, Robert L. Reddick, Alan S. Rabson, Robert R. Maronpot, R. Ilona Linnoila, Matthew H. Kaufman, Diana C. Haines, William T. Gunning, Edward W. Gabrielson, Armando E. Fraire, Darlene Dixon, Robert D. Cardiff, Roderick T. Bronson, Miriam R. Anver, Ana Alcaraz, and Alexander Yu. Nikitin

Abstract

Rapid advances in generating new mouse genetic models for lung neoplasia provide a continuous challenge for pathologists and investigators. Frequently, phenotypes of new models either have no precedents or are arbitrarily attributed according to incongruent human and mouse classifications. Thus, comparative characterization and validation of novel models can be difficult. To address these issues, a series of discussions was initiated by a panel of human, veterinary, and experimental pathologists during the Mouse Models of Human Cancers Consortium (NIH/National Cancer Institute) workshop on mouse models of lung cancer held in Boston on June 20–22, 2001. The panel performed a comparative evaluation of 78 cases of mouse and human lung proliferative lesions, and recommended development of a new practical classification scheme that would (a) allow easier comparison between human and mouse lung neoplasms, (b) accommodate newly emerging mouse neoplasms, and (c) address the interpretation of benign and preinvasive lesions of the mouse lung. Subsequent discussions with additional experts in pulmonary pathology resulted in the current proposal of a new classification. It is anticipated that this classification, as well as the complementary digital atlas of virtual histological slides, will help investigators and pathologists in their characterization of new mouse models, as well as stimulate further research aimed at a better understanding of proliferative lesions of the lung.

Published
2023

41. Supplementary Table 8 from B-Raf Activation Cooperates with PTEN Loss to Drive c-Myc Expression in Advanced Prostate Cancer

Author

Cory Abate-Shen, Michael M. Shen, Andrea Califano, Martin McMahon, Robert D. Cardiff, Antonina Mitrofanova, Celine Lefebvre, David Dankort, Alvaro Aytes, Carolyn Waugh Kinkade, Nicolas Floc'h, Takashi Kobayashi, and Jingqiang Wang

Abstract

XLS file - 188K, List of differentially expressed genes between RAP + PD treated and Vehicle treated Nkx3.1CE2/+; Ptenf/f; Braf CA/+ mouse prostate tumors (p-value

Published
2023

42. Data from Decoding Intratumoral Heterogeneity of Breast Cancer by Multiparametric In Vivo Imaging: A Translational Study

Author

Andreas M. Schmid, Bernd J. Pichler, Robert D. Cardiff, Christian la Fougère, Konstantin Nikolaou, Sara Brucker, Alexander D. Borowsky, Gerald Reischl, Neil E. Hubbard, Olulanu H. Aina, Ursula Kohlhofer, Annette Staebler, Nina Schwenzer, Beate Wietek, Markus Hahn, Leticia Quintanilla-Martinez, Qian Chen, Johannes Schwenck, Julian Schwab, and Jennifer Schmitz

Abstract

Differential diagnosis and therapy of heterogeneous breast tumors poses a major clinical challenge. To address the need for a comprehensive, noninvasive strategy to define the molecular and functional profiles of tumors in vivo, we investigated a novel combination of metabolic PET and diffusion-weighted (DW)-MRI in the polyoma virus middle T antigen transgenic mouse model of breast cancer. The implementation of a voxelwise analysis for the clustering of intra- and intertumoral heterogeneity in this model resulted in a multiparametric profile based on [18F]Fluorodeoxyglucose ([18F]FDG)-PET and DW-MRI, which identified three distinct tumor phenotypes in vivo, including solid acinar, and solid nodular malignancies as well as cystic hyperplasia. To evaluate the feasibility of this approach for clinical use, we examined estrogen receptor-positive and progesterone receptor-positive breast tumors from five patient cases using DW-MRI and [18F]FDG-PET in a simultaneous PET/MRI system. The postsurgical in vivo PET/MRI data were correlated to whole-slide histology using the latter traditional diagnostic standard to define phenotype. By this approach, we showed how molecular, structural (microscopic, anatomic), and functional information could be simultaneously obtained noninvasively to identify precancerous and malignant subtypes within heterogeneous tumors. Combined with an automatized analysis, our results suggest that multiparametric molecular and functional imaging may be capable of providing comprehensive tumor profiling for noninvasive cancer diagnostics. Cancer Res; 76(18); 5512–22. ©2016 AACR.

Published
2023

44. Supplementary Methods, Figure Legend from Ultrasound Increases Nanoparticle Delivery by Reducing Intratumoral Pressure and Increasing Transport in Epithelial and Epithelial–Mesenchymal Transition Tumors

Author

Katherine W. Ferrara, Rolf K. Reed, Fitz-Roy Curry, Elizabeth S. Ingham, Julie Beegle, Lisa M. Mahakian, Robert D. Cardiff, Jai Woong Seo, Yueh-Chen Lin, Dustin E. Kruse, Shengping Qin, Chun-Yen Lai, and Katherine D. Watson

Abstract

PDF file - 137K, Detailed relationship between the PAP parameter derived through the image-guided model with the classical parameters of solute transport coefficient, clearance, and 30 minute albumin clearance (Cl30).

Published
2023

45. Supplementary Figure 6 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 3402K, Supplementary Figure 6. Additional PTEN/AKT Pathway models.

Published
2023

46. Supplemental Figure Legend from Decoding Intratumoral Heterogeneity of Breast Cancer by Multiparametric In Vivo Imaging: A Translational Study

Author

Andreas M. Schmid, Bernd J. Pichler, Robert D. Cardiff, Christian la Fougère, Konstantin Nikolaou, Sara Brucker, Alexander D. Borowsky, Gerald Reischl, Neil E. Hubbard, Olulanu H. Aina, Ursula Kohlhofer, Annette Staebler, Nina Schwenzer, Beate Wietek, Markus Hahn, Leticia Quintanilla-Martinez, Qian Chen, Johannes Schwenck, Julian Schwab, and Jennifer Schmitz

Abstract

Detailed description of mean and max value analysis of ADC and [18F]FDG data of tumors of tg(PyV-mT) mice.

Published
2023

47. Supplementary Figure 1 from Ultrasound Increases Nanoparticle Delivery by Reducing Intratumoral Pressure and Increasing Transport in Epithelial and Epithelial–Mesenchymal Transition Tumors

Author

Katherine W. Ferrara, Rolf K. Reed, Fitz-Roy Curry, Elizabeth S. Ingham, Julie Beegle, Lisa M. Mahakian, Robert D. Cardiff, Jai Woong Seo, Yueh-Chen Lin, Dustin E. Kruse, Shengping Qin, Chun-Yen Lai, and Katherine D. Watson

Abstract

PDF file - 51K, Representative biodistribution of tissues 48 hours after nanoparticle injection (N=8). Accumulation was significantly greater for insonified tumors (p

Published
2023

48. Supplemental Figure I from Decoding Intratumoral Heterogeneity of Breast Cancer by Multiparametric In Vivo Imaging: A Translational Study

Author

Andreas M. Schmid, Bernd J. Pichler, Robert D. Cardiff, Christian la Fougère, Konstantin Nikolaou, Sara Brucker, Alexander D. Borowsky, Gerald Reischl, Neil E. Hubbard, Olulanu H. Aina, Ursula Kohlhofer, Annette Staebler, Nina Schwenzer, Beate Wietek, Markus Hahn, Leticia Quintanilla-Martinez, Qian Chen, Johannes Schwenck, Julian Schwab, and Jennifer Schmitz

Abstract

Mean (blue) and maximal (red) ADC and [18F]FDG uptake values of the same representative 8 tumors: VOIs were drawn on the basis of the T2-weighted TSE MRI data, and transferred to the appropriate PET and ADC data. The mean and max values were determined. The comparison between mean or maximal values between the tumors revealed different trends.

Published
2023

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