Identifying biomarkers of breast cancer micrometastatic disease in bone marrow using a patient-derived xenograft mouse model

Pillai, Sreeraj G.; Li, Shunqiang; Siddappa, Chidananda M.; Ellis, Matthew J.; Watson, Mark A.; Aft, Rebecca

doi:10.1186/s13058-017-0927-1

Cited by 18 publications

(15 citation statements)

References 42 publications

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“…These attempts, however, do not reflect the entire complexity of metastasis formation as outlined above as they circumvent, e.g ., relevant steps at the primary tumor site. Therefore, we and others started to develop mouse models of spontaneous metastasis formation of human tumors, in which the single steps of the metastatic cascade are largely reflected 13 – 15 , and to characterize the tumor cells at the molecular ( e.g ., genomic) level at different metastatic stages 16 .…”

Section: Introductionmentioning

confidence: 99%

Differential Proteome Analysis of Human Neuroblastoma Xenograft Primary Tumors and Matched Spontaneous Distant Metastases

Hänel

Gosau

Maar

et al. 2018

Sci Rep

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Metastasis formation is the major cause for cancer-related deaths and the underlying mechanisms remain poorly understood. In this study we describe spontaneous metastasis xenograft mouse models of human neuroblastoma used for unbiased identification of metastasis-related proteins by applying an infrared laser (IR) for sampling primary tumor and metastatic tissues, followed by mass spectrometric proteome analysis. IR aerosol samples were obtained from ovarian and liver metastases, which were indicated by bioluminescence imaging (BLI), and matched subcutaneous primary tumors. Corresponding histology proved the human origin of metastatic lesions. Ovarian metastases were commonly larger than liver metastases indicating differential outgrowth capacities. Among ~1,900 proteins identified at each of the three sites, 55 proteins were differentially regulated in ovarian metastases while 312 proteins were regulated in liver metastases. There was an overlap of 21 and 7 proteins up- and down-regulated at both metastatic sites, respectively, most of which were so far not related to metastasis such as LYPLA2, EIF4B, DPY30, LGALS7, PRPH, and NEFM. Moreover, we established in vitro sublines from primary tumor and metastases and demonstrate differences in cellular protrusions, migratory/invasive potential and glycosylation. Summarized, this work identified several novel putative drivers of metastasis formation that are tempting candidates for future functional studies.

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Section: Introductionmentioning

confidence: 99%

Differential Proteome Analysis of Human Neuroblastoma Xenograft Primary Tumors and Matched Spontaneous Distant Metastases

Hänel

Gosau

Maar

et al. 2018

Sci Rep

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show abstract

“…These xenografts are very close to patients in terms of genetic abnormalities, gene expression profiles, pathological parameters, metastatic potential, and drug response ( DeRose et al, 2011 ). PDX models are used to identify biomarkers for personalized drug selection and to overcome the limitations of CDX transplantation in clinical treatment ( Cho et al, 2016 ; Pillai et al, 2018 ). Many institutions now build their own PDX model libraries.…”

Section: Transplanted Modelsmentioning

confidence: 99%

Breast cancer animal models and applications

Zeng

Chen

2020

Zoological Research

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Breast cancer is the most common malignancy in women. Basic and translational breast cancer research relies heavily on experimental animal models. Ideally, such models for breast cancer should have commonality with human breast cancer in terms of tumor etiology, biological behavior, pathology, and response to therapeutics. This review introduces current progress in different breast cancer experimental animal models and analyzes their characteristics, advantages, disadvantages, and potential applications. Finally, we propose future research directions for breast cancer animal models.

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“…Resulting tumors have characteristics that are similar to those of the original patients' tumors with respect to histology, genomic signature, and heterogeneity, as well as high predictive drug response [142829303132]. These models are used to identify biomarkers for personalized drug selection, and to overcome the limitation of CDX transplantation in clinical therapies [33]. While subcutaneous PDX transplantation models have been used in studies to measure primary tumor growth, orthotopic PDX transplantation models are suitable for mechanistic studies of metastasis and therapeutic resistance [34].…”

Section: Tumor Transplantation Modelsmentioning

confidence: 99%

Mouse models of breast cancer in preclinical research

Park

Lee

2018

Lab Anim Res

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Breast cancer remains the second leading cause of cancer death among woman, worldwide, despite advances in identifying novel targeted therapies and the development of treating strategies. Classification of clinical subtypes (ER+, PR+, HER2+, and TNBC (Triple-negative)) increases the complexity of breast cancers, which thus necessitates further investigation. Mouse models used in breast cancer research provide an essential approach to examine the mechanisms and genetic pathway in cancer progression and metastasis and to develop and evaluate clinical therapeutics. In this review, we summarize tumor transplantation models and genetically engineered mouse models (GEMMs) of breast cancer and their applications in the field of human breast cancer research and anti-cancer drug development. These models may help to improve the knowledge of underlying mechanisms and genetic pathways, as well as creating approaches for modeling clinical tumor subtypes, and developing innovative cancer therapy.

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Identifying biomarkers of breast cancer micrometastatic disease in bone marrow using a patient-derived xenograft mouse model

Cited by 18 publications

References 42 publications

Differential Proteome Analysis of Human Neuroblastoma Xenograft Primary Tumors and Matched Spontaneous Distant Metastases

Differential Proteome Analysis of Human Neuroblastoma Xenograft Primary Tumors and Matched Spontaneous Distant Metastases

Breast cancer animal models and applications

Mouse models of breast cancer in preclinical research

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