Jenna A. Mosier scite author profile

While considerable progress has been made in studying genetic and cellular aspects of metastasis with in vitro cell culture and in vivo animal models, the driving mechanisms of each step of metastasis are still relatively unclear due to their complexity. Moreover, little progress has been made in understanding how cellular fitness in one step of the metastatic cascade correlates with ability to survive other subsequent steps. Engineered models incorporate tools such as tailored biomaterials and microfabrication to mimic human disease progression, which when coupled with advanced quantification methods permit comparisons to human patient samples and in vivo studies. Here, we review novel tools and techniques that have been recently developed to dissect key features of the metastatic cascade using primary patient samples and highly representative microenvironments for the purposes of advancing personalized medicine and precision oncology. Although improvements are needed to increase tractability and accessibility while faithfully simulating the in vivo microenvironment, these models are powerful experimental platforms for understanding cancer biology, furthering drug screening, and facilitating development of therapeutics.

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Phenotypic Heterogeneity and Metastasis of Breast Cancer Cells

Hapach

Carey

Schwager

et al. 2021

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Although intratumoral genomic heterogeneity can impede cancer research and treatment, less is known about the effects of phenotypic heterogeneities. To investigate the role of cell migration heterogeneities in metastasis, we phenotypically sorted metastatic breast cancer cells into two subpopulations based on migration ability. Although migration is typically considered to be associated with metastasis, when injected orthotopically in vivo, the weakly migratory subpopulation metastasized significantly more than the highly migratory subpopulation. To investigate the mechanism behind this observation, both subpopulations were assessed at each stage of the metastatic cascade, including dissemination from the primary tumor, survival in the circulation, extravasation, and colonization. Although both subpopulations performed each step successfully, weakly migratory cells presented as circulating tumor cell (CTC) clusters in the circulation, suggesting clustering as one potential mechanism behind the increased metastasis of weakly migratory cells. RNA sequencing revealed weakly migratory subpopulations to be more epithelial and highly migratory subpopulations to be more mesenchymal. Depletion of E-cadherin expression from weakly migratory cells abrogated metastasis. Conversely, induction of E-cadherin expression in highly migratory cells increased metastasis. Clinical patient data and blood samples showed that CTC clustering and E-cadherin expression are both associated with worsened patient outcome. This study demonstrates that deconvolving phenotypic heterogeneities can reveal fundamental insights into metastatic progression. More specifically, these results indicate that migratory ability does not necessarily correlate with metastatic potential and that E-cadherin promotes metastasis in phenotypically sorted breast cancer cell subpopulations by enabling CTC clustering. Significance: This study employs phenotypic cell sorting for migration to reveal a weakly migratory, highly metastatic breast cancer cell subpopulation regulated by E-cadherin, highlighting the dichotomy between cancer cell migration and metastasis.

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Cancer cell metabolic plasticity in migration and metastasis

Mosier

Schwager

Boyajian

et al. 2021

Clin Exp Metastasis

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Extent of Cell Confinement in Microtracks Affects Speed and Results in Differential Matrix Strains

Mosier

Rahman-Zaman

Zanotelli

et al. 2019

Biophysical Journal

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Calcification of Biomaterials and Diseased States

Mosier¹,

Nguyen²,

Parker³

et al. 2018

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Calcification is one of the most common issues that arise concerning biocompatibility, known to affect many systems in the body. It is often associated with an increase in free phosphate and calcium particles in the serum that leads to mineral deposition. Calcification is problematic both in the naturally occurring state of the body, as well as when it exists as result of biomaterial implants. While calcification is prominent in many different forms, not all mechanisms and processes associated with the phenomenon are completely understood. In this chapter, materials affected by calcification, potential mechanisms of action, and potential treatments will be discussed. Both bioprosthetic and polymer heart valves and urinary implants will be evaluated for material composition, application, and failure. Current research on the assessment of these materials will be reported, with the associated chemical and biological mechanisms explained. The chapter will also detail diseased states of the arteries that induce calcification and what treatments can be used for both arterial and bioprosthetic calcification. Finally, the chapter will conclude by detailing future designs for biomaterials to prevent and treat calcification in both natural and synthetic applications.

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Jenna A. Mosier

Engineered models to parse apart the metastatic cascade

Phenotypic Heterogeneity and Metastasis of Breast Cancer Cells

Cancer cell metabolic plasticity in migration and metastasis

Extent of Cell Confinement in Microtracks Affects Speed and Results in Differential Matrix Strains

Calcification of Biomaterials and Diseased States

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