Eliah R. Shamir scite author profile

Three-dimensional organotypic culture: experimental models of mammalian biology and disease

Shamir

¹

,

Ewald

²

2014

Nat Rev Mol Cell Biol

View full text Add to dashboard Cite

Mammalian organs are challenging to study as they are fairly inaccessible to experimental manipulation and optical observation. Recent advances in three-dimensional (3D) culture techniques, coupled with the ability to independently manipulate genetic and microenvironmental factors, have enabled the real-time study of mammalian tissues. These systems have been used to visualize the cellular basis of epithelial morphogenesis, to test the roles of specific genes in regulating cell behaviours within epithelial tissues and to elucidate the contribution of microenvironmental factors to normal and disease processes. Collectively, these novel models can be used to answer fundamental biological questions and generate replacement human tissues, and they enable testing of novel therapeutic approaches, often using patient-derived cells.

show abstract

ECM microenvironment regulates collective migration and local dissemination in normal and malignant mammary epithelium

Nguyen-Ngoc

¹

,

Cheung

²

,

Brenot

³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

Breast cancer progression involves genetic changes and changes in the extracellular matrix (ECM). To test the importance of the ECM in tumor cell dissemination, we cultured epithelium from primary human breast carcinomas in different ECM gels. We used basement membrane gels to model the normal microenvironment and collagen I to model the stromal ECM. In basement membrane gels, malignant epithelium either was indolent or grew collectively, without protrusions. In collagen I, epithelium from the same tumor invaded with protrusions and disseminated cells. Importantly, collagen I induced a similar initial response of protrusions and dissemination in both normal and malignant mammary epithelium. However, dissemination of normal cells into collagen I was transient and ceased as laminin 111 localized to the basal surface, whereas dissemination of carcinoma cells was sustained throughout culture, and laminin 111 was not detected. Despite the large impact of ECM on migration strategy, transcriptome analysis of our 3D cultures revealed few ECM-dependent changes in RNA expression. However, we observed many differences between normal and malignant epithelium, including reduced expression of cell-adhesion genes in tumors. Therefore, we tested whether deletion of an adhesion gene could induce sustained dissemination of nontransformed cells into collagen I. We found that deletion of P-cadherin was sufficient for sustained dissemination, but exclusively into collagen I. Our data reveal that metastatic tumors preferentially disseminate in specific ECM microenvironments. Furthermore, these data suggest that breaks in the basement membrane could induce invasion and dissemination via the resulting direct contact between cancer cells and collagen I.

show abstract

Robust Fluorescent Detection of Protein Fatty-Acylation with Chemical Reporters

Charron

¹

,

Zhang

²

,

Yount

³

et al. 2009

View full text Add to dashboard Cite

Fatty-acylation of proteins in eukaryotes is associated with many fundamental cellular processes but has been challenging to study due to limited tools for rapid and robust detection of protein fatty-acylation in cells. The development of azido-fatty acids enabled the nonradioactive detection of fatty-acylated proteins in mammalian cells using the Staudinger ligation and biotinylated phosphine reagents. However, the visualization of protein fatty-acylation with streptavidin blotting is highly variable and not ideal for robust detection of fatty-acylated proteins. Here we report the development of alkynyl-fatty acid chemical reporters and improved bioorthogonal labeling conditions using the Cu(I)-catalyzed Huisgen [3 + 2] cycloaddition that enables specific and sensitive fluorescence detection of fatty-acylated proteins in mammalian cells. These improvements allow the rapid and robust biochemical analysis of fatty-acylated proteins expressed at endogenous levels in mammalian cells by in-gel fluorescence scanning. In addition, alkynyl-fatty acid chemical reporters enable the visualization of fatty-acylated proteins in cells by fluorescence microscopy and flow cytometry. The ability to rapidly visualize protein fatty-acylation in cells using fluorescence detection methods therefore provides new opportunities to interrogate the functions and regulatory mechanisms of fatty-acylated proteins in physiology and disease.

show abstract

Twist1-induced dissemination preserves epithelial identity and requires E-cadherin

Shamir

¹

,

Pappalardo

²

,

Jorgens

³

et al. 2014

View full text Add to dashboard Cite

show abstract

3D Culture Assays of Murine Mammary Branching Morphogenesis and Epithelial Invasion

Nguyen-Ngoc

¹

,

Shamir

²

,

Huebner

³

et al. 2014

View full text Add to dashboard Cite

Epithelia are fundamental tissues that line cavities, glands, and outer body surfaces. We use three-dimensional (3D) embedded culture of primary murine mammary epithelial ducts, called “organoids,” to recapitulate in days in culture epithelial programs that occur over weeks deep within the body. Modulating the composition of the extracellular matrix (ECM) allows us to model cell- and tissue-level behaviors observed in normal development, such as branching morphogenesis, and in cancer, such as invasion and dissemination. Here, we describe a collection of protocols for 3D culture of mammary organoids in different ECMs and for immunofluorescence staining of 3D culture samples and mammary gland tissue sections. We illustrate expected phenotypic outcomes of each assay and provide troubleshooting tips for commonly encountered technical problems.

show abstract

Cell-cell communication enhances the capacity of cell ensembles to sense shallow gradients during morphogenesis

Ellison

¹

,

Mugler

²

,

Brennan

³

et al. 2015

Preprint

View full text Add to dashboard Cite

Collective cell responses to exogenous cues depend on cell-cell interactions. In principle, these can result in enhanced sensitivity to weak and noisy stimuli. However, this has not yet been shown experimentally, and, little is known about how multicellular signal processing modulates single cell sensitivity to extracellular signaling inputs, including those guiding complex changes in the tissue form and function. Here we explored if cell-cell communication can enhance the ability of cell ensembles to sense and respond to weak gradients of chemotactic cues. Using a combination of experiments with mammary epithelial cells and mathematical modeling, we find that multicellular sensing enables detection of and response to shallow Epidermal Growth Factor (EGF) gradients that are undetectable by single cells. However, the advantage of this type of gradient sensing is limited by the noisiness of the signaling relay, necessary to integrate spatially distributed ligand concentration information. We calculate the fundamental sensory limits imposed by this communication noise and combine them with the experimental data to estimate the effective size of multicellular sensory groups involved in gradient sensing. Functional experiments strongly implicated intercellular communication through gap junctions and calcium release from intracellular stores as mediators of collective gradient sensing. The resulting integrative analysis provides a framework for understanding the advantages and limitations of sensory information processing by relays of chemically coupled cells. Significance StatementWhat new properties may result from collective cell behavior, and how these emerging capabilities may influence shaping and function of tissues, in health and disease? Here, we explored these questions in the context of epithelial branching morphogenesis. We show experimentally that, while individual mammary epithelial cells are incapable of sensing extremely weak gradients of a growth factor, cellular collectives in organotypic cultures exhibit reliable, gradient driven, directional growth. This underscores a critical importance of collective cell-cell communication and computation in gradient sensing. We develop and verify a biophysical theory of such communication, and identify the mechanisms by which it is implemented in the mammary epithelium, quantitatively analyzing both advantages and limitations of biochemical cellular communication in collective decision making.All rights reserved. No reuse allowed without permission.(which was not peer-reviewed) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.

show abstract

Cell–cell communication enhances the capacity of cell ensembles to sense shallow gradients during morphogenesis

Ellison

¹

,

Mugler

²

,

Brennan

³

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

Collective cell responses to exogenous cues depend on cell-cell interactions. In principle, these can result in enhanced sensitivity to weak and noisy stimuli. However, this has not yet been shown experimentally, and little is known about how multicellular signal processing modulates single-cell sensitivity to extracellular signaling inputs, including those guiding complex changes in the tissue form and function. Here we explored whether cell-cell communication can enhance the ability of cell ensembles to sense and respond to weak gradients of chemotactic cues. Using a combination of experiments with mammary epithelial cells and mathematical modeling, we find that multicellular sensing enables detection of and response to shallow epidermal growth factor (EGF) gradients that are undetectable by single cells. However, the advantage of this type of gradient sensing is limited by the noisiness of the signaling relay, necessary to integrate spatially distributed ligand concentration information. We calculate the fundamental sensory limits imposed by this communication noise and combine them with the experimental data to estimate the effective size of multicellular sensory groups involved in gradient sensing. Functional experiments strongly implicated intercellular communication through gap junctions and calcium release from intracellular stores as mediators of collective gradient sensing. The resulting integrative analysis provides a framework for understanding the advantages and limitations of sensory information processing by relays of chemically coupled cells. gradient sensing | development | collective cellular phenomena | linear response theory | chemotaxis

show abstract

Autophagic Degradation of NBR1 Restricts Metastatic Outgrowth during Mammary Tumor Progression

Marsh

¹

,

Kenific

²

,

Suresh

³

et al. 2020

View full text Add to dashboard Cite

show abstract

Eliah R. Shamir

Three-dimensional organotypic culture: experimental models of mammalian biology and disease

ECM microenvironment regulates collective migration and local dissemination in normal and malignant mammary epithelium

Robust Fluorescent Detection of Protein Fatty-Acylation with Chemical Reporters

Twist1-induced dissemination preserves epithelial identity and requires E-cadherin

3D Culture Assays of Murine Mammary Branching Morphogenesis and Epithelial Invasion

Cell-cell communication enhances the capacity of cell ensembles to sense shallow gradients during morphogenesis

Cell–cell communication enhances the capacity of cell ensembles to sense shallow gradients during morphogenesis

Autophagic Degradation of NBR1 Restricts Metastatic Outgrowth during Mammary Tumor Progression

Contact Info

Product

Resources

About