Lisa K. Meixner scite author profile

We present an organoid regeneration assay in which freshly isolated human mammary epithelial cells are cultured in adherent or floating collagen gels, corresponding to a rigid or compliant matrix environment. In both conditions, luminal progenitors form spheres, whereas basal cells generate branched ductal structures. In compliant but not rigid collagen gels, branching ducts form alveoli at their tips, express basal and luminal markers at correct positions, and display contractility, which is required for alveologenesis. Thereby, branched structures generated in compliant collagen gels resemble terminal ductal-lobular units (TDLUs), the functional units of the mammary gland. Using the membrane metallo-endopeptidase CD10 as a surface marker enriches for TDLU formation and reveals the presence of stromal cells within the CD49fhi/EpCAM− population. In summary, we describe a defined in vitro assay system to quantify cells with regenerative potential and systematically investigate their interaction with the physical environment at distinct steps of morphogenesis.

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An Organotypic 3D Assay for Primary Human Mammary Epithelial Cells that Recapitulates Branching Morphogenesis

Linnemann

Meixner

Miura

et al. 2017

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We have developed a three-dimensional organotypic culture system for primary human mammary epithelial cells (HMECs) in which the cells are cultured in free floating collagen type I gels. In this assay, luminal cells predominantly form multicellular spheres, while basal/myoepithelial cells form complex branched structures resembling terminal ductal lobular units (TDLUs), the functional units of the human mammary gland in situ. The TDLU-like organoids can be cultured for at least 3 weeks and can then be passaged multiple times. Subsequently, collagen gels can be stained with carmine or by immunofluorescence to allow for the analysis of morphology, protein expression and polarization, and to facilitate quantification of structures. In addition, structures can be isolated for gene expression analysis. In summary, this technique is suitable for studying branching morphogenesis, regeneration, and differentiation of HMECs as well as their dependence on the physical environment.

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Twist1 induces distinct cell states depending on TGFBR1-activation

et al. 2016

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Basic helix-loop-helix transcription factor Twist1 is a master regulator of Epithelial-Mesenchymal Transition (EMT), a cellular program implicated in different stages of development as well as metastatic dissemination of carcinomas. Here, we show that Twist1 requires TGF-beta type-I receptor (TGFBR1)-activation to bind an enhancer region of downstream effector ZEB1, thereby inducing ZEB1 transcription and EMT. When TGFBR1-phosphorylation is inhibited, Twist1 generates a distinct cell state characterized by collective invasion, simultaneous proliferation and expression of endothelial markers. By contrast, TGFBR1-activation directs Twist1 to induce stable mesenchymal transdifferentiation through EMT, thereby generating cells that display single-cell invasion, but lose their proliferative capacity. In conclusion, preventing Twist1-induced EMT by inhibiting TGFβ-signaling does not generally block acquisition of invasion, but switches mode from single-cell/non-proliferative to collective/proliferative. Together, these data reveal that transient Twist1-activation induces distinct cell states depending on signaling context and caution against the use of TGFβ-inhibitors as a therapeutic strategy to target invasiveness.

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Mechanical plasticity of the ECM directs invasive branching morphogenesis in human mammary gland organoids

Buchmann¹,

Meixner

Fernández³

et al. 2019

Preprint

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11Although branching morphogenesis is central for organogenesis in diverse organs, the underlying 12 self-organizing principles have yet to be identified. Here, we show that invasive branching 13 morphogenesis in human mammary organoids relies on an intricate tension-driven feedback 14 mechanism, which is based on the nonlinear and plastic mechanical response of the surrounding 15 collagen network. Specifically, we demonstrate that collective motion of cells within organoid 16branches generates tension that is strong enough to induce a plastic reorganization of the 17 surrounding collagen network which results in the formation of mechanically stable collagen cages. 18Such matrix encasing in turn directs further tension generation, branch outgrowth and plastic 19deformation of the matrix. The identified mechanical feedback-loop sets a framework to understand 20 how mechanical cues direct organogenesis. 21

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Lisa K. Meixner

Quantification of regenerative potential in primary human mammary epithelial cells

An Organotypic 3D Assay for Primary Human Mammary Epithelial Cells that Recapitulates Branching Morphogenesis

Twist1 induces distinct cell states depending on TGFBR1-activation

Mechanical plasticity of the ECM directs invasive branching morphogenesis in human mammary gland organoids

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