Collagen microarchitecture mechanically controls myofibroblast differentiation

Seo, Bo Ri; Chen, Xingyu; Lu, Ling; Song, Young Hye; Shimpi, Adrian A.; Choi, Sung Sik; González, Jacqueline; Sapudom, Jiranuwat; Wang, Karin; Eguiluz, Roberto C. Andresen; Gourdon, Delphine; Shenoy, Vivek B.; Fischbach, Claudia

doi:10.1073/pnas.1919394117

Cited by 151 publications

(131 citation statements)

References 82 publications

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“…Experiments performed using adipose stromal cells (ASCs) cultured in collagen matrices of different architectures show that matrices with thicker fibers promote ASC phenotype transition into myofibroblast through regulation of VEGF and IL-8 secretion (Seo et al, 2020). Intriguingly, nanoscale changes in the ligand spacing of model ECM fibers were shown to influence the collective cell behavior and overall characteristics, such as action-potential propagation in cardiac myocytes, on the scale of centimeters, suggesting effects on the ECM organization over six orders of magnitude of length scale (Kim et al, 2010).…”

Section: Cell Phenotype Is Driven By Physical and Mechanical Propertimentioning

confidence: 99%

“…When ASCs that are undergoing FMT are treated with Y27632, which inhibits ROCK and reduces α-SMA levels (Seo et al, 2015), as well as diminishing the capability of the cells to sense the environment by inhibiting the receptors to TGF-β, the cells exhibit a decrease in myofibroblast transition and moreover reduced VEGF and IL-8 secretion. On the contrary, treating these cells with blebbistatin influences their morphology, confining the adhesions to the extreme cell periphery, causing actin stress fiber formation and enhancing contractility, thereby stimulating ASC myofibroblast transition (Seo et al, 2020). Consistent with this link between cell mechanosensing, force generation, mechanical properties, and organization, it is also increasingly recognized that ECM viscoelasticity, non-linear elasticity, and fiber rearrangement play a central role for cell behavior such as proliferation and multilineage differentiation (Baker et al, 2015;Chaudhuri et al, 2016;Das et al, 2016;Xie et al, 2017;Matera et al, 2019;Vining et al, 2019).…”

Section: Mechanotransduction Leads To Distinct Internal Cellular Rearmentioning

confidence: 99%

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Mechanical and Physical Regulation of Fibroblast–Myofibroblast Transition: From Cellular Mechanoresponse to Tissue Pathology

D’Urso

Kurniawan

2020

Front. Bioeng. Biotechnol.

164

129

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Fibroblasts are cells present throughout the human body that are primarily responsible for the production and maintenance of the extracellular matrix (ECM) within the tissues. They have the capability to modify the mechanical properties of the ECM within the tissue and transition into myofibroblasts, a cell type that is associated with the development of fibrotic tissue through an acute increase of cell density and protein deposition. This transition from fibroblast to myofibroblast—a well-known cellular hallmark of the pathological state of tissues—and the environmental stimuli that can induce this transition have received a lot of attention, for example in the contexts of asthma and cardiac fibrosis. Recent efforts in understanding how cells sense their physical environment at the micro- and nano-scales have ushered in a new appreciation that the substrates on which the cells adhere provide not only passive influence, but also active stimulus that can affect fibroblast activation. These studies suggest that mechanical interactions at the cell–substrate interface play a key role in regulating this phenotype transition by changing the mechanical and morphological properties of the cells. Here, we briefly summarize the reported chemical and physical cues regulating fibroblast phenotype. We then argue that a better understanding of how cells mechanically interact with the substrate (mechanosensing) and how this influences cell behaviors (mechanotransduction) using well-defined platforms that decouple the physical stimuli from the chemical ones can provide a powerful tool to control the balance between physiological tissue regeneration and pathological fibrotic response.

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Section: Cell Phenotype Is Driven By Physical and Mechanical Propertimentioning

confidence: 99%

Section: Mechanotransduction Leads To Distinct Internal Cellular Rearmentioning

confidence: 99%

Mechanical and Physical Regulation of Fibroblast–Myofibroblast Transition: From Cellular Mechanoresponse to Tissue Pathology

D’Urso

Kurniawan

2020

Front. Bioeng. Biotechnol.

164

129

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“…Although the effect of stiffness has been decoupled from the effect of the pore size of a collagen matrix [ 106 ], the stiffness range is relatively low, which is suitable for the study of breast cancer and might not apply to pancreatic cancer, which showed a higher stiffness range (i.e., Young’s modulus: 1–4 kPa) [ 37 ]. Similarly, Seo et al suggested that the microarchitecture (e.g., pore size and fiber diameter) of the collagen matrix guides myofibroblast differentiation, and the effect is independent of the stiffness of the bulk collagen matrix [ 118 ].…”

Section: Stiffness Gradient In Tme-mimetic Hydrogelsmentioning

confidence: 99%

Hydrogel Models with Stiffness Gradients for Interrogating Pancreatic Cancer Cell Fate

Chang

Lin

2021

Bioengineering

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Pancreatic ductal adenocarcinoma (PDAC) is the most common type of pancreatic cancer and has seen only modest improvements in patient survival rate over the past few decades. PDAC is highly aggressive and resistant to chemotherapy, owing to the presence of a dense and hypovascularized fibrotic tissue, which is composed of stromal cells and extracellular matrices. Increase deposition and crosslinking of matrices by stromal cells lead to a heterogeneous microenvironment that aids in PDAC development. In the past decade, various hydrogel-based, in vitro tumor models have been developed to mimic and recapitulate aspects of the tumor microenvironment in PDAC. Advances in hydrogel chemistry and engineering should provide a venue for discovering new insights regarding how matrix properties govern PDAC cell growth, migration, invasion, and drug resistance. These engineered hydrogels are ideal for understanding how variation in matrix properties contributes to the progressiveness of cancer cells, including durotaxis, the directional migration of cells in response to a stiffness gradient. This review surveys the various hydrogel-based, in vitro tumor models and the methods to generate gradient stiffness for studying migration and other cancer cell fate processes in PDAC.

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“…As shown in Figure 2 B, the interactions between adipocytes and collagen fibrils could be observed. In addition, Seo et al reported that collagen fibril diameter can also trigger adipocyte fibrotic functions [ 118 ]. Although 3D models were used to study adipocyte functions, less is known about whether tissue microstructure and stiffness, as well as other ECM components, influence adipogenesis.…”

Section: Modeling Adipogenesis Via Three-dimensional (3d) Culturementioning

confidence: 99%

Modeling Adipogenesis: Current and Future Perspective

Bahmad

Daouk

Azar

et al. 2020

Cells

Self Cite

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Adipose tissue is contemplated as a dynamic organ that plays key roles in the human body. Adipogenesis is the process by which adipocytes develop from adipose-derived stem cells to form the adipose tissue. Adipose-derived stem cells’ differentiation serves well beyond the simple goal of producing new adipocytes. Indeed, with the current immense biotechnological advances, the most critical role of adipose-derived stem cells remains their tremendous potential in the field of regenerative medicine. This review focuses on examining the physiological importance of adipogenesis, the current approaches that are employed to model this tightly controlled phenomenon, and the crucial role of adipogenesis in elucidating the pathophysiology and potential treatment modalities of human diseases. The future of adipogenesis is centered around its crucial role in regenerative and personalized medicine.

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Collagen microarchitecture mechanically controls myofibroblast differentiation

Cited by 151 publications

References 82 publications

Mechanical and Physical Regulation of Fibroblast–Myofibroblast Transition: From Cellular Mechanoresponse to Tissue Pathology

Mechanical and Physical Regulation of Fibroblast–Myofibroblast Transition: From Cellular Mechanoresponse to Tissue Pathology

Hydrogel Models with Stiffness Gradients for Interrogating Pancreatic Cancer Cell Fate

Modeling Adipogenesis: Current and Future Perspective

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