The Connexin 43 Carboxyl Terminal Mimetic Peptide αCT1 Prompts Differentiation of a Collagen Scar Matrix Resembling Unwounded Skin

Montgomery, Jade; Richardson, William J.; Rhett, J. Matthew; Bustos, Francis; Degen, Katherine; Ghatnekar, Gautam S.; Grek, Christina L.; Marsh, Spencer; Jourdan, L. Jane; Holmes, Jeffrey W.; Gourdie, Robert G.

doi:10.1101/2020.07.07.191742

Cited by 3 publications

(2 citation statements)

References 71 publications

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“…Moreover, PI3K activation in this study triggered an interaction between α5β1-integrin and Cx43, resulting in the opening of Cx43 HCs. A recent study reporting in silico (computational and mathematical), ex vivo, and in vitro evidence of scar formation demonstrated that αCT1 may render cells insensitive to biomechanical inputs during scar differentiation [ 203 ]. Computational modeling predicted that αCT1′s alteration of collagen organization, resulting from its effects on fibroblast migration characteristics (as fibroblast secrete collagen), occurs in a mechanically-sensitive manner.…”

Section: Channel-independent Roles Of Cx43 In Barrier Functionmentioning

confidence: 99%

Cx43 and the Actin Cytoskeleton: Novel Roles and Implications for Cell-Cell Junction-Based Barrier Function Regulation

Strauss

Gourdie

2020

Biomolecules

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Barrier function is a vital homeostatic mechanism employed by epithelial and endothelial tissue. Diseases across a wide range of tissue types involve dynamic changes in transcellular junctional complexes and the actin cytoskeleton in the regulation of substance exchange across tissue compartments. In this review, we focus on the contribution of the gap junction protein, Cx43, to the biophysical and biochemical regulation of barrier function. First, we introduce the structure and canonical channel-dependent functions of Cx43. Second, we define barrier function and examine the key molecular structures fundamental to its regulation. Third, we survey the literature on the channel-dependent roles of connexins in barrier function, with an emphasis on the role of Cx43 and the actin cytoskeleton. Lastly, we discuss findings on the channel-independent roles of Cx43 in its associations with the actin cytoskeleton and focal adhesion structures highlighted by PI3K signaling, in the potential modulation of cellular barriers. Mounting evidence of crosstalk between connexins, the cytoskeleton, focal adhesion complexes, and junctional structures has led to a growing appreciation of how barrier-modulating mechanisms may work together to effect solute and cellular flux across tissue boundaries. This new understanding could translate into improved therapeutic outcomes in the treatment of barrier-associated diseases.

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Section: Channel-independent Roles Of Cx43 In Barrier Functionmentioning

confidence: 99%

Cx43 and the Actin Cytoskeleton: Novel Roles and Implications for Cell-Cell Junction-Based Barrier Function Regulation

Strauss

Gourdie

2020

Biomolecules

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“…In some of these tissues, matrix structure and the resulting mechanical properties vary significantly across local subregions, and the effects of such heterogeneity can be important for tissue function or failure. For example, mechanical stress gradients have been shown to produce heterogeneous structural hallmarks during headfold morphogenesis [6,7]; a hammock-like heterogeneity of matrix orientation from commissure to commissure in heart valves has been a key target of tissue engineering approaches [8,9]; the spatial transition from highly aligned tendon matrix to randomly oriented and mineralized bone matrix at the tendon-bone enthesis is critical to proper load transfer and musculoskeletal function [10,11]; spatial heterogeneity in the structural composition of aneurysms has been associated with high variation in tensile moduli and failure locations [12,13]; and collagen orientation heterogeneity in dermal wounds has been associated with improved cell infiltration and healing rates [14].…”

Section: Introductionmentioning

confidence: 99%

Fabrication and Characterization Methods for Investigating Cell-Matrix Interactions in Environments Possessing Spatial Orientation Heterogeneity

Potter

Richardson

2021

Preprint

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Fibrillar collagen is a ubiquitous structural protein that plays a significant role in determining the mechanical properties of various tissues. The constituent collagen architecture can give direct insight into the respective functional role of the tissue due to the strong structure-function relationship that is exhibited. In such tissues, matrix structure can vary across local subregions contributing to mechanical heterogeneity which can be implicated in tissue function or failure. The post-myocardial infarction scar environment is an example of note where mechanically insufficient collagen can result in impaired cardiac function and possibly tissue rupture due to post-MI cellular response and matrix interactions. In order to further develop the understanding of cell-matrix and cell-cell interactions within heterogeneous environments, we developed a method of heterogeneous collagen gel fabrication which produces a region of randomly oriented fibers directly adjacent to an interconnected region of anisotropic alignment. To fully capture and evaluate the degree of alignment and spatial orientation heterogeneity, several image processing and automated analysis methods were employed. Our analysis revealed the successful fabrication of an interconnected spatially heterogeneous collagen gel possessing distinct regions of random or preferential alignment. Additionally, embedded cell populations were observed to recognize and reorient with their underlying and surrounding architectures through our cell-centric analysis techniques.

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Fabrication and characterization methods for investigating cell-matrix interactions in environments possessing spatial orientation heterogeneity

Potter

Richardson

2021

Acta Biomaterialia

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The Connexin 43 Carboxyl Terminal Mimetic Peptide αCT1 Prompts Differentiation of a Collagen Scar Matrix Resembling Unwounded Skin

Cited by 3 publications

References 71 publications

Cx43 and the Actin Cytoskeleton: Novel Roles and Implications for Cell-Cell Junction-Based Barrier Function Regulation

Cx43 and the Actin Cytoskeleton: Novel Roles and Implications for Cell-Cell Junction-Based Barrier Function Regulation

Fabrication and Characterization Methods for Investigating Cell-Matrix Interactions in Environments Possessing Spatial Orientation Heterogeneity

Fabrication and characterization methods for investigating cell-matrix interactions in environments possessing spatial orientation heterogeneity

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