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GRHL3 activates FSCN1 to relax cell-cell adhesions between migrating keratinocytes during wound reepithelialization
Ghaidaa Kashgari, Sanan Venkatesh, Samuel Refuerzo, Brandon Pham, Anita Bayat, Rachel Herndon Klein, Raul Ramos, Albert Paul Ta, Maksim V. Plikus, Ping H. Wang, Bogi Andersen
Ghaidaa Kashgari, Sanan Venkatesh, Samuel Refuerzo, Brandon Pham, Anita Bayat, Rachel Herndon Klein, Raul Ramos, Albert Paul Ta, Maksim V. Plikus, Ping H. Wang, Bogi Andersen
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Research Article Dermatology Genetics

GRHL3 activates FSCN1 to relax cell-cell adhesions between migrating keratinocytes during wound reepithelialization

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Abstract

The migrating keratinocyte wound front is required for skin wound closure. Despite significant advances in wound healing research, we do not fully understand the molecular mechanisms that orchestrate collective keratinocyte migration. Here, we show that, in the wound front, the epidermal transcription factor Grainyhead like-3 (GRHL3) mediates decreased expression of the adherens junction protein E-cadherin; this results in relaxed adhesions between suprabasal keratinocytes, thus promoting collective cell migration and wound closure. Wound fronts from mice lacking GRHL3 in epithelial cells (Grhl3-cKO) have lower expression of Fascin-1 (FSCN1), a known negative regulator of E-cadherin. Assay for Transposase-Accessible Chromatin using sequencing (ATAC-seq) on wounded keratinocytes shows decreased wound-induced chromatin accessibility near the Fscn1 gene in Grhl3-cKO mice, a region enriched for GRHL3 motifs. These data reveal a wound-induced GRHL3/FSCN1/E-cadherin pathway that regulates keratinocyte-keratinocyte adhesion during wound-front migration; this pathway is activated in acute human wounds and is altered in diabetic wounds in mice, suggesting translational relevance.

Authors

Ghaidaa Kashgari, Sanan Venkatesh, Samuel Refuerzo, Brandon Pham, Anita Bayat, Rachel Herndon Klein, Raul Ramos, Albert Paul Ta, Maksim V. Plikus, Ping H. Wang, Bogi Andersen

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Figure 5

GRHL3 upregulates FSCN1 in migrating wound-front keratinocytes.

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GRHL3 upregulates FSCN1 in migrating wound-front keratinocytes.
(A) Norm...
(A) Normalized Fscn1 mRNA expression (RPKM; mean ± SEM) in unwounded and wounded keratinocytes in WT mice 3 days after wounding (*P < 0.05). (B) Immunofluorescence analysis of FSCN1 (anti-FSCN1) expression in day 3 wound sections in WT and Grhl3-cKO mice. Dashed lines indicate the basis of the wound front. White boxes indicate the areas that are magnified on the top right. Scale bar: 40 μm. (C) Immunofluorescence analysis of FSCN1 (green), E-cadherin (red), and DAPI (blue) in nonmigrating and migrating HaCaT cells 12 hours after scratch. Scale bar: 10 μm. White arrows point to E-cadherin expression. Dashed lines indicate the leading front (right panel). (D) Immunofluorescence analysis of FSCN1 (green), E-cadherin (red), and DAPI (blue) in migrating HaCaT cells at the leading edge in cells transfected with scramble siRNAs (upper) and Grhl3 siRNAs (lower). Dashed lines indicate the original scratch area. Scale bar: 150 μm. Higher magnification of the area in the demarcated boxes (left panels) showing immunofluorescence staining of E-cadherin (red) and DAPI (blue) in migrating HaCaT cells transfected with scramble siRNAs and Grhl3 siRNAs (right panels). Scale bar: 30 μm. (E) Immunofluorescence staining of FSCN1 (left column) and E-cadherin (right column) in migrating HaCaT cells transfected with scramble siRNAs (control), FSCN1 siRNAs, and hFscn1(pRP-EGFP-hFSCN1). Scale bars: 30 μm (left) and 10 μm (right). White arrows point to E-cadherin expression at the cell membrane. (F) Immunofluorescence analysis of FSCN1 (green), E-cadherin (red), and DAPI (blue) in HaCaT cells transfected with GRHL3 siRNAs and pRP-EGFP-hFSCN1 plasmid. The white asterisk indicates a HaCaT cell with high FSCN1 expression. The yellow asterisk indicates a HaCaT cell with low FSCN1 expression. The white arrow points to the absent E-cadherin protein at the cell membrane. The yellow arrow points to E-cadherin at the cell membrane. Scale bar: 10 μm.

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