Disruption of basal JNK activity differentially affects key fibroblast function important for wound healing

Javelaud D, Laboureau J, Gabison E, Verrecchia F and Mauviel A
Source: J Biol Chem
Publication Date: (2003)
Issue: 278(27): 24624-24628
Research Area:
Dermatology/Tissue Engineering
Cells used in publication:
Fibroblast, dermal (NHDF-Neo), human neonatal
Species: human
Tissue Origin: dermal

Primary human dermal fibroblasts, nucleofected with an expression vector coding for dominant negative MKK4, did not show altered collagen gene expression as measured by Northern blotting.


We used both a gene knockout approach and pharmacologic modulation to study the implication of the JNK pathway in regulating fibroblast motility, capacity to contract mechanically unloaded collagen gels, and type I collagen gene expression in vitro. These parameters, which are important for tissue repair, are positively regulated by transforming growth factor (TGF)-beta, a cytokine viewed as playing a master role during wound healing. We demonstrate that basal JNK activity is critical for fibroblast motility because (a) mouse embryo jnk-/- fibroblasts exhibit significantly lower ability to close mechanically induced cell layer wounds than their wild-type (wt) counterparts, and (b) wound closure by human dermal fibroblasts is dramatically impaired by the specific JNK inhibitor SP600125. junAA fibroblasts, in which amino acids Ser63 and Ser73 of c-Jun are replaced by two Ala residues so that c-Jun cannot be phosphorylated by JNK, also exhibited impaired motility, suggesting that c-Jun phosphorylation by JNK is critical for fibroblast migration. In sharp contrast to their lesser motility on plastic, jnk-/- and junAA fibroblasts contracted free-floating, mechanically unloaded, collagen lattices markedly faster than wt fibroblasts. Furthermore, basal mRNA steady-state levels for types I and III collagen genes were similar in jnk-/- and wt fibroblasts. Likewise, overexpression of a dominant-negative mutant form of MKK4 in dermal fibroblasts did not affect collagen expression. We also demonstrate that basal JNK activity does not affect either TGF-beta-induced collagen gene expression or lattice contraction, whereas on the other hand, the blockage of motility initiated by JNK inhibition cannot be overcome by TGF-beta. Together these results demonstrate discrete, yet significant and highly specific, regulation of fibroblast functions important for wound healing by basal JNK activity.