Major
burns induce immune complications, which are associated with myeloid cell activation by ill-defined mechanisms. Although γδ T cells have been shown to be important in postinjury
inflammation and wound healing, their role in the regulation of myeloid cells remains unknown. To study this, wild-type (WT) and γδ T cell-deficient (δTCR) mice were subjected to major
burn (25% total body surface area, third degree) or
sham treatment. At 3 days thereafter, skin samples were assayed for
cytokine content or used to isolate single cells that were used for myeloid cell characterization by flow cytometry. The number of CD11b myeloid cells increased by approximately 75% in the
wound skin of WT mice. This influx was caused by increased myeloid-derived suppressor cells (CD11b GR1) whose numbers increased 19-fold compared with those of
sham skin. In contrast, macrophage (MØ; CD11b F4/80) numbers decreased by approximately 50% after
burn. In δTCR mice,
burn increased the myeloid cell numbers approximately 5-fold. The increase in myeloid cells at the injury site of δTCR mice was caused by both a myeloid-derived suppressor cell (50-fold) and a MØ (2-fold) influx.
Burn increased skin
cytokine levels for a number of prototypic inflammatory
cytokines (
interleukin 1β,
interleukin 6,
tumor necrosis factor-α,
macrophage inflammatory protein [MIP] 1β, etc).
Tumor necrosis factor-α, MIP-1α, and MIP-1β levels were further elevated (2- to 3-fold) in the injured skin of δTCR mice compared with those of WT mice. In conclusion, these data show that γδ T cells regulate myeloid cell infiltration of the
wound site and act to quell
inflammation, thereby promoting the transition to the proliferative phase of wound healing.