Trefoil Factor 2 Promotes Type 2 Immunity and Lung Repair through Intrinsic Roles in Hematopoietic and Nonhematopoietic Cells.

Trefoil factors (TFFs) are small secreted proteins that regulate tissue integrity and repair at mucosal surfaces, particularly in the gastrointestinal tract. However, their relative contribution(s) to controlling baseline lung function or the extent of infection-induced lung injury are unknown issues. With the use of irradiation bone marrow chimeras, we found that TFF2 produced from both hematopoietic- and nonhematopoietic-derived cells is essential for host protection, proliferation of alveolar type 2 cells, and restoration of pulmonary gas exchange after infection with the hookworm parasite Nippostrongylus brasiliensis. In the absence of TFF2, lung epithelia were unable to proliferate and expressed reduced lung mRNA transcript levels for type 2 response-inducing IL-25 and IL-33 after infectious injury. Strikingly, even in the absence of infection or irradiation, TFF2 deficiency compromised lung structure and function, as characterized by distended alveoli and reduced blood oxygen levels relative to wild-type control mice. Taken together, we show a previously unappreciated role for TFF2, produced by either hematopoietic or nonhematopoietic sources, as a pro-proliferative factor for lung epithelial cells under steady-state and infectious injury conditions.

Myeloid-Restricted AMPKα1 Promotes Host Immunity and Protects against IL-12/23p40-Dependent Lung Injury during Hookworm Infection.

How the metabolic demand of parasitism affects immune-mediated resistance is poorly understood. Immunity against parasitic helminths requires M2 cells and IL-13, secreted by CD4(+) Th2 and group 2 innate lymphoid cells (ILC2), but whether certain metabolic enzymes control disease outcome has not been addressed. This study demonstrates that AMP-activated protein kinase (AMPK), a key driver of cellular energy, regulates type 2 immunity and restricts lung injury following hookworm infection. Mice with a selective deficiency in the AMPK catalytic α1 subunit in alveolar macrophages and conventional dendritic cells produced less IL-13 and CCL17 and had impaired expansion of ILC2 in damaged lung tissue compared with wild-type controls. Defective type 2 responses were marked by increased intestinal worm burdens, exacerbated lung injury, and increased production of IL-12/23p40, which, when neutralized, restored IL-13 production and improved lung recovery. Taken together, these data indicate that defective AMPK activity in myeloid cells negatively impacts type 2 responses through increased IL-12/23p40 production. These data support an emerging concept that myeloid cells and ILC2 can coordinately regulate tissue damage at mucosal sites through mechanisms dependent on metabolic enzyme function.

Macrophages promote epithelial proliferation following infectious and non-infectious lung injury through a Trefoil factor 2-dependent mechanism.

Coordinated efforts between macrophages and epithelia are considered essential for wound healing, but the macrophage-derived molecules responsible for repair are poorly defined. This work demonstrates that lung macrophages rely upon Trefoil factor 2 to promote epithelial proliferation following damage caused by sterile wounding, Nippostrongylus brasiliensis or Bleomycin sulfate. Unexpectedly, the presence of T, B, or ILC populations was not essential for macrophage-driven repair. Instead, conditional deletion of TFF2 in myeloid-restricted CD11cCre TFF2 flox mice exacerbated lung pathology and reduced the proliferative expansion of CD45- EpCAM+ pro-SPC+ alveolar type 2 cells. TFF2 deficient macrophages had reduced expression of the Wnt genes Wnt4 and Wnt16 and reconstitution of hookworm-infected CD11cCre TFF2flox mice with rWnt4 and rWnt16 restored the proliferative defect in lung epithelia post-injury. These data reveal a previously unrecognized mechanism wherein lung myeloid phagocytes utilize a TFF2/Wnt axis as a mechanism that drives epithelial proliferation following lung injury.