Thrombospondin-1 triggers macrophage IL-10 production and promotes resolution of experimental lung injury.

Mononuclear phagocyte recognition of apoptotic cells triggering suppressive cytokine signaling is a key event in inflammation resolution from injury. Mice deficient in thrombospondin (TSP)-1 (thbs1⁻/⁻), an extracellular matrix glycoprotein that bridges cell-cell interactions, are prone to lipopolysaccharide-induced lung injury and show defective macrophage interleukin (IL)-10 production during the resolution phase of inflammation. Reconstitution of IL-10 rescues thbs1⁻/⁻ mice from persistent neutrophilic lung inflammation and injury and thbs1⁻/⁻ alveolar macrophages show defective IL-10 production following intratracheal instillation of apoptotic neutrophils despite intact efferocytosis. Following co-culture with apoptotic neutrophils, thbs1⁻/⁻ macrophages show a selective defect in IL-10 production, whereas prostaglandin E2 and transforming growth factor beta 1 responses remain intact. Full macrophage IL-10 responses require the engagement of TSP-1 structural repeat 2 domain and the macrophage scavenger receptor CD36 LIMP-II Emp sequence homology (CLESH) domain in vitro. Although TSP-1 is not essential for macrophage engulfment of apoptotic neutrophils in vivo, TSP-1 aids in the curtailment of inflammatory responses during the resolution phase of injury in the lungs by providing a means by which apoptotic cells are recognized and trigger optimal IL-10 production by macrophages.

Mutational evidence of transition state stabilization by serine 88 in Escherichia coli type I signal peptidase.

Type I signal peptidase (SPase I) catalyzes the hydrolytic cleavage of the N-terminal signal peptide from translocated preproteins. SPase I belongs to a novel class of Ser proteases that utilize a Ser/Lys dyad catalytic mechanism instead of the classical Ser/His/Asp triad found in most Ser proteases. Recent X-ray crystallographic studies indicate that the backbone amide nitrogen of the catalytic Ser 90 and the hydroxyl side chain of Ser 88 might participate as H-bond donors in the transition-state oxyanion hole. In this work, contribution of the side-chain Ser 88 in Escherichia coli SPase I to the stabilization of the transition state was investigated through in vivo and in vitro characterizations of Ala-, Cys-, and Thr-substituted mutants. The S88T mutant maintains near-wild-type activity with the substrate pro-OmpA nuclease A. In contrast, substitution with Cys at position 88 results in more than a 740-fold reduction in activity (k(cat)) whereas S88A retains much less activity (>2440-fold decrease). Measurements of the kinetic constants of the individual mutant enzymes indicate that these decreases in activity are attributed mainly to decreases in k(cat) while effects on K(m) are minimal. Thermal inactivation and CD spectroscopic analyses indicate no global conformational perturbations of the Ser 88 mutants relative to the wild-type E. coli SPase I enzyme. These results provide strong evidence for the stabilization by Ser 88 of the oxyanion intermediate during catalysis by E. coli SPase I.

The role of the conserved box E residues in the active site of the Escherichia coli type I signal peptidase.

Type I signal peptidases are integral membrane proteins that function to remove signal peptides from secreted and membrane proteins. These enzymes carry out catalysis using a serine/lysine dyad instead of the prototypical serine/histidine/aspartic acid triad found in most serine proteases. Site-directed scanning mutagenesis was used to obtain a qualitative assessment of which residues in the fifth conserved region, Box E, of the Escherichia coli signal peptidase I are critical for maintaining a functional enzyme. First, we find that there is no requirement for activity for a salt bridge between the invariant Asp-273 and the Arg-146 residues. In addition, we show that the conserved Ser-278 is required for optimal activity as well as conserved salt bridge partners Asp-280 and Arg-282. Finally, Gly-272 is essential for signal peptidase I activity, consistent with it being located within van der Waals proximity to Ser-278 and general base Lys-145 side-chain atoms. We propose that replacement of the hydrogen side chain of Gly-272 with a methyl group results in steric crowding, perturbation of the active site conformation, and specifically, disruption of the Ser-90/Lys-145 hydrogen bond. A refined model is proposed for the catalytic dyad mechanism of signal peptidase I in which the general base Lys-145 is positioned by Ser-278, which in turn is held in place by Asp-280.