Surfactant protein A regulates complement activation.

Complement proteins aid in the recognition and clearance of pathogens from the body. C1, the first protein of the classical pathway of complement activation, is a calcium-dependent complex of one molecule of C1q and two molecules each of C1r and C1s, the serine proteases that cleave complement proteins. Upon binding of C1q to Ag-bound IgG or IgM, C1r and C1s are sequentially activated and initiate the classical pathway of complement. Because of structural and functional similarities between C1q and members of the collectin family of proteins, including pulmonary surfactant protein A (SP-A), we hypothesized that SP-A may interact with and regulate proteins of the complement system. Previously, SP-A was shown to bind to C1q, but the functional significance of this interaction has not been investigated. Binding studies confirmed that SP-A binds directly to C1q, but only weakly to intact C1. Further investigation revealed that the binding of SP-A to C1q prevents the association of C1q with C1r and C1s, and therefore the formation of the active C1 complex required for classical pathway activation. This finding suggests that SP-A may share a common binding site for C1r and C1s or Clq. SP-A also prevented C1q and C1 from binding to immune complexes. Furthermore, SP-A blocked the ability of C1q to restore classical pathway activity to C1q-depleted serum. SP-A may down-regulate complement activity through its association with C1q. We hypothesize that SP-A may serve a protective role in the lung by preventing C1q-mediated complement activation and inflammation along the delicate alveolar epithelium.

Complement-mediated host defense in the lung.

Complement is a system of plasma proteins that aids in the elimination of pathogens from the body. We hypothesized that there is a functional complement system present in the lung that aids in the removal of pathogens. Western blot analysis revealed complement proteins of the alternative and classical pathways of complement in bronchoalveolar lavage fluids (BALF) from healthy volunteers. Functional classical pathway activity was detected in human BALF, but there was no significant alternative pathway activity in lavage fluid, a finding that correlates with the low level of the alternative pathway protein, factor B, in these samples. Although the classical pathway of complement was functional in lavage fluid, the level of the classical pathway activator C1q was very low. We tested the ability of the lung- specific surfactant proteins, surfactant protein A (SP-A) and surfactant protein D (SP-D), to substitute for C1q in classical pathway activation, since they have structural homology to C1q. However, neither SP-A nor SP-D restored classical pathway activity to C1q-depleted serum. These data suggest that the classical pathway of complement is functionally active in the lung where it may play a role in the recognition and clearance of bacteria.

Surfactant protein-A binds group B streptococcus enhancing phagocytosis and clearance from lungs of surfactant protein-A-deficient mice.

Surfactant protein-A (SP-A) gene-targeted mice clear group B streptococcus (GBS) from the lungs at a slower rate than wild-type mice. To determine mechanisms by which SP-A enhances pulmonary clearance of GBS, the role of SP-A in binding and phagocytosis of GBS was assessed in SP-A (-/-) mice infected with GBS in the presence and absence of exogenous SP-A. Coadministration of GBS with exogenous SP-A decreased GBS colony counts in lung homogenates of SP-A (-/-) mice. SP-A bound to GBS in a calcium-dependent manner. Although pulmonary infiltration with macrophages was not altered in SP-A (-/-) versus wild-type mice after GBS infection, the number of alveolar macrophages with phagocytosed bacteria was lower in the SP-A (-/-) mice than in the wild-type mice. When SP-A was coadministered with GBS, phagocytosis was significantly increased. Oxygen radical production by alveolar macrophages from SP-A (-/-) mice infected with GBS was decreased compared with wild-type controls and was increased when SP-A (-/-) mice were infected in the presence of exogenous SP-A. Superoxide (SO) radical generation was deficient in macrophages from SP-A (-/-) mice. SP-A plays an important role in GBS clearance in vivo, mediated in part by binding to and enhancing GBS phagocytosis and by increasing SO production by alveolar macrophages.