The ability of surfactant protein A (SP-A) to aggregate and opsonize type a and b Hemophilus influenzae was investigated. Type a, but not type b, was aggregated by SP-A. Aggregation was maximal at 24 micrograms SP-A/ml and was Ca(2+)-dependent. Aggregation of type a was inhibited by D-glucosyl-BSA but not by high concentrations of monosaccharides (D-mannose, D-galactose, D-glucose, or L-fucose) or by sialic acid, purified type a capsular polysaccharide, or type IV collagen. In Western blots, 125I-labeled SP-A bound to the major outer membrane protein (putatively P2) of type a hemophilus by a Ca(2+)-dependent mechanism. This binding was competitively inhibited by excess unlabeled SP-A. 125I-labeled SP-A also bound to the major membrane protein of type b, but at less than 5% of the level observed for type a. SP-A did not bind to lipooligosaccharides of either type a or type b. SP-A increased association of type a, but not type b, hemophilus with alveolar macrophages. After opsonization with SP-A, type a hemophilus were killed by alveolar macrophages, as indicated by bactericidal assays and the release of soluble, radiolabeled products from leukocytes. It is concluded that SP-A aggregated and opsonized type a hemophilus, but not type b, possibly because SP-A bound to the P2 outer membrane protein of type a to a greater extent.
Capsular polysaccharide was detected in the serum in 19 of 46 patients with pneumococcal pneumonia. Antigenemia was strongly associated with bacteremia and with infection by low-numbered serotypes. During antibiotic therapy, the concentration of polysaccharide in the circulation declined progressively, but circulating antigen remained detectable in two thirds of cases for 2 weeks or longer. The development of measurable type-specific antibody was delayed in patients with antigenemia. It is not known whether this delay was due to diminished antibody production or to neutralization of antibody by circulating antigen. Despite effective antibiotic therapy many patients with antigenemia had a severe and protracted illness; this may have been related to diminished availability of antibody early in the infection.
Influenza A and B are RNA-containing viruses that frequently infect humans. Currently, sensitive detection of these viruses requires fresh respiratory secretions and special facilities for culture. To facilitate diagnosis of influenza, the polymerase chain reaction (PCR) was used in the present studies to detect DNA produced by reverse transcription of influenzal RNA in vaccines, tissue culture fluids, and stored respiratory secretions. Primers were directed at targets on the highly conserved segment 7 (matrix gene) of influenza A (212-bp product) and B (365-bp product). The primers were completely type specific. Critical variables in the assay were the concentration of pleotropic salts used during preparation of samples, the use of carrier RNA and RNase inhibitors during sample preparation, and the use of optimum K+ and Mg2+ levels at each step. Studies of 33 patients with symptoms of viral respiratory infection whose nasal washes had been cultured and frozen for up to 1 year before assay showed that PCR provided type-specific detection of influenza with a sensitivity comparable to that of culture of the fresh secretions. The assay offers a powerful test for detection of devitalized influenza viruses and may be useful in both diagnostic work and epidemiological studies of influenza.
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