In addition to tests for the group-specific hexon antigen of adenoviruses, adenoviruses can be detected in clinical specimens by hybridization assays utilizing the widely shared base sequences of the region of the hexon gene that codes for the group-reactive determinants. We have developed a liquid-phase hybridization system with biotin-and europium-labeled probes which are reacted after DNA amplification of a 161-bp region of the hexon gene and which are quantitated by time-resolved (TR) fluorometry in streptavidin-coated microtiter wells. Polymerase chain reaction (PCR)-TR fluorometry is not a rapid test in the usual sense, but it is highly useful for specimens with inherent toxicity or with low virus yield, such as organ minces and specimens obtained late in the course of an illness. In a survey of 103 specimens tested by this method, including urine, stool, and tissue suspensions, the agreement with the hexon-specific TR fluoroimmunoassay antigen test for positive specimens was 100%Yv and the sensitivity compared with that of virus culture was 91%. The PCR-TR fluorometry system was also shown to be advantageous as a quantitative measure of PCR products.
We identified several types of neutralization effected by F and G protein monoclonal antibodies (MAbs) reacted individually or as mixtures against respiratory syncytial virus (RSV). Neutralizing activity was identified by a microneutralization test in which virus replication was determined by enzyme immunoassay. Complete neutralization was seen only with MAbs against the F protein. Strain-specific neutralization, complete neutralization against some strains of RSV, and no neutralization against other strains were seen with an additional MAb against the F protein. Partial neutralization, virus replication significantly reduced but still present, and no neutralization were seen with MAbs against both the F and G proteins. Enhanced neutralization, enhanced efficacy of neutralization, or increased neutralizing titer with a mixture of two MAbs over that for the individual MAbs was seen with all MAbs against the F protein and all but three MAbs against the G protein. Most (10 of 13) of the MAbs that exhibited neutralizing activity reacted with some but not all strains of RSV in an enzyme immunoassay. The epitopes corresponding to these 10 MAbs probably contribute to the strain-specific component of the neutralizing antibody response to RSV. Our results suggest that interpretation of RSV neutralization with MAbs is complex and that studies of such neutralization should include mixtures of MAbs and multiple RSV strains.
Virus infectivity and antibody neutralization titers for respiratory syncytial virus were determined in cell cultures in microtiter plates. After an appropriate incubation period, the cells were fixed, and an enzymelinked immunosorbent assay was performed directly in the microtiter plates for detection of virus. Results could be read and recorded automatically, which is especially helpful when running large numbers of tests.
An ali-monoclonal antibody, time-resolved fluoroimmunoassay was compared with several enzyme immunoassays for the detection of respiratory syncytial virus and parainfluenza virus type 1, 2, and 3 antigens in clinical specimens. The most sensitive enzyme immunoassay for parainfluenza virus type 1 was an allmonoclonal antibody assay with biotin-labeled detector antibody and streptavidin-peroxidase conjugate, but for respiratory syncytial virus and parainfluenza virus types 2 and 3 the most sensitive assay was a polyclonal antibody assay with horse capture antibodies and bovine or rabbit detector antibodies with anti-species peroxidase. All tests were evaluated with nasopharyngeal aspirate specimens from respiratory illnesses and with cell culture harvests of multiple strains of each virus isolated over many years. The time-resolved fluoroimmunoassay detected respiratory syncytial virus antigen in 92% of the specimens positive by culture, which was a decidedly higher sensitivity than either the monoclonal or polyclonal antibody enzyme immunoassay format (62 and 76%, respectively). For the parainfluenza viruses the time-resolved fluoroimmunoassay detected type-specific antigen in 94 to 100% of culture-positive specimens and again was more sensitive than the all-monoclonal antibody enzyme immunoassays (75 to 89%) or all-polyclonal antibody enzyme immunoassays (66 to 95%). Combined with results from a previously reported adenovirus timeresolved fluoroimmunoassay, these tests identified respiratory antigens in large numbers of clinical specimens.
Monoclonal antibodies were prepared to the F and M proteins of parainfluenza 4A and 4B and to mumpsvirus to obtain reagents that could be configured into type-specific yet broadly-reactive IFA, EIA, and TR-FIA tests. Several antibodies to parainfluenza 4A also detected subtype 4B, although to a somewhat lower signal, and thus were well suited to generic parainfluenza type 4 tests that were comparable to similar tests previously described for parainfluenza types 1, 2, and 3. Monoclonals to subtype 4B were less able to detect 4A because of high background problems in one or another test. Monoclonals to mumpsvirus F protein were completely type-specific. These antibodies were screened by IFA and EIA for broad reactivity with diverse strains of each virus and were configured into optimized EIA and TR-FIA tests. The all-monoclonal tests were then compared to polyclonal tests in terms of their ability to detect virus in clinical specimens. The all-monoclonal TR-FIA was uniformly the most sensitive, detecting virus in 80% of culture-positive parainfluenza 4A specimens, 67% of parainfluenza 4B specimens, and 90% of mumps specimens, compared to 40-67% for the monoclonal EIA tests and 33-60% for the polyclonal EIA tests. For parainfluenza 4 TR-FIA, mean P/N values were 379 for subtype 4A cell culture fluids (228 for subtype 4B cultures) and 57 for 4A clinical specimens (43 for 4B specimens). For mumpsvirus TR-FIA, mean P/N values were 27 for culture fluids and 32 for clinical specimens. The sensitivities of the TR-FIA were determined with purified virus to be 0.28 ng virus per well for parainfluenza 4A and 0.70 ng virus per well for mumpsvirus.
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