James A. Booth

Interferon assessment by the immunofluorescent, immunoperoxidase, and hemadsorption cell-counting techniques

SummaryThe immunofluorescent, immunoperoxidase, and hemadsorption cell-counting techniques were quantitatively evaluated for assessing interferon activity. The three assays exhibited parallel dose-responses and were comparable in sensitivity, precision, and reproducibility.

Activity of diesel engine emission particulates on the interferon system

Abstract When mammalian (LLC-MK2) cell monolayers were pretreated with diesel engine emission particulates of respirable size, viral induction of interferon was depressed by approximately 60%. However, the presence of particulates did not impair the ability of interferon to confer antiviral cellular resistance. When either diesel emission particulates or cell monolayers were pretreated with the nonionic polymer, poly(4-vinylpyridine-N-oxide), the inhibitory activity of particulates on interferon induction was significantly diminished or abolished. Influenza virus growth in cell monolayers pretreated with diesel emission particulates attained a two- to threefold higher level than that noted in normal cell monolayers or those containing polymer-pretreated particulates. This was related to suppression of viral interferon induction by diesel emission particulates. Removal of cell membrane-bound sialic acid by neuraminidase or pretreatment of diesel emission particulates with sialic acid abolished the adverse activity of particulates on viral interferon induction. These findings suggest that the receptivity for and interaction of cell membrane-bound sialic acid with diesel emission particulates are involved in the described altered cellular behavior in response to viral induction of interferon.

Effects of lignite fly ash particulates and soluble components on the interferon system

Induction of interferon by influenza virus was depressed by approximately 50% when mammalian (LLC-MK2) cell monolayers were pretreated with lignite fly ash. The presence of fly ash, however, did not impair the ability of exogenous interferon to confer antiviral cellular resistance. Influenza virus multiplication in cell monolayers pretreated with fly ash attained a twofold higher level of growth than that noted in normal cell monolayers. This was related to suppression of viral interferon induction by fly ash. Whereas aqueous extracts of fly ash had no adverse effect on interferon induction, extractions of fly ash by either polar or nonpolar solvents, by horse serum with or without EDTA (a metal chelator), and fractionation of serum extracts yielded corresponding compounds, most likely organic and inorganic, that were antagonistic to viral interferon induction. Residual fly ash particulates after extraction by horse serum with EDTA were still capable of inhibiting viral induction of interferon. These findings indicate that several soluble components inherent to lignite fly ash and the particulate matrix per se may modify, independently or in concert, cellular defense behavior. Neither polar, nonpolar, nor horse serum extracts of lignite fly ash, however, showed mutagenic activity as determined by the Salmonella histidine reversion assay. Removal of cell-membrane-bound sialic acid (N-acetylneuraminic acid) by neuraminidase or pretreatment of lignite fly ash with sialic acid abolished the adverse activity of fly ash on viral interferon induction. This suggests that the interaction of cell-membrane-bound sialic acid residue with fly ash particulates may be involved in the altered state of cellular behavior described in response to viral induction of interferon.

In vitro biologic responses to native and surface-modified asbestos.

A comparative study was made of in vitro biologic responses to native chrysotile, amosite, and crocidolite and corresponding asbestos fibers whose surfaces were modified by metal oxides. Interferon induction by influenza virus was depressed by approximately 50% by all native asbestos whereas corresponding surface modified asbestos minimally affected this nonspecific cellular defense mechanism. The release of the cytoplasmic enzyme, lactate dehydrogenase (LDH), and lysosomal enzymes, beta-N-acetylglucosaminidase (beta-NAG) and beta-glucuronidase (beta-Gluc), by rat alveolar macrophages after exposure to either native or surface-modified asbestos (which is indicative of membrane damage) was monitored. Although both native and surface-modified asbestos induced significant leakage of LDH, generally, lesser amounts of the enzyme were released as a result of exposure to the latter than to native asbestos. Whereas all forms of native asbestos caused significant release of beta-NAG and beta-Gluc, leakage of these enzymes from macrophages exposed to surface-modified asbestos was minimal. In contrast to native asbestos which induced irritation of cell membranes, as indicated by hemolysis of sheep erythrocytes, surface-modified asbestos exhibited minimal hemolytic activity. The findings indicate that surface modification of different asbestos by metal oxides generally lessened the adverse effect of the native mineral on the aforementioned biologic entities.

Coinhibition of viral interferon induction by benzo[a]pyrene and chrysotile asbestos

Benzo[a]pyrene (B[a]P) and its noncarcinogenic analog, benzo[e]pyrene (B[e]P), each in combination with chrysotile, were studied for their inhibitory effects on interferon (IFN) induction by influenza virus in rhesus monkey kidney (LLC-MK2) cell monolayers. B[a]P alone had no adverse effect on IFN induction; however, from 60 to 70% inhibition of IFN production occurred when B[a]P was enzymatically activated by rat liver S9. Chrysotiles inhibitory effect on the IFN process was similar in magnitude to that of activated B[a]P. The combination of activated B[a]P with chrysotile resulted in coinhibition of IFN induction which significantly exceeded (P less than 0.05) the inhibitory activity of the reagents tested alone or in other combinations. B[e]P alone or with S9 neither affected IFN induction nor was it capable of further enhancing chrysotiles inhibition of IFN synthesis. These findings provide further evidence of enhanced deleterious action by the combination of asbestos and activated B[a]P on a biological defense mechanism and further support the discriminatory power and credibility of the inhibition IFN induction assay for evaluating potential carcinogens.