Proteolytic detergent enzymes enhance the allergic antibody responses of guinea pigs to nonproteolytic detergent enzymes in a mixture: implications for occupational exposure.

A guinea pig intratracheal test was developed to assess the respiratory allergenicity of enzymes used in the detergent industry. Information gained from this test was used in a process for setting operational exposure guidelines to protect worker health. Mixtures of enzyme proteins were given to guinea pigs once per week for 10 weeks to determine whether there were interactions among enzymes that affected the induction of antibody responses to each enzyme in the mixture. Passive cutaneous anaphylaxis antibody titers against each enzyme were measured in sera. Mixtures of two or three enzymes always consisted of a protease (Alcalase, Savinase; Novo Industri A/S) with an alpha-amylase (Termamyl; Novo Industri A/S), a lipase (Lipolase; Novo Industri A/S), or both. Control animals were exposed to single enzymes. The antibody titers to Termamyl and Lipolase were significantly greater in animals dosed with the protease-containing mixtures as compared with control animals dosed with a single enzyme. Antibody titers to the protease were unchanged in the presence of additional enzymes in the mixture. Complete inactivation of protease activity abrogated the enhanced antibody response to Lipolase. Inhalation exposure of guinea pigs to a mixture of Alcalase and Lipolase also resulted in higher antibody titers to Lipolase as compared with animals exposed by inhalation to Lipolase alone, showing that the enhanced response was not due to intratracheal delivery of antigen to the respiratory tract. These results show that proteolytic enzymes in a mixture enhance antibody responses to other enzymes. This should be considered when defining exposure guidelines for protease-containing enzyme mixtures.

Antigenic and allergenic analysis of psyllium seed components.

The outer portions (husk) of psyllium seeds are a concentrated source of natural fiber used in some bulk-fiber laxatives and cereals. They are known to elicit respiratory allergic reactions after inhalation or ingestion among sensitized individuals. Antigenic and allergenic characterization of three psyllium-seed fractions (husk, endosperm, and embryo) was conducted with crossed immunoelectrophoresis (CIE), crossed radioimmunoelectrophoresis, and sodium dodecyl sulfate-polyacrylamide gel electrophoresis to determine the source of psyllium allergenicity. Homologous CIE demonstrated psyllium endosperm and embryo extracts contained seven and four antigens, respectively. Husk extracts were too gelatinous to react by CIE. However, heterologous CIE profiles of endosperm or embryo extracts, reacted with antihusk antibodies, resulted in antigen-antibody precipitin peaks that matched the heavy staining precipitin lines of homologous reactions for endosperm and embryo, respectively. These results indicated that commercial-grade husk, endosperm, and embryo contained similar antigens. Extracts of all three seed components contained antigens that bound IgE antibodies in the sera of 11 psyllium RAST-positive individuals, as determined by crossed radioimmunoelectrophoresis. The few prominent husk protein/peptide bands resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis were common in either embryo or endosperm. Immunoblots revealed common IgE reactive bands in all three seed fractions. Microscopic examination of the powdered commercial-grade psyllium (95% pure) revealed it contained endosperm and embryo particles. These immunologic, biochemical, and microscopic findings suggest that other contaminating seed components are primarily responsible for the allergenicity of commercial-grade psyllium-husk powder rather than the husk itself.

Lack of DNA-strand breaks in rat testicular cells after in vivo treatment with sodium fluoride.

Oral administration of up to 84 mg/kg of NaF to adult male rats did not induce DNA-strand breaks in testicular cells when measured by alkaline elution. Although plasma fluoride levels were as high as 12 ppm is rats given 84 mg/kg of NaF, testicular fluoride levels in most cases were only 10-20% of plasma levels. Fluoride did not accumulate in the testes after 5 daily treatments. Therefore, it is unlikely that NaF, even at high doses, poses a hazard with respect to heritable genetic effects.

Validation of an in vivo alkaline elution assay to detect DNA damage in rat testicular cells.

An alkaline elution assay was used to measure DNA damage in the rat testis after in vivo treatment with chemicals. All of the chemicals reported to induce heritable mutations in a mammalian assay (mouse specific locus test) were positive in the rat alkaline elution assay. Chemicals that are negative or inconclusive in the specific locus test did not cause detectable DNA damage in rat testes. DNA damage was detected by alkaline elution after either intraperitoneal or oral administration of chemical mutagens. Data from these validation studies were used to establish criteria to be used for evaluation of alkaline elution results with materials of unknown potential for genotoxic effects in germinal tissue.

Alkaline elution of rat testicular DNA: detection of DNA cross-links after in vivo treatment with chemical mutagens.

The alkaline elution technique was used to measure DNA damage in the rat testis after intraperitoneal injection of 3 chemicals known to cause heritable mutations in rodents. These 3 chemicals are triethylenemelamine (TEM), mitomycin C, and cyclophosphamide. All three of these chemicals produced DNA damage which was readily detectable by alkaline elution. Both TEM and mitomycin C produced DNA interstrand cross-links, although TEM was a more potent cross-linker on an equimolar basis than mitomycin C. Cyclophosphamide produced both DNA cross-links and DNA strand breaks. Alkaline elution in the absence of proteinase K indicated that some of the strand breaks appeared to be closely associated with protein. These studied indicate that the alkaline elution technique is capable of detecting DNA damage in mammalian germ cells produced by chemical mutagens. This technique may prove useful as a screening tool for identifying chemicals which cause heritable mutations in mammals.

Alkaline elution of rat testicular DNA: detection of DNA strand breaks after in vivo treatment with chemical mutagens.

The alkaline elution technique was used to measure DNA strand breaks in rat testes after intraperitoneal injection of several chemicals known to cause heritable mutations in rodents. Methyl methanesulfonate (MMS), ethyl methanesulfonate, methylnitrosourea, and ethylnitrosourea all produced single strand breaks in rat testicular DNA. For both of these pairs of homologous alkylating agents the relative potency was methyl analog greater than ethyl analog. Strand breaks produced by MMS appeared rapidly (within 2 h) in rat testicular DNA and were partially repaired within 24 h. Studies with low doses of MMS indicate that the assay has the sensitivity to detect DNA strand breaks in the testis after a dose of only 5 mg/kg. Variability in DNA elution profiles for individual control animals and for individual animals given identical doses of MMS was small. In contrast to the results with known mutagens, intraperitoneal injection of nonmutagens such as dimethyl sulfoxide, phenol, and Triton X-15, did not produce strand breaks in testicular DNA. These data indicate that this assay detects DNA strand breaks in the rat testis. The results for several heritable mutagens and nonmutagens are qualitatively predictive of mutagenic activity in the testis.