Determination of low tetanus or diphtheria antitoxin titers in sera by a toxin neutralization assay and a modified toxin-binding inhibition test.

A method for the screening of tetanus and diphtheria antibodies in serum using anatoxin (inactivated toxin) instead of toxin was developed as an alternative to the in vivo toxin neutralization assay based on the toxin-binding inhibition test (TOBI test). In this study, the serum titers (values between 1.0 and 19.5 IU) measured by a modified TOBI test (Modi-TOBI test) and toxin neutralization assays were correlated (P < 0.0001). Titers of tetanus or diphtheria antibodies were evaluated in serum samples from guinea pigs immunized with tetanus toxoid, diphtheria-tetanus or triple vaccine. For the Modi-TOBI test, after blocking the microtiter plates, standard tetanus or diphtheria antitoxin and different concentrations of guinea pig sera were incubated with the respective anatoxin. Twelve hours later, these samples were transferred to a plate previously coated with tetanus or diphtheria antitoxin to bind the remaining anatoxin. The anatoxin was then detected using a peroxidase-labeled tetanus or diphtheria antitoxin. Serum titers were calculated using a linear regression plot of the results for the corresponding standard antitoxin. For the toxin neutralization assay, L+/10/50 doses of either toxin combined with different concentrations of serum samples were inoculated into mice for anti-tetanus detection, or in guinea pigs for anti-diphtheria detection. Both assays were suitable for determining wide ranges of antitoxin levels. The linear regression plots showed high correlation coefficients for tetanus (r(2) = 0.95, P < 0.0001) and for diphtheria (r(2) = 0.93, P < 0.0001) between the in vitro and the in vivo assays. The standardized method is appropriate for evaluating titers of neutralizing antibodies, thus permitting the in vitro control of serum antitoxin levels.

Determination of low tetanus or diphtheria antitoxin titers in sera by a toxin neutralization assay and a modified toxin-binding inhibition test

A method for the screening of tetanus and diphtheria antibodies in serum using anatoxin (inactivated toxin) instead of toxin was developed as an alternative to the in vivo toxin neutralization assay based on the toxin-binding inhibition test (TOBI test). In this study, the serum titers (values between 1.0 and 19.5 IU) measured by a modified TOBI test (Modi-TOBI test) and toxin neutralization assays were correlated (P < 0.0001). Titers of tetanus or diphtheria antibodies were evaluated in serum samples from guinea pigs immunized with tetanus toxoid, diphtheria-tetanus or triple vaccine. For the Modi-TOBI test, after blocking the microtiter plates, standard tetanus or diphtheria antitoxin and different concentrations of guinea pig sera were incubated with the respective anatoxin. Twelve hours later, these samples were transferred to a plate previously coated with tetanus or diphtheria antitoxin to bind the remaining anatoxin. The anatoxin was then detected using a peroxidase-labeled tetanus or diphtheria antitoxin. Serum titers were calculated using a linear regression plot of the results for the corresponding standard antitoxin. For the toxin neutralization assay, L+/10/50 doses of either toxin combined with different concentrations of serum samples were inoculated into mice for anti-tetanus detection, or in guinea pigs for anti-diphtheria detection. Both assays were suitable for determining wide ranges of antitoxin levels. The linear regression plots showed high correlation coefficients for tetanus (r² = 0.95, P < 0.0001) and for diphtheria (r² = 0.93, P < 0.0001) between the in vitro and the in vivo assays. The standardized method is appropriate for evaluating titers of neutralizing antibodies, thus permitting the in vitro control of serum antitoxin levels.

Induction of FOS and JUN proteins by adrenocorticotropin and phorbol ester but not by 3',5'-cyclic adenosine monophosphate derivatives.

We report the results of an extensive kinetic analysis of the effects of ACTH, cAMP derivatives (dibutyryl cAMP and 8-bromo-cAMP) and phorbol ester (phorbol-12-myristate-13-acetate) on the expression of fos and jun gene family members at the mRNA (Northern hybridization) and protein levels (immunoprecipitation and indirect immunofluorescence) in the mouse Y-1 adrenocortical cell line. FOS and JUN proteins are induced by ACTH independently of cell cycle stage. c-Fos, fos-B, fra-1, fra-2, c-jun, and jun-B genes are induced by ACTH, the kinetic profiles for mRNAs and respective protein products being similar, except for a 1-h protein delay. Jun-D mRNA is an exception, being constitutively expressed. However, JUN D protein is induced by ACTH. phorbol-12-myristate-13-acetate closely mimics these inductive effects of ACTH. On the other hand, cAMP derivatives are not effective in inducing the fos and jun genes, except for fra-2 mRNA, JUN D protein, and to some extent JUN B protein. Clearly, ACTH is endowed with the versatile capability of modulating fos and jun gene expression, suggesting that AP-1 transcription factors play a role in ACTH mechanisms of action. ACTH receptors are likely to activate signaling routes other than the classical cAMP/protein kinase A in order to induce FOS and JUN proteins.

Imbalanced expression of cellular nuclear oncogenes caused by v-sis/PDGF-2.

Two murine cell lines that overexpress v-sis/PDGF-2 were used to study the mechanism of cell transformation by SSV (simian sarcoma virus). In contrast to the parental cells that are phenotypically normal and serum-dependent for growth, v-sis-overexpressing cells grow in PDGF-free plasma medium, are unable to enter the G0 state and are highly tumorigenic. Analysis of the expression of some growth factor-induced early response genes in v-sis-overexpressing cells revealed: (a) high and constitutive c-myc mRNA levels in SSV-NRK cells; (b) unaltered levels of fra-1, fos B, jun B and krox 20 transcripts; (c) high and constitutive FOS staining due to c-FOS and FOS-related protein(s); (d) constitutive c-JUN and higher JUN D expression. These results are compatible with a model in which endogenous production of v-sis/PDGF-2 leads to deregulated expression of key cellular transregulators that, in turn, alter the cells' transcriptional program leading to the transformed state and malignancy.