The genetic control of chemically and radiation-induced skin tumorigenesis: a study with carcinogenesis-susceptible and carcinogenesis-resistant mice.

Outbred carcinogenesis-resistant (Car-R) and carcinogenesis-susceptible (Car-S) mouse lines were generated by phenotypic selection for resistance or susceptibility to two-stage skin carcinogenesis. These two Car mouse lines differ by >100-fold in susceptibility. In the present study, we tested the hypothesis that a subset of genetic loci responsible for susceptibility or resistance to chemical skin tumorigenesis may also be involved in radiation-induced skin tumorigenesis.

Analysis of c-Ha-ras gene mutations in skin tumors induced in carcinogenesis-susceptible and carcinogenesis-resistant mice by different two-stage protocols or tumor promoter alone.

In the present study we describe the molecular analysis of c-Ha-ras gene mutations in 47 papillomas and 17 carcinomas developed in two lines of mice, carcinogenesis-susceptible (Car-S) and carcinogenesis-resistant (Car-R), selectively bred for extreme susceptibility or resistance to chemical skin carcinogenesis initiated and promoted with different doses of 7,12-dimethylbenz[a]anthracene (DMBA) and 12-O-tetradecanoylphorbol-13-acetate (TPA). This study also presents the analysis of c-Ha-ras gene mutations in 22 papillomas and 22 carcinomas in Car-S mice initiated with DMBA and promoted with benzoyl peroxide (BzPo) and in seven papillomas and one carcinoma from a group of uniniated Car-S mice that received only BzPo treatment. The data showed that a A(182)-->T transversion in the c-Ha-ras gene was present in 100% and 81% of the skin tumors developed in Car-S and Car-R mice, respectively, after DMBA initiation and TPA promotion, suggesting that differences in genetic susceptibility can influence the frequency of c-Ha-ras mutations in the skin tumors produced.

Genetics of chemical carcinogenesis: analysis of bidirectional selective breeding inducing maximal resistance or maximal susceptibility to 2-stage skin tumorigenesis in the mouse.

We report on bidirectional selective breeding, initiated from a genetically defined foundation population and carried out to selection limit, for producing lines of mice endowed with maximal resistance (Car-R) or maximal susceptibility (Car-S) to 2-stage skin tumorigenesis. The initial population resulted from a balanced intercrossing of 8 inbred strains of mice. The tumors, induced by a single application of DMBA (initiation) and twice weekly applications of TPA (promotion), were benign papillomas; their number at the end of the promotion period was the phenotype chosen for assortative mating.

Skin tumorigenesis by initiators and promoters of different chemical structures in lines of mice selectively bred for resistance (Car-r) or susceptibility (Car-s) to two-stage skin carcinogenesis.

Carcinogenesis-resistant (Car-R) and carcinogenesis-susceptible (Car-S) mice were obtained applying a bi-directional selective breeding approach to a two-stage skin carcinogenesis protocol, using 9,10-dimethyl-1,2-benzanthracene (DMBA) as initiator and 12-O-tetradecanoylphorbol-13-acetate (TPA) as promoter. Sixteen generations of selection produced a remarkable interline difference in responsiveness to two-stage skin carcinogenesis between Car-R and Car-S: identical DMBA (25 microgram) and TPA (5 microgram) doses induced papillomas in 100% of Car-S compared with 3.3% of Car-R mice and maximal responses of 14.

Low antibody responsiveness is found to be associated with resistance to chemical skin tumorigenesis in several lines of Biozzi mice.

High and low antibody responder lines of mice from Selections I, III and G were assayed for two-step skin tumorigenesis using a protocol consisting in initiation with 7,12-dimethylbenz[a]anthracene (DMBA) and promotion with 12-O-tetradecanoylphorbol-13-acetate (TPA). Concordant results were obtained in the three selections: low antibody responder mice were shown to be significantly more resistant to tumor induction than the high responder counterparts. The difference was observed for all parameters: kinetics and percentages of tumor incidence and tumor multiplicity.

Effect of genetic modification of acute inflammatory responsiveness on tumorigenesis in the mouse.

Two distinct bidirectional selective breedings for quantitative traits were initiated from identical genetically heterogeneous mouse populations. The resulting lines are characterized by maximal or minimal acute inflammatory responsiveness (AIR): AIRmax and AIRmin lines, respectively, and by resistance or susceptibility to chemical skin tumorigenesis: Car-R and Car-S lines, respectively. The AIR response to s.

Genetic control of immune responsiveness, aging and tumor incidence.

Age-related alterations of the immune system affect both antibody and cell-mediated immune responses, T-cell responses being more severely affected than B-cell responses. Within the T-cell population, aging leads to replacement of virgin by memory cells and to accumulation of cells with signal transduction defects. Changes in T-cell subsets and in cytokine production profiles may produce suitable conditions for T-cell-mediated disregulation of antibody responses characterized by the production of low affinity and self-reactive antibodies.

Genetics of chemical carcinogenesis--III. Tissue-specificity of the genes controlling susceptibility and resistance to skin carcinogenesis in the mouse.

Carcinogenesis-resistant (Car-R) and carcinogenesis-susceptible (Car-S) mice have been obtained by the method of bi-directional selective breeding. After 10 generations of selection Car-R and Car-S mice show a remarkable difference in their response to chemical carcinogenesis. Car-R and Car-S mice, initiated and promoted by skin application of 9,10-dimethyl-1,2-benzanthracene (DMBA) and 12-O-tetradecanoylphorbol-13-acetate (TPA) reach a tumour multiplicity of 0.

Genetics of chemical carcinogenesis--II. Papilloma induction and malignant conversion in susceptible (Car-s) and resistant (Car-R) lines of mice produced by bidirectional selective breeding and in their (Car-S X Car-R) F1 hybrids.

Susceptible (Car-S) and resistant (Car-R) lines of mice separated by 10 consecutive generations of bidirectional selective breeding present a very large difference in responsiveness to two-stage skin carcinogenesis. Car-S mice initiated with 0.5 micrograms 9,10-dimethyl-1,2-benzanthracene (DMBA) and promoted with 0.

Comparison of 7,12-dimethylbenz(a)anthracene-DNA adduction in the epidermis of two lines of mice selected for resistance (CAR-R) or susceptibility (CAR-S) to skin carcinogenesis.

Two lines of mice were produced by bidirectional selective breeding: one resistant (CAR-R) and one susceptible (CAR-S) to two-stage skin carcinogenesis by dimethylbenz(a)anthracene and 12-O-tetradecanoyl-phorbol-13-acetate. The dimethylbenz(a)anthracene-DNA adduct formation was compared in the two lines by a postlabeling procedure so as to determine whether the striking interline difference observed as to tumor incidence could (in part) be due to differences in the formation of DNA-reactive metabolites. Results show that qualitatively, adduct profiles in CAR-R and CAR-S epidermis are similar.

Genetics of chemical carcinogenesis. 1. Bidirectional selective breeding of susceptible and resistant lines of mice to two-stage skin carcinogenesis.

Six generations of a bidirectional selective breeding model for producing lines of mice susceptible (Car-S) and resistant (Car-R) to two-stage skin carcinogenesis are described. Initiation was with 9,10-dimethyl-1,2-benzanthracene (DMBA single application), and promotion with 12-O-tetradecanoyl-phorbol-13-acetate (TPA twice weekly). The selective breeding was initiated with a highly genetically polymorph foundation population, produced by the intercrossing of eight inbred mouse strains.

Genetics of acute inflammation: inflammatory reactions in inbred lines of mice and in their interline crosses.

Acute inflammation is induced by the subcutaneous injection of swollen polyacrylamide microbeads, its intensity measured by the cell and protein concentration of the local exudates. A large and continuous range of responses is obtained in different inbred strains of mice, which suggests a polygenic control of the inflammatory response. The variable levels of the global dominance observed in F1 hybrids issued from several parental combinations indicated that the pattern of alleles controlling high or low response was different in each parental strain.

Inheritance of immune responsiveness, life span, and disease incidence in interline crosses of mice selected for high or low multispecific antibody production.

High (H) and low (L) antibody responder lines of mice separated by selective breeding present a maximal interline difference in antibody (Ab) response to Ag of different specificities (general genetic regulation). The analysis of SRBC agglutinin response in H line, L line, F1 hybrids, F2, and backcross segregants demonstrates that Ab responsiveness is a polygenic trait regulated by the additive interaction of 5 to 7 independent loci, with an incomplete dominance (44% +/- 7%) of the high response character, and a 30% +/- 10% impact of the environmental factors. The life span of H, L, F1, F2, and backcross populations is correlated positively with 2-ME-resistant agglutinin response (r = 0.

Polygenic control of quantitative antibody responsiveness: restrictions of the multispecific effect related to the selection antigen.

Among the differences observed between the various high (H) and low (L) antibody responder lines of mice resulting from distinct bidirectional selective breedings, one of the most puzzling is the variation in the "multispecific effect," i.e., in the modification of antibody responses to antigens unrelated to those used during the selection.

Genetic regulation of the specific and non-specific component of immunity.

Bi-directional selective breeding for antibody (Ab) responsiveness to heterologous erythrocytes (Selection I) produced a high (H) and a low (L) responder line of mice which were also remarkably separated for Ab responses to many unrelated natural antigens (Ags) such as heterologous proteins, viruses, bacteria, parasites and haptens carried by these immunogens. The character "quantitative Ab responsiveness" is controlled by several independently segregating loci (polygenic regulation). The major genetic modification is produced at the level of macrophage activities.

Effect of silica on the genetic regulation of antibody responsiveness.

The high (H) and low (L) antibody responder lines of mice produced by selective breeding are characterized by different modifications in immunocompetent cell potentialities, according to the immunization procedure used for the selection process. In selections I and II, the difference in antibody responsiveness between H and L lines was clearly shown to depend mainly on macrophage function: the more rapid catabolism of antigens in L mice was the main cause of the low antibody production. In contrast, up to now, no difference has been observed between H and L mice of selections III and IV in terms of the macrophage accessory role.

Genetics of antibody responsiveness to bovine serum albumin and rabbit gamma-globulin. II. Evidence for a partially common genetic regulation of response to bovine serum albumin and rabbit gamma-globulin.

In order to measure the reciprocal nonspecific effect of the genetic regulation of antibody responsiveness to bovine serum albumin (BSA) and rabbit gamma-globulin (RGG), two independent bidirectional selective breedings for responses to these two antigens were carried out: selection V/BSA and selection V/RGG respectively. The total interline separation at selection limit (RT) was 5.3 log2 for selection V/BSA and 2.

Genetics of antibody responsiveness to bovine serum albumin and rabbit gamma-globulin. I. Genetic analysis of high and low responder lines of mice produced by selective breeding.

The selective breeding for antibody production against bovine serum albumin (BSA) and rabbit gamma-globulin (RGG) induced a large modification in responsiveness in the high (Hv) and low (Lv) responder lines at selection limit. The total response to selection (RT) was 9.0 log2 for BSA and 8.

Potentialities of immunocompetent cells in high and low antibody-producing lines of mice obtained by selective breedings for responsiveness to flagellar or somatic antigens of Salmonellae.

The genetic modifications of immunocompetent cell functions were investigated in high (H) and low (L) antibody responder lines of mice obtained by selective breeding for responsiveness to flagellar and somatic antigens of Salmonellae (Selection III and Selection IV, respectively). Several lines of evidence converge to demonstrate that the differences in antibody responses between the H and L lines of the two selections are not due to the modification of antigen handling by macrophages. This contrasts with previous observations that macrophages play a major role in interline differences in Selections I and II.

Effect of genetic modification of antibody responsiveness on resistance to Toxoplasma gondii infection.

Resistance to Toxoplasma gondii infection was studied in the high (H/f) and low (L/f) antibody responder lines of mice that were selected on the basis of quantitative antibody responsiveness to the flagellar antigen of Salmonella (selection III). No interline difference was observed in resistance to a highly virulent strain of T. gondii.

Regulatory function of Thy-1-negative cells: V. A lymphokine of B cell origin (BEF) induces in vitro high antibody response in genetically selected low responder mice.

Studies were conducted on two lines of mice genetically selected, respectively, for high (AB/H) and low (AB/L) antibody production, in order to identify the mechanism by which genes involved in the selection express their functions. It was found that B cell-derived enhancing factor (BEF), a lymphokine of B cell origin which acts on T cells by preventing the activation of suppressor cells, is effective in inducing high responses in low responder mice, whereas it is ineffective in modulating antibody production in high responder mice. As a result, no difference was found between the responses of AB/H and AB/L mice when spleen cells were stimulated in vitro in the presence of BEF.

Basal immunoglobulin serum concentration and isotype distribution in relation to the polygenic control of antibody responsiveness in mice.

Serum Ig concentration and isotype distribution were determined in the high (H) and low (L) responder lines selected for antibody response to complex immunogens. Data were recorded in normal and postimmunization sera from the H and L lines produced by five independent selective breedings (selections I, II, III, IV, and V). Ig levels were much higher in H than in L mice of all the selections.

Independent polygenic regulation of quantitative antibody responsiveness and expression of delayed-type hypersensitivity (DTH).

The intensity of delayed-type hypersensitivity (DTH) expression measured by footpad swelling was established in high and low antibody responder lines of mice produced by bidirectional selective breeding for antibody responsiveness to different antigens. These lines of mice presented a very large difference in antibody response to the antigens used in each selective breeding (selection Ags) and to several other unrelated Ags (nonspecific effect). The intensity of DTH reactivity to selection Ags and to unrelated Ags differed in the various lines investigated, but the intensity of DTH reactions was not correlated with antibody responsiveness.