Modulation by lipoproteins of amphotericin B-induced immunostimulation

Previous reports indicate that amphotericin B (AmB) and amphotericin methyl ester (AME) are potent adjuvants and polyclonal B-cell activators, and that most mouse strains can be classified as high or low responders to AmB and AME. In the present study, an inbred strain with very high plasma cholesterol concentration (HC strain) proved to be a low responder. Responses of HC mice to other immune stimuli were normal, suggesting that HC lymphoid cells expressed selectively weak responses to AmB and AME. Plasma levels of low-density lipoproteins (LDL), very-low-density lipoproteins (VLDL), and high-density lipoprotein subfraction (HDL2) were very much higher in HC mice than in AKR mice, an AmB-high responder strain. Low responses in vitro to AME were observed with lymphoid cells from HC mice and from AKR----HC bone marrow chimeras, i.e., AmB-high responder strain lymphocytes from a low responder host. However, enhanced AME responses were induced by a 2- or 48-hr preincubation of splenocytes from either HC or AKR mice in medium containing lipoprotein-depleted fetal calf serum. Taken together these studies indicate that plasma lipoproteins can inhibit lymphocyte responses to AME; this seems to account for the low AmB and AME responses of the HC strain. The mechanism of this lipoprotein-induced inhibition remains obscure, but it cannot be accounted for by competitive binding of AmB by lipoproteins.     

Genetic control of immune responses to the 18-kDa protein of Mycobacterium leprae. Different TH1 subsets may be involved in proliferative and delayed-type hypersensitivity responses.

In vitro and in vivo responses to the 18-kDa protein of Mycobacterium leprae have been analysed in different strains of mice. Lymphocytes from BALB/cJ (H-2d), BALB.B (H-2b), B10.BR (H-2k), and B10.M (H-2f) mice primed with 18-kDa protein yielded high T cell proliferative responses, while those from C57BL/10J (H-2b) mice yielded lower responses. Both H-2 and non-H-2 genes contributed to the magnitude of responsiveness. F1 mice from high and low responder strains showed high responsiveness to the 18-kDa protein. Supernatants from lymph node cell cultures prepared from 18-kDa protein-immunised BALB/cJ, B10.BR, and C57BL/10J mice contained IL-2 but no IL-4, indicating that activated T cells from both high and low responder mice were of a TH1 phenotype. Cell cultures from low responder C57BL/10J mice produced less IL-2 than those from high responders. The low responsiveness to the 18-kDa protein in proliferative assays might be due to a low frequency of antigen-specific T cells in the C57BL/10J mouse strain. BALB/cJ, C57BL/10J, and F1 (BALB/cJ x B10.BR) mouse strains were tested for in vivo DTH reactions to the 18-kDa protein. All strains, including C57BL/10J, were high DTH responders. Although DTH effector cells and 18-kDa protein-specific proliferative T cells belong to the TH1 subset, our data comparing high and low responder status indicate that distinct TH1 subpopulations are stimulated in response to the 18-kDa protein of M. leprae.     

Immunity to leprosy. II. Genetic control of murine T cell proliferative responses to Mycobacterium leprae

T cell proliferative responses to Mycobacterium leprae were measured after immunization of mice at the base of the tail with antigen and challenging lymphocytes from draining lymph nodes in culture with M. leprae. This T cell response to M. leprae has been compared in 18 inbred strains of mice. C57BL/10J mice were identified as low responder mice. The congenic strains B10.M and B10.Q were found to be high responders, whereas B10.BR and B10.P were low responders. F1 (B10.M X C57BL/10J) and F1 (B10.Q X C57BL/10J) hybrid mice were found to be low responders, similar to the C57BL/10J parent, indicating that the low responsive trait is dominant. Whereas B10.BR mice were shown to be low responders to M. leprae, B10.AKM and B10.A(2R) were clearly high responders, indicating that the H-2D region influences the magnitude of the T cell proliferative response. Gene complementation within the H-2 region was evident. Genes outside the H-2 region were also shown to influence the response to M. leprae. C3H/HeN were shown to be high responder mice, whereas other H-2k strains, BALB.K, CBA/N, and B10.BR, were low responders. Gene loci that influence the T cell proliferation assay have been discussed and were compared to known background genes which may be important for the growth of intracellular parasites. Because mycobacteria are intracellular parasites for antigen-presenting cells, genes that affect bacterial growth in these cells will also influence subsequent immune responses of the host.     

Genes of the H-2 complex regulate the antibody response to murine leukemia virus

The influence of the major histocompatibility complex of the mouse (H-2 complex) on the antibody response against murine leukemia virus (MuLV) was investigated after 3 different ways of virus presentation (milk transmission of virus, spontaneous virus activation, and immunization with inactivated virus). The antibody response against MuLV was measured in the sera of H-2 congenic C57BL V+ sublines (V+ denotes positive for milk-transmitted MuLV), (B10.AV+ X C57BL)F1 mice, (C57BL X AKR)F1 mice and of C57BL animals after immunization with inactivated AKR virus. The pattern of immune responsiveness of the different C57BL strains to MuLV was independent of virus replication and was similar for the 3 ways of virus presentation. Serum antibody levels were controlled by 2 genes within the H-2 complex. The first gene (Ir-MuLV-1) was located in the I-A region and was complemented by a second gene (Ir-MuLV-2), which was situated in the regions to the right of the I-B region. Presence of 2 responder alleles (Ir-MuLV-1+,2+) led to an optimal antibody response (H-2b haplotype). Animals that only expressed a responder allele in the I-A region (Ir-MuLV-1+,2-) were intermediate responders. Animals lacking a responder allele in the I-A region (Ir-MuLV-1-,2+ or Ir-MuLV-1-,2-) were low responders.     

Comparison of immune responses to diphtheria and tetanus toxoids of various mouse strains

Immune responses of 11 mouse strains with known genetical characteristics and two outbred strains to diphtheria and to tetanus toxoids were compared. Both diphtheria and tetanus antitoxins were titrated by passive hemagglutination. From the pattern of the immune response, the mouse strains tested may be classified into four groups. [1] Strains ddY (SPF) and ddY (conv) and those with haplotype H-2b, such as C57BL/6 and C57BL/10, were high responders to both toxoids. [2] Strains with H-2d, such as BALB/c, B10.D2 and DBA/2Cr, were intermediate responders to both toxoids. [3] Strains with H-2k, H-2a or, H-2m, such as C3H/He, B10.BR, B10.BR/SgSn, B10.A/SgSnJ and B10.AKM/O1a, were high responders to diphtheria toxoid but low responders to tetanus toxoid. [4] The strain with H-2h4, B10.A (4R), was a poor responder to both toxoids.     

Genetic control of murine T cell proliferative responses to Mycobacterium leprae. V. Evidence for cross-reactivity between host antigens and Mycobacterium leprae

T cell proliferative responses to Mycobacterium leprae were measured by immunization of mice at the base of the tail with Ag and challenging lymphocytes from draining lymph nodes in culture with M. leprae. C57BL/10J and B10.BR mice were identified as low responder mice and the congenic strains B10.M, B10.Q, and B10.AKM as high responders whereas F1 (high x low) hybrid mice were found to be low responders. The cellular basis of low responsiveness did not appear to result from a defect in Ag-presenting cells or the activation of suppressor T cells by M. leprae. The influence of the environment in which T cells developed on responsiveness to M. leprae was analyzed in chimeric mice prepared by irradiating F1(C57BL/10J x B10.M) mice and reconstituting with bone marrow from C57BL/10J, B10.M, or F1 donors. Six weeks later, chimeric mice were immunized with M. leprae, lymph node cells were subsequently prepared, and H-2 phenotyped and challenged in culture with M. leprae Ag. T cell proliferative responses were found to be low in all cases, similar to those observed using lymph node cells from F1 hybrid mice. These results suggested that high responder B10.M lymphocytes developing in the irradiated F1 mice became tolerized to antigenic determinants found on M. leprae. This implied cross-reactive epitopes existed between some mouse strains and M. leprae. Low responsiveness to M. leprae in low responder and F1 hybrid mice may result from tolerance to H-2-encoded Ag that show cross-reactivity with M. leprae.     

Serum antibody and cellular immune response in mice to dextran B512.

Serum antibodies to dextran started to appear 3 days after immunization of C57BL/6 mice. Synthesis of IgM antibodies was followed by IgG3 and IgGA. Other immunoglobulin classes (IgG1, IgG2b, and IgG2a) were very low or absent. The immune response to dextran was also thymus independent with regard to IgG3 and IgA synthesis as demonstrated by the use of nu/nu mice. CBA and C57BL/6 mice were high responders to dextran with regard to IgM synthesis. C57BL/6 mice produced high levels of IgG3 and IgA antibodies, whereas CBA, A/J, and A.TL only synthesized IgM antibodies. A/J and A.TL strains were most frequently low responders with regard to IgM synthesis and CBA/N mice were completely nonresponders with regard to all immunoglobulin classes. The ability to produce anti-dextran antibodies increased with age in high responder strains. This was most pronounced for IgG3 and IgA antibodies, which reached adult levels 3 months after birth. The affinity of anti-dextran antibodies was high and homogeneous in antisera from C57BL/6 mice. Preimmune matural antibodies and antibodies from immunized low responder strains had a low and variable affinity for dextran.     

Murine responses to (Tyr-Glu-Ala-Gly)n: II. H-2 and non-H-2 gene effects

Mice of the H-2^b haplotype responded to the sequential polymer poly(Tyr-Glu-Ala-Gly) in the in vitro T-cell proliferative assay, irrespective of whether they were homozygous or heterozygous at the H-2^b locus. The antibody responses of the H-2^b congenic mice to this polymer were variable, with A.BY and BALB.B showing responses better than those of C57BL/6 and C57BL/10 strains. The antibody responses of the F₁ progeny of (responder × nonresponder) strains of mice to this polymer are generally lower than the responder parents. F₁ mice with C57BL/10 background were the poorest responders. Studies with F₂ mice and backcross progenies of selective breeding of high and low antibody responder (C57BL/6 × BALB/c) F₁ to high responder C57BL/6 mice indicated that both non-H-2 genes and H-2 gene dosage effects influenced the magnitude of the humoral antibody responses. Animals having low responder non-H-2 background and only half the dosage of the responder immune response genes has greatly diminished antibody responses.     

Genetics of the anti-dextran B512 and the autoanti-idiotypic response: codominant expression in F1 hybrids and dichotomy of response and allotype-linked idiotype

The IgM plaque-forming response to the alpha 1-6 epitope of dextran B512 is linked to the Ig-1 heavy chain allotypes j and b characteristic of CBA and C57BL strains, respectively, and the response typically induces the formation of autoanti-idiotypic antibodies that can distinguish between anti-dextran antibodies of CBA and C57BL origin. Nevertheless, some substrains of Balb/c mice (allotype a) and some Bailey recombinant stains give a PFC response although they do not possess allotypes j or b. The anti-dextran antibodies in these strains lack the idiotypes characteristic of either CBA and C57BL antibodies to dextran, but they possess their own particular idiotype. F1 hybrids between two responder strains possessing different idiotypes on their antibodies against dextran, produce both idiotypes and two different autoanti-idiotypic antibodies. CBA(Ig-1b) mice were high responders to dextran and possessed the idiotype of C57BL, whereas C57BL/6(Ig-1a) mice were low responders. The V(H) recombinant strains BAB.14 and CB-8KN that possess the Ig-1b allotype of C57BL, but have some of the V(H) genes from Balb/c and the rest from C57BL/6 were high responders to dextran, but did not possess the C57BL idiotype, suggesting that the genes determining the response against dextran and the idiotype may have different locations in the heavy chain locus.     

Differences in antibody production against mouse hepatitis virus (MHV) among mouse strains

Several strains of mice were examined for antibody production after intranasal inoculation with a low virulence strain of mouse hepatitis virus (MHV), MHV-NuU. C57BL/6N mice were shown to be high responders in the production of complement fixing (CF) antibody as compared to C3H/HeN, BALB/c-AnN, DBA/2N mice. F1 hybrids B6C3 and BDF1 from C57BL/6N mice, showed CF antibody responses as high as C57BL/6N, suggesting that high responsiveness is genetically controlled. All these mouse strains were able to produce high titred neutralizing antibody to MHV.     

The response of recombinant inbred strains of mice to bacterial lipopolysaccharides.

Fourteen recombinant inbred strains of mice have been produced by the inbreeding of the F2 generation of a cross between C57BL/6J and C3H/HeJ progenitor mice. The responses of these BXH strains to bacterial lipopolysaccharides (LPS) have been characterized. Four BXH strains are high LPS responders and nine strains are low LPS responders. One BXH strain shows intermediate responsiveness which may reflect residual heterozygosity. F1 hybrid mice from low x high responder strains were intermediate in their response to LPS suggesting additive genetic control. The LPS responses in backcross mice from the F1 x low LPS responders showed segregation consistent with LPS responsiveness being determined by a single gene. In 13/14 BXH strains, there was concordant inheritance of LPS responsiveness and the major urinary protein locus Mup-1b. The association of the expression of the Mup-1 alleles with LPS responsiveness in the BXH strains suggests that the defective LPS response gene in C3H/HeJ mice is located on chromosome 4.     

Salmonella-typhimurium-specific difference in rate of intracellular killing by resident peritoneal macrophages from salmonella-resistant CBA and salmonella-susceptible C57BL/10 mice

The aim of the present study was to determine whether the difference between the rate of intracellular killing of Salmonella typhimurium by macrophages of salmonella-resistant CBA and salmonella-susceptible C57BL/10 mice also holds for other salmonellae and other bacteria species. After in vivo phagocytosis, the initial rate of in vitro intracellular killing of S. typhimurium phagetype 505, S. typhimurium phagetype 510, and S. typhimurium M206 by macrophages of CBA mice amounted always to approximately 1.7 times the value found for macrophages of C57BL/10 mice (p less than 0.001), indicating that the difference in killing efficiency between CBA and C57BL/10 macrophages holds for various strains of S. typhimurium. However, some other salmonella species, i.e., S. dublin and S. heidelberg, as well as E. coli 054 and 02K1+, Listeria monocytogenes EGD and L347, and Staphylococcus aureus were killed equally efficiently by macrophages of both mouse strains. These findings indicate that the difference between the rates of intracellular killing by macrophages of salmonella-resistant CBA and salmonella-susceptible C57BL/10 does not hold for several other bacteria species and thus might be specific for S. typhimurium. Subsequent experiments showed that the in vivo proliferation of S. typhimurium 510 in the first 2 days after i.v. injection was 2.0-fold to 3.0-fold higher in the spleens and livers of C57BL/10 mice than in those of CBA mice, whereas the in vivo proliferation of S. dublin and S. heidelberg was between 1.0-fold to 1.4-fold higher in the C57BL/10 mice. These findings suggest that the differences between the rate of in vitro intracellular killing of salmonella by CBA and C57BL/10 macrophages are reflected in differences in the rate of in vivo proliferation of these microorganisms in CBA and C57BL/10 mice. To gain insight into the involvement of the oxidative metabolism of CBA and C57BL/10 macrophages in the difference in the rate of intracellular killing of S. typhimurium, the O2 consumption and H2O2 release by resident peritoneal macrophages was determined. The amplitudes of the respiratory burst and the release of H2O2 was identical in macrophages of the two mouse strains after triggering by either preopsonized heat-killed S. typhimurium or phorbol myristic acetate. These findings indicate that the mouse species-associated difference in the intracellular killing of S. typhimurium is not caused by a difference in the oxidative metabolism of CBA and C57BL/10 macrophages.     

The two-step leukocyte migration inhibition factor (LIF) assay. Its use in evaluation of cellular immune function in patients with immunodeficiency diseases.

Administration of interferon (IF) inducers to mice enhances the uptake of antibody-coated erythrocytes (EA) by peritoneal macrophages. To evaluate the role of induced IF in macrophage activation, serum IF titers and phagocytosis of EA by macrophages were determined in recombinant inbred (RI) mice inoculated with Newcastle disease virus (NDV). RI strains carry either a “high” or a “low” response allele for a gene that controls their IF titers induced by NDV. C × BH and C × BK strains, both high responders for IF induction, were also found to be high responders for enhancement of phagocytosis by NDV. Conversely, strains C × BD, C × BI and C × BJ, low responders for IF induction, were also shown to be low responders for phagocytosis of EA by macrophages. In contrast, phagocytosis of EA by macrophages from high responder C × BH mice and low responder C × BD mice was similarly enhanced by the administration of a lipopolysaccharide. When data from all NDV-inoculated mice were analysed, a significant correlation was obtained between serum IF titers and the percentage of macrophages that ingested four or more EA. The results are compatible with two main possibilities: (i) IF induced by NDV enhances phagocytosis of EA by macrophages; or (ii) a macrophage-activating factor different from IF is released together with IF in response to NDV and the activity of this factor correlates with serum IF titers.     

Association of Lps gene with natural resistance of mouse macrophages against Legionella pneumophila.

Peritoneal macrophages obtained from lipopolysaccharide (LPS)-low responder C3H/HeJ mice (J) permitted the intracellular growth of the bacterium in macrophages of (J x N) F1 progeny was between the parent strains, showing that the traits were co-dominantly expressed. Correlation between intracellular bacterial growth in macrophages and LPS response of spleen cells was examined. Negative correlation was found between the two factors in F2, (J x F1) backcross and (N x F1) backcross progeny. This result implies that Lps gene controls the innate resistance of murine macrophages against the bacteria. Although macrophages of A/J strain also permit intracellular growth of L. pneumophila, gene complementation analysis of A/J and C3H/HeJ mice made clear that the gene control in C3H/HeJ differs from that of A/J strain. Macrophages of C57BL/10ScN, which is LPS-low responder line obtained from C57BL/10, were also defective in controlling the bacterial growth when compared to C57BL/10 mice. We suggest that the Lps gene also controls the natural resistance of murine macrophages against L. pneumophila.     

Genetic control of eosinophilia in parasitic infections: Responses of mouse strains to treatment with cyclophosphamide and parasite antigen

, and 1988. Genetic control of eosinophilia in parasitic infections: responses of mouse strains to treatment with cyclophosphamide and parasite antigen. International Journal for Parasitology18:1077–1085. Strain-dependent variation in the capacity of inbred and congenic mice to mount an eosinophilia in response to inoculation with the antigens of Mesocestoides corti, Trichinella spiralis or with Limulus haemocyanin (LCH), following pretreatment with cyclophosphamide (CY), is described. SWR, NIH, BALB/c, C3H and SJL mice were eosinophil high responder strains whereas C57 BL/10 and CBA mice were eosinophil low responder strains. Congenic strains with the B10 background (B10.S, B10.G and B10.BR) were all low eosinophil responders, although B10.G mice showed a level of response consistently above the other B10 congenic strains. Some of the gene(s) for high responsiveness appeared to be dominant, because F(In1)hybrids between high and low eosinophil response parental strains were intermediate to high responders. The strain-dependent pattern of eosinophil responsiveness to LHC or to M. corti and T. spiralis antigens, following CY pretreatment, was similar to that obtained previously following infection with either M. corti or T. spiralis, suggesting that heterogeneity in capacity to produce eosinophils operates independently of the nature of the eliciting stimulus.     

Murine catalase phenotypes

An examination of three inbred strains of mice differing with respect to liver and kidney catalase activity reveals two distinct genetic factors controlling the level of liver catalase activity. The first genetic factor controls the catalytic activity of the enzyme. Specific activity of purified enzyme from C57BL/6 and C57BL/Ha strains is 60% of that of the DBA/2 strain. The second factor controls the content of liver catalase. Liver catalase of C57BL/Ha is degraded in vivo at a rate one half that of liver catalase of DBA/2 and C57BL/6, resulting in the accumulation of twice as many catalase molecules in C57BL/Ha. The factor affecting turnover of catalase is apparently specific for catalase of liver since no differences exist in kidney catalase levels between C57BL/Ha and C57BL/6. Furthermore, this factor does not appear to alter the metabolism of total liver protein since no substantial difference in the turnover rate of liver protein is observed among the strains. It is particularly significant that the genetic factor affecting the amount of liver catalase does so by altering the rate of catalase degradation rather than the rate of synthesis, confirming the previously published report of Rechcigl and Heston (1967). Thus, these studies emphasize that the quantity of an enzyme in animal cells is a balance between the rate of synthesis and the rate of degradation of the enzyme.This paper was presented at a symposium entitled Genetic Control of Mammalian Metabolism held at The Jackson Laboratory, Bar Harbor, Maine, June 30–July 2, 1969. The symposium was supported in part by an allocation from NIH General Research Support Grant FR 05545 from the Division of Research Resources to The Jackson Laboratory.This investigation was supported by USPHS Research Grant GM 14931 from the Division of General Medical Sciences, and Grants PF-373 and P-427 from the American Cancer Society.     

Genetic control of T-Cell subset representation in inbred mice

Lyt-2+ T cells constitute a significantly greater proportion of the total peripheral T-cell population in C57BL mice than in BALB/c and other mouse strains. The inheritance of this differential representation of Lyt-2- vs. Lyt-2+ T cells was studied by two-color immunofluorescence analysis of peripheral T cell subsets in BALB/c, C57BL, F1 and F2 generations, and in CXB recombinant inbred strains. It was shown that the C57BL phenotype (low Lyt-2-/Lyt-2+ ratio) is a dominant Mendelian character. Studies of subpopulations of thymocytes and of early thymus emigrants indicate that the representation of mature Lyt-2- and Lyt-2+ T cells is influenced by mechanisms of selection or differential turnover in the peripheral lymphoid organs, but that thymic and prethymic influences may also play a role.     

Role of phosphatidylinositol-3-kinase-gamma (PI3Kgamma)-mediated pathway in 17beta-estradiol-induced killing of L. mexicana in macrophages from C57BL/6 mice

We recently demonstrated that 17beta-estradiol (E2) enhances killing of Leishmania mexicana in macrophages from both male and female DBA/2 mouse by increasing nitric oxide (NO) production. Here, we analyzed the effect of E2 on leishmanicidal activity and cytokine production by bone marrow-derived macrophages (BMDMs) from male and female C57BL/6 mice in vitro, specifically examining the role of phosphatidylinositol-3-kinase-gamma (PI3Kgamma) in E2-induced parasite killing. Unlike its effect on macrophages from both male and female DBA/2 mice, E2 only increased leishmanicidal activity in macrophages from female C57BL/6 mice, which was evident by a significant reduction in both infection rates and infection levels compared to sham controls. E2-treated BMDMs from female C57BL/6 mice expressed higher levels of interferon-gammaRalpha, and also produced more interleukin (IL)-12, IL-6 and NO than both the sham controls and E2-treated male-derived macrophages. Sham-treated BMDMs from female PI3Kgamma-/- C57BL/6 mice displayed lower infection rates and infection levels compared to sham-treated wild-type (WT) macrophages. However E2, unlike its effect on macrophages from female WT C57BL/6 mice, failed to reduce infection rates and infection levels in BMDMs from female PI3Kgamma-/- mice. Interestingly, E2-treated BMDMs from female C57BL/6 mice produced significant amounts of inflammatory cytokines and NO in levels comparable to those observed in sham-treated PI3Kgamma-deficient macrophages as well as E2-treated macrophages from WT mice. These findings show that E2 exerts a distinct effect on leishmanicidal activity of macrophages from male versus female C57BL/6 mice. In addition, they suggest that PI3Kgamma is not required for E2-induced cytokine and NO production in L. mexicana-infected macrophages from female C57BL/6 mice but it may be involved in parasite clearance from these cells.     

Macrophage chemotactic response in mice is controlled by two genetic loci

The level of the in vitro chemotactic responsiveness of murine inflammatory peritoneal macrophages is dependent upon the genetic background of the host. A survey of the responses of macrophages from various inbred strains showed three categories of response (high, intermediate, and low), indicating that genetic control is multigenic. Among the high responder strains were those derived from the C57BL (B) background, while mice of the A/J (A) strain exhibited the lowest response. In order to determine the number of genes controlling the level of macrophage chemotactic responses, segregation analysis of backcross mice derived from high responder B and low responder A parental mice was performed. The results of analysis of the data by the maximum likelihood modeling, a computerized method, showed that the difference in macrophage chemotactic responsiveness in the strain combination of B and A mice is due to the effects of two autosomal genetic loci.     

A quantitative genetic analysis of tissue-specific catalase activity inMus musculus

Tissue-specific catalase activity in 3-week-old animals from inbred mouse strains 129/ReJ, BALB/c, C3H/HeAnl/Cas-1^b, C3H/HeSnJ, C3H/S, C57BL/6J, and Swiss-Webster was found to be highly variable by analysis of variance (P=0.01). Appropriate crosses were made among strains which were classified as normal (BALB/c, C3H/HeSnJ, C3H/S), hypocatalasemic (129/ReJ, C57BL/6J), and acatalasemic (C3H/HeAnl/Cas-1^b) with respect to blood catalase activity to study the inheritance of the blood, kidney, liver, and lung catalase activity levels in a number of generations (reciprocal F₁'s, F₂, two backcrosses —BC₁ and BC₂— and some RI lines). Segregation analysis and statistical methods which tested different models of inheritance as well as calculations of heritability were used in an effort to assess and evaluate genetic parameters that affect catalase activity. Results indicate that the inheritance of blood catalase activity in the cross involving acatalasemic and normal (BALB/c, C3H/HeSnJ) strains is compatible with the single-locus difference between the parental strains; however, the difference between the acatalasemic and the hypocatalasemic strain (C57BL/6J) would require additional genetic interaction for a satisfactory explanation. A similar pattern of generalization also applies to the inheritance of kidney catalase activity. The segregation pattern for the liver and lung catalase activity in most crosses is significantly different from the expectations of the single locus model. These results are compatible with the concept that a number of genes must affect tissue-specific catalase activity in mice. These may include previously described (e.g., Ce-1 and Ce-2) or novel genetic regulators/modifiers which interact with a single structural gene (Cas-1) or its product to produce the catalase phenotype characteristic of specific tissues in each strain.This investigation was supported by a Natural Sciences and Engineering Research Council of Canada operating grant to S.M.S.