Mouse chromosome 1 Ity locus regulates microbicidal activity of isolated peritoneal macrophages against a diverse group of intracellular and extracellular bacteria

The genotype of a mouse influences whether or not it will survive infection with the agent of murine typhoid, Salmonella typhimurium. The best-characterized murine salmonella response gene is a Chromosome 1 locus designated Ity. Inbred strains of mice that express the Itys allele are unable to contain the net growth of Salmonella typhimurium within their spleens and livers, and usually die early in the infection. By contrast, mice homozygous or heterozygous for the Ityr allele are able to control the net multiplication of Salmonella typhimurium within these organs. The Ity gene also appears to regulate the extent of replication within murine reticuloendothelial cell tissues of the obligate intracellular parasite Leishmania donovani, as well as the facultative intracellular bacteria Mycobacterium bovis and Mycobacterium lepraemurium. Previous studies from our laboratory strongly suggested that Ityr mice are more resistant to S. typhimurium infection than are Itys mice, because resident Ityr macrophages kill salmonellae more efficiently than do Itys macrophages. In this study, we used an in vitro macrophage assay to assess the specificity of the enhanced killing capacity of Ityr macrophages. We found that Ityr macrophages were better able than Itys macrophages to kill both intracellular bacteria (Salmonella typhi) and extracellular bacteria (Escherichia coli, Staphylococcus aureus, Corynebacterium diphtheriae). Thus, the diversity of organisms affected by Ity expression suggests that the product of this gene may play a key regulatory role in the initial interaction of mice with a variety of microbial agents.     

Genetic control of the innate resistance of mice to Salmonella typhimurium: Ity gene is expressed in vivo by 24 hours after infection

The early response of inbred mice to infection with S. typhimurium is controlled by the mouse Chromosome 1 locus, Ity. To better understand the expression of this gene, the initial interactions between the reticuloendothelial system (RES) and i.v. injected salmonellae were compared in resistant (Ityr) and susceptible (Itys) mice. In both mouse strains 99% of the bacteria was cleared from the blood within 2 hr, and uptake of S. typhimurium by splenic and hepatic macrophages was similar regardless of Ity genotype. In vivo phagocytosis of bacteria was followed by a 30 to 60% decline in viable bacteria, which was attributed to the bactericidal activity of RES macrophages. Experiments with radiolabeled S. typhimurium strains TML and TML/TS27 (a temperature-sensitive mutant) confirmed that the efficiency of this early phase killing was not under Ity control. Despite the equivalent uptake and initial bactericidal activity by resident macrophages, bacterial numbers in the RES organs of Itys mice were significantly greater than in Ityr mice by approximately 24 hr after infection. These data suggest that Ity regulates the level of surviving intracellular bacteria that accumulate within resident macrophages of the liver and spleen.     

The primary effect of the Ity locus is on the rate of growth of Salmonella typhimurium that are relatively protected from killing

The Ity locus affects the net increase in numbers of Salmonella typhimurium in the liver and spleen of infected mice. There has been controversy, however, about whether the effects of this locus are due to differential killing of S. typhimurium or differential growth rates of S. typhimurium in mice. Our studies using S. typhimurium aroA mutants, which do not grow in vivo, demonstrate that growth of the infecting salmonella is necessary for the observation of the Ity phenotype. To examine the effects of the Ity locus on the growth and killing of fully virulent salmonella, we infected Ity-congenic mice i.v. with stationary phase S. typhimurium containing a single copy of the plasmid pHSG422. This plasmid exhibits defective replication at body temperature and is diluted out during salmonella growth in vivo. Thus, the frequency of plasmid-containing salmonella recovered from mice provides a measure of salmonella cell divisions in vivo. Inasmuch as the numbers of plasmid-containing salmonella are only slightly affected by bacterial division, any decline in the numbers of plasmid-containing salmonella is an unbiased measure of killing. By infecting mice with these plasmid-containing salmonella we observed that: 1) during the first four h post infection (during blood clearance of injected salmonella) there is about 3-fold more killing of salmonella in Ityr mice than in Itys mice; 2) from 4 to 44 h postinfection (after blood clearance is completed) there is little if any additional killing in either Itys or Ityr mice; and 3) during the first 48 h postinfection there is about 18-fold more growth of salmonella in Itys mice than in Ityr mice. Thus, the major effect of the Ity locus on resistance to salmonella, is the regulation of growth within a "safe" (relatively nonbactericidal) site in the liver and spleen.     

Effect of pertussis vaccine on the functional activity of the peritoneal and splenic macrophages in 2 mouse strains genetically differing by the intensity of their immune response

The immunostimulating effect of corpuscular pertussis vaccine on the antigen-presenting and bactericidal functions of peritoneal and splenic macrophages in CBA and C57BL/6 mice, differing in the intensity of immune response to sheep red blood cells and Salmonella typhimurium, has been studied. The study has revealed that the injection of pertussis vaccine alters the functional activity of the cells under study, the effect depending on the immunizing dose, the strain of mice and the time elapsed from the moment of immunization. Pertussis vaccine enhances the low capacity of macrophages for antigen presentation in C57BL/6 mice with low responsiveness and alters the resistance of peritoneal and splenic macrophages to the cytopathic action of salmonellae.     

Activation of mouse peritoneal macrophages during infection with Salmonella typhimurium does not result in enhanced intracellular killing

Our study was performed to investigate whether macrophages become activated during an infection with Salmonella typhimurium and, if so, whether these activated macrophages kill S. typhimurium faster than resident macrophages. Mice received i.v. injections with a sublethal number of S. typhimurium; on about day 12 of the infection the numbers of bacteria in the liver and the spleen were maximal. During the infection, activation of peritoneal macrophages could be demonstrated on the basis of three criteria, i.e., the ability to inhibit the proliferation of Toxoplasma gondii, an enhanced production of H2O2 and an increased expression of Ia Ag. The rate of in vitro intracellular killing of S. typhimurium by these activated macrophages was not increased compared to that for resident macrophages. To determine the growth of S. typhimurium in activated mice a nalidixic acid-resistant mutant strain, called S. typhimurium 510R, was used. The net growth rates of the mutant S. typhimurium 510R in the spleen of S. typhimurium 510-activated and normal mice were similar. However, in the liver of S. typhimurium 510-activated mice the number of S. typhimurium 510R did not change during 3 to 48 h after injection. The role of specific antibodies during the initial phase of the infection was negligible, because only low levels of antibodies were detected during the first 15 days of infection and the growth rates of S. typhimurium 510 in the spleen and liver of mice with high titers of antibodies were not significantly different from the rates in normal mice. The results of this study demonstrate that although macrophages become activated during an infection with S. typhimurium, these cells do not display an enhanced bactericidal activity in vitro and in vivo no significant effect on the growth rate of S. typhimurium in the spleen and a bacteriostatic effect in the liver is found. Hence macrophage activation is probably not very important in the host defense against S. typhimurium.     

Host resistance to mucosal gram-negative infection. Susceptibility of lipopolysaccharide nonresponder mice

The effect of Lps on the resistance of mice to gram-negative infection was compared in two genetically different backgrounds; C3H and C57BL. To mimic the natural sequence of pathogenetic events, infection was induced via a mucosal surface (intravesically), with Escherichia coli which remained at the mucosal site and Salmonella typhimurium which invaded to e.g., livers and spleens. Susceptibility was assessed as the bacterial persistence in kidneys, bladders, livers, and spleens at various times after infection. The initial clearance of both bacterial species from the mucosal site was significantly impaired in Lpsd mice both in the C3H and C57BL backgrounds. In the C57BL mice, additional unknown determinants conferred increased resistance to mucosal infection compared to the C3H mouse. For S. typhimurium, these resistance factors and alleles at the Lps locus dominated over Ity as determinants of resistance to mucosal infection. The Itys genotype conferred a significant increase in the susceptibility only to systemic infection, especially in the Lpsd, Itys mice. These results demonstrate an important difference between the genetic determinants of host resistance at mucosal and systemic sites, and emphasize the role of LPS induced host defense mechanisms for bacterial clearance from mucosal surfaces.     

Effect of insulin and isoproterenol on macrophage phagocytic activity

To reveal the influence of cyclic adenosine monophosphate (cAMP) on the completion of the phagocytosis of salmonellae, the influence of insulin and isoproterenol on the phagocytic activity of peritoneal macrophages obtained from mice infected with S. typhimurium strains differing in virulence was studied in vitro. The study showed that isoproterenol, while increasing the intracellular content of cAMP, suppressed the bactericidal properties of macrophages with respect to salmonellae, whereas insulin decreased the level of cAMP in the cells and thus facilitated more rapid and complete digestion of ingested bacteria irrespective of their virulence.     

Effects of in vitro growth phase on the pathogenesis of Salmonella typhimurium in mice

The growth phase of a bacterial (Salmonella typhimurium) culture was shown to have pronounced effects on the pathogenic properties of the harvested bacteria. Salmonellae obtained from a culture in primary (exponential) growth phase (PP) were more readily cleared from the blood and more readily killed by phagocytes than were salmonellae obtained from a more slowly growing secondary growth phase (SP) culture. PP salmonellae were observed to cause death of mice sooner than SP salmonellae. This appeared to be because the more rapid growth of PP, as compared to SP, salmonellae continued in the liver and spleen for several hours following intravenous injection, and more than compensated for their high in vivo death rate. As a result, within 4 h there were approximately 10-fold more live salmonellae in the spleens and livers of mice that had received PP, as compared to SP, salmonellae. This 10-fold difference was maintained until the death of the mice, indicating that after the first 4 h post-inoculation, the net in vivo growth of the salmonellae was the same regardless of their growth phase in the inoculating culture. This transition between PP and SP salmonellae occurred long before a dense stationary phase culture was obtained. Salmonellae grown in minimal media exhibited the biological properties of SP salmonellae and never entered as rapid a growth phase as did salmonellae in complete media.     

Inability of recombinant interferon-gamma to activate the antibacterial activity of mouse peritoneal macrophages against Listeria monocytogenes and Salmonella typhimurium

The effect of recombinant murine interferon-gamma (rIFN-gamma) as single stimulus for the activation of antibacterial activity of macrophages was investigated on the basis of the rate of intracellular killing of Listeria monocytogenes and Salmonella typhimurium by normal and rIFN gamma-activated peritoneal macrophages of CBA and C57BL/10 mice, which differ in natural resistance to infection by these bacteria. Eighteen hours after i.p. injection of 10 to 1 X 10(4) U rIFN-gamma, resident and exudate peritoneal macrophages which had phagocytosed L. monocytogenes or S. typhimurium in vivo, killed both species in vitro just as efficiently as did resident macrophages of normal mice. Similar results were obtained after 18 hr of in vitro incubation of resident or exudate peritoneal macrophages with 0.1 to 1 X 10(4) U/ml rIFN-gamma. Consistent with the in vitro findings, two i.v. injections of 5 X 10(4) U rIFN-gamma did not affect the rate of in vivo proliferation of L. monocytogenes or S. typhimurium in the spleens of mice during the first 2 days after i.v. injection of the bacteria. Compared with the effect on the controls, two i.p. injections of 5 X 10(2) to 5 X 10(4) U rIFN-gamma did not decrease the numbers of viable S. typhimurium in either the peritoneal cell suspension or the spleen 24 hr after i.p. injection of the bacteria. Checking the state of activation of rIFN-gamma-activated macrophages on the basis of two commonly used criteria for macrophage activation showed that rIFN-gamma-activated macrophages inhibited the intracellular replication of Toxoplasma gondii and displayed enhanced O2 consumption and H2O2 release after stimulation with phorbol myristate acetate compared with macrophages from normal CBA and C57BL/10 mice. The present findings show that as single activating stimulus, rIFN-gamma is not capable of activating the antibacterial effector functions of peritoneal macrophages against facultative intracellular pathogens such as L. monocytogenes and S. typhimurium.     

GM-CSF administration augments the survival of ity-resistant A/J mice, but not ity-susceptible C57BL/6 mice, to a lethal challenge with Salmonella typhimurium

Ity resistant A/J mice were challenged with a lethal dose (2 x 10(3) organisms) of Salmonella typhimurium. Infected mice treated with 1 microgram of GM-CSF twice daily showed increased median survival time and had a higher survival fraction than untreated controls. GM-CSF was most effective when given for a brief period (1 to 2 days) after infection. Pretreatment of the mice or delayed treatment with GM-CSF had no effect on the survival of the mice. Studies on the effect of GM-CSF on the bacterial load showed that mice treated with GM-CSF had fewer S. typhimurium in the spleen and peritoneal cavity on day 4 but not on day 2 after infection. GM-CSF treatment of ity-susceptible C57BL/6 mice infected with 10 organisms had no therapeutic effect.     

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.     

Interaction of T-activin with peritoneal macrophages

The action of T-activin on peritoneal macrophages of CBA mice after its introduction into the animals has been studied. In intact mice the phagocytic activity of macrophages and their resistance to the cytopathogenic action of Salmonella typhimurium live cells remains unchanged. The injection of corpuscular pertussis vaccine into mice leads to a decrease in the resistance of macrophages to the action of salmonellae. The simultaneous injection of T-activin into mice in doses of 0.1 and 1.0 microgram per animal abolishes the damaging action of the vaccine. The analysis of the in vitro action of T-activin on macrophages of intact mice revealed that the preliminary incubation of cells with the preparation sharply increases their resistance to the action of salmonellae, while its introduction simultaneously with bacteria or after them rapidly leads to the death of macrophages. The action of T-activin is supposed to be linked with triggering the biosynthetic processes mediating the resistance of macrophages to the cytopathogenic action of salmonellae.     

Effect of cyclic 3,5-adenosine monophosphate on the virulence of Salmonella typhimurium

To study the role of cAMP in the virulence of S. typhimurium, cAMP-producing plasmid pTG 4 was transferred to cAMP-deficient S. typhimurium mutant. The transfer of the plasmid enhanced the virulence of the microorganisms due to the increased destruction of macrophages and the intensified multiplication of salmonellae in the spleen of mice.     

Adoptive transfer of natural killer cell activity in B6D2F1 mice challenged with Salmonella typhimurium

The purpose of this study was to extend our previous findings as to the role of murine NK cells in host protection to a challenge infection with virulent Salmonella typhimurium SR-11. B6D2F1 mice were depleted of NK cells with anti-asialo GM1 or a monoclonal antibody, anti-NK 1.1, followed by a salmonellae challenge. Significantly decreased numbers of splenic bacteria (P less than 0.005) in the NK cell-depleted mice were note at 12, 24, and 48 hr postchallenging, compared to the sham-injected control animals. When Percoll gradient-enriched large granular lymphocytes (NK cells) were adoptively transferred to NK cell-depleted mice followed by challenging, the splenic bacterial numbers were comparable to those present in NK cell-intact, control mice. These data indicate that large granular lymphocytes (NK cells) are responsible for the down-regulation of the protective host response in mice challenged with the facultative intracellular parasite. S. typhimurium.     

Use of the reaction of macrophage disappearance from peritoneal exudate for characterizing cellular immunity in Salmonella immunization

The test of macrophage disappearance from peritoneal exudate quite effectively shows the state of cell-mediated immunity in guinea pigs immunized with both live and killed S. typhimurium culture. The macrophages of the animals immunized with killed S. typhimurium culture react to the protein extract of these bacteria more actively than the macrophages of the animals immunized with killed S. sonnei cultures, which indicates the specificity of this test.     

Role of bacterial DNA in macrophage activation by group B streptococci

Bacterial DNA (CpG DNA) induces macrophage activation and the production of inflammatory mediators, including tumor necrosis factor (TNF) and nitric oxide (NO) by these cells. However, the role of bacterial DNA in the macrophage response to whole bacteria is unknown. We used overlapping strategies to estimate the relative contribution of bacterial DNA to the upregulation of TNF and NO production in macrophages stimulated with antibiotic-treated group B streptococci (GBS). Selective inhibitors of the bacterial DNA/TLR9 pathway (chloroquine, an inhibitory oligonucleotide, and DNase I) consistently inhibited GBS-induced TNF secretion by 35-50% in RAW 264.7 macrophages and murine splenic macrophages, but had no effect on inducible nitric oxide synthase (iNOS) accumulation or NO secretion. Similarly, splenic and peritoneal macrophages from mice lacking TLR9 expression secreted 40% less TNF than macrophages from control mice after GBS challenge but accumulated comparable amounts of iNOS protein. Finally, studies in both RAW 264.7 cells and macrophages from TLR9-/- mice implicated GBS DNA in the upregulation of interleukins 6 (IL-6) and 12 (IL-12) but not interferon-beta (IFNbeta), a key intermediary in macrophage production of iNOS/NO. Our data suggest that the bacterial DNA/TLR9 pathway plays an important role in stimulating TNF rather than NO production in macrophages exposed to antibiotic-treated GBS, and that TLR9-independent upregulation of IFNbeta production by whole GBS may account for this difference.     

Intracellular replication of Salmonella typhimurium strains in specific subsets of splenic macrophages in vivo

We used flow cytometry and confocal immunofluorescence microscopy to study the localization of Salmonella typhimurium in spleens of infected mice. Animals were inoculated intragastrically or intraperitoneally with S. typhimurium strains, constitutively expressing green fluorescent protein. Independently of the route of inoculation, most bacteria were found in intracellular locations 3 days after inoculation. Using a panel of antibodies that bound to cells of different lineages, including mononuclear phagocyte subsets, we have shown that the vast majority of S. typhimurium bacteria reside within macrophages. Bacteria were located in red pulp and marginal zone macrophages, but very few were found in the marginal metallophilic macrophage population. We have demonstrated that the Salmonella SPI-2 type III secretion system is required for replication within splenic macrophages, and that sifA ⁻ mutant bacteria are found within the cytosol of these cells. These results confirm that SifA and SPI-2 are involved in maintenance of the vacuolar membrane and intracellular replication in vivo .     

Role of peritoneal macrophages in the development of an experimental Salmonella infection

The effect produced on the course of Salmonella infection in mice by the removal of peritoneal macrophages with agarose has been studied. Peritoneal macrophages have been shown to control the multiplication of faintly virulent and virulent S. typhimurium strains in the spleen of mice. In immune mice the elimination of the virulent strain of the causative agent of superinfection may occur without the control of peritoneal macrophages.