Induction of Salmonella stress proteins upon infection of macrophages.

Regulated expression of bacterial genes allows a pathogen to adapt to new environmental conditions within the host. The synthesis of over 30 Salmonella proteins is selectively induced during infection of macrophages. Two proteins induced by Salmonella are the heat shock proteins GroEL and DnaK. Two avirulent, macrophage-sensitive mutants of Salmonella synthesize GroEL and DnaK but fail to synthesize different subsets of proteins normally induced within the macrophage. Enhanced expression of selected Salmonella proteins contributes to bacterial survival within macrophages and may also contribute to the apparent immunodominance of heat shock proteins.

DNA repair is more important than catalase for Salmonella virulence in mice.

Pathogenic microorganisms possess antioxidant defense mechanisms for protection from reactive oxygen metabolites such as hydrogen peroxide (H2O2), which are generated during the respiratory burst of phagocytic cells. These defense mechanisms include enzymes such as catalase, which detoxify reactive oxygen species, and DNA repair systems which repair damage resulting from oxidative stress. To determine the relative importance of these two potentially protective defense mechanisms against oxidative stress encountered by Salmonella during infection of the host, a Salmonella typhimurium double mutant unable to produce either the HPI or HPII catalase was constructed, and compared with an isogenic recA mutant deficient in DNA repair. The recA mutant was hypersusceptible to H2O2 at low cell densities in vitro, while the catalase mutant was more susceptible to high H2O2 concentrations at high cell densities. The catalase mutant was found to be resistant to macrophages and retained full murine virulence, in contrast to the recA mutant which previously was shown to be macrophage-sensitive and attenuated in mice. These observations suggest that Salmonella is subjected to low concentrations of H2O2 while at relatively low cell density during infection, conditions requiring an intact DNA repair system but not functional catalase activity.

Inhibition of macrophage phagosome-lysosome fusion by Salmonella typhimurium.

Salmonella typhimurium-infected macrophages were examined by electron microscopy to determine whether intracellular survival of S. typhimurium is associated with failure of bacteria containing phagosomes to fuse with secondary lysosomes. S. typhimurium 14028 actively inhibited phagosome-lysosome fusion and appeared to preferentially divide within unfused phagocytic vesicles. In comparison with Escherichia coli, S. typhimurium inhibited phagosome-lysosome fusion in peritoneal macrophages, J774 macrophages, and bone marrow-derived macrophages from both BALB/c (itys) and SWR/J (ityr) mice. The mechanism responsible for Salmonella inhibition of phagosome-lysosome fusion is unknown but requires viable salmonellae, is not blocked by opsonization with fresh normal mouse serum, and is not due to lipopolysaccharide. Inhibition of phagosome-lysosome fusion may play a critical role in survival of salmonellae within macrophages and in virulence.

Suppression of monocyte functions by human cytomegalovirus.

The role of the monocyte in human cytomegalovirus (HCMV)-induced immunosuppression was examined by assessing the ability of the virus to directly suppress various monocyte accessory cell functions. Both patient-derived and laboratory-adapted strains of HCMV were capable of impairing antigen-presenting functions of purified human monocytes. In seven of 12 virus-infected samples, there was a significant decrease (P less than 0.05) in the ability of HCMV-infected monocytes to present tetanus toxoid to autologous lymphocytes compared with mock-infected controls; similar results were obtained with Candida albicans and mumps. In contrast, the response to PHA was impaired in only one of eight HCMV-infected samples. The increased expression of MHC class II Ia antigens (HLA-DQ and HLA-DR) by monocytes after stimulation by interferon-gamma was impaired in approximately one-third of the 43 virus-infected samples tested. Interleukin-1 (IL-1) production after incubation with the stimulating antigens, however, was unaffected. Attempts to augment immuno-suppression by co-stimulation of monocytes with lipopolysaccharide (LPS), heat-killed Escherichia coli or Listeria monocytogenes were not successful; however, dramatically increased levels of immunosuppression was obtained with HCMV preparations containing mycoplasma. Thus, although HCMV is capable of directly perturbing monocyte accessory cell functions, the variability and partial suppression observed suggests that infection of monocytes by HCMV alone is not sufficient to produce the levels of immune hyporesponsiveness observed in HCMV-infected patients.

Intracellular survival of wild-type Salmonella typhimurium and macrophage-sensitive mutants in diverse populations of macrophages.

Salmonella typhimurium survives within macrophages and causes a fatal infection in susceptible strains of mice. A number of S. typhimurium mutants that contain Tn10 insertions in genes which are necessary for survival within the macrophage have been isolated. To demonstrate the importance of each gene in intracellular survival, the mutations were transduced into a smooth-strain background and the ability to survive intracellularly was assayed in five different populations of macrophages. The majority of the original macrophage-sensitive mutants retained the macrophage-sensitive phenotype in the smooth-strain background. The ability to survive or grow within macrophages varied with both the source of macrophages and the individual mutants. S. typhimurium grew best in the macrophage-like cell line J774, survived at moderate levels in splenic and bone marrow-derived macrophages, and was killed most efficiently in peritoneal macrophages. Macrophage-sensitive mutants transduced into a smooth background were also less virulent than the parent, with a 50% lethal dose of 2 to 5 logs greater than that of the parental strain. These experiments demonstrate that survival of S. typhimurium within macrophages varies with the source of cells, with a distinct ability to survive in macrophages from mouse spleens, where S. typhimurium grows rapidly. These experiments also demonstrate the heterogeneity in intracellular survival among the various macrophage-sensitive mutants, which may reflect the relative importance of the individual mutated genes in survival within macrophages.

Dynamics of growth and death within a Salmonella typhimurium population during infection of macrophages.

Survival of Salmonella typhimurium within macrophages is associated with virulence. Most data on the fate of Salmonella during infection of macrophages are derived from viable counts of intracellular bacteria. These counts are a result of a combination of bacterial death and growth within the intracellular population but may not reflect the true levels of either macrophage killing of Salmonella or bacterial growth inside cells. In this study, two independent methods have been used to obtain a more accurate measurement of absolute levels of both death and growth of Salmonella inside macrophages. A purine auxotroph (purD) was used to measure Salmonella death in the absence of bacterial growth and then bacterial growth was measured by supplementing the purD cultures with adenosine. Numbers of dead and live Salmonella were also quantitated using the BacLight staining system, which distinguishes dead from live bacteria. Both methods demonstrate that killing of Salmonella by macrophages is considerably greater than detected using traditional cell counts and that bacterial inactivation occurs throughout the infection period. Salmonella was inactivated at a similar rate in both J774 macrophages (most permissive macrophages) and peritoneal exuadate macrophages (least permissive macrophages), suggesting that the major difference between these cells is the ability to limit bacterial growth. These studies also demonstrate that growth of Salmonella within murine macrophages occurs simultaneously with significant amounts of bacterial death. Identifying the factors responsible for shifting the interaction between macrophages and bacteria toward conditions that favor bacterial growth will be critical to understanding Salmonella virulence.

Requirement of endogenous interferon-gamma production for resolution of Listeria monocytogenes infection.

Peritoneal exudate cells and splenic cells of mice infected with Listeria monocytogenes show increased production of interferon-gamma (IFN-gamma) after antigen or mitogen stimulation. When an IFN-gamma-specific enzyme-linked immunosorbent assay was used, increased production was first observed 2 days after infection in peritoneal cells and 4 to 6 days after infection in splenic cells. The increased production of IFN-gamma correlated with the clearance of Listeria from the peritoneal cavity and spleen. Macrophages derived from mice at these times were activated as evidenced by expression of nonspecific tumoricidal activity against 111In-labeled P815 mastocytoma cells. Injection of neutralizing monoclonal anti-IFN-gamma into 1-day-infected mice completely inhibited the generation of activated macrophages. Normal hamster IgG had no effect. In vivo, the monoclonal antibody also abrogated clearance of bacteria from the spleen and peritoneal cavity. Six days after injection of a sublethal dose of Listeria, the peritoneal cavity of control mice treated with normal hamster IgG was devoid of bacteria and the spleen contained less than 10(3) colony-forming units. However, mice treated with anti-IFN-gamma carried more than 8 X 10(6) colony-forming units in either anatomical site at day 6 and exhibited a higher mortality rate. These results indicate that IFN-gamma production is required for the in vivo generation of activated macrophages and the clearance of bacteria during Listeria infection.

Growth of Mycobacterium tuberculosis in a defined medium is very restricted by acid pH and Mg(2+) levels.

Mycobacterium tuberculosis grows within the phagocytic vacuoles of macrophages, where it encounters a moderately acidic and possibly nutrient-restricted environment. Other mycobacterial species encounter acidic conditions in soil and aquatic environments. We have evaluated the influence of pH and divalent cation levels on the growth of M. tuberculosis and seven other mycobacterial species. In a defined medium, the growth of M. tuberculosis was very restricted by acidic pH. Higher levels of Mg(2+) were required for growth of M. tuberculosis in mildly acidic media (pH 6.0 to 6.5) compared to pH 7. 0 medium. The divalent cations Ca(2+), Zn(2+), or Mn(2+) could not replace Mg(2+) during growth at pH 6.25, but Ca(2+) could at least partially substitute for Mg(2+) during growth at pH 7.0. Among eight species of mycobacteria tested, there was a diversity of growth rates in media with acidic pH and low Mg(2+) levels. M. tuberculosis was the most restricted in growth at pH 6.0, and all of this growth required elevated levels of Mg(2+). M. kansasii and M. smegmatis also grew very poorly in acidic media with limiting Mg(2+). M. fortuitum, M. marinum, M. scrofulaceum, M. avium, and M. chelonae grew at pH 6.0 in an unrestricted manner. These results demonstrate that M. tuberculosis is unique among the mycobacteria in its extreme sensitivity to acid and indicate that M. tuberculosis must acquire sufficient Mg(2+) in order to grow in a mildly acidic environment such as within the phagosome of macrophages.

Recombination-deficient mutants of Salmonella typhimurium are avirulent and sensitive to the oxidative burst of macrophages.

Mutations in the genes recA and recBC were constructed in the virulent Salmonella typhimurium strain 14028s. Both the recA and recBC mutants were attenuated in mice. The mutants were also sensitive to killing by macrophages in vitro. The recombination mutants were no longer macrophage sensitive in a variant line of J774 macrophage-like cells that fail to generate superoxide. This suggests that repair of DNA damage by Salmonella is necessary for full virulence in vivo and that the oxidative burst of phagocytes is one source of such DNA damage.

Abortive replication of vaccinia virus in activated rabbit macrophages.

During the course of infection of rabbits with vaccinia virus, macrophages obtained from the peritoneal cavity develop bactericidal activity and the replication of vaccinia virus becomes restricted in these cells. The abortive replication of vaccinia virus in the activated macrophages was characterized in the present study. The virus adsorbed to and was uncoated equally well in macrophages from both normal and infected rabbits. A burst of deoxyribonucleic acid synthesis of comparable magnitude took place 3 to 6 h after infection in both normal and activated macrophages. Although the production of viral antigens, as detected by immunodiffusion and immunofluorescence, was the same in both types of cells, very few virus particles were formed in activated as compared with normal macrophages. We conclude that a block in a late step of the virus replication cycle occurred in the activated macrophages.

Monoclonal antibodies to murine gamma-interferon which differentially modulate macrophage activation and antiviral activity.

Four monoclonal IgG antibodies to purified, recombinant murine gamma-interferon (rIFN-gamma) have been produced by fusion of immune hamster splenocytes with HAT-sensitive murine myeloma cells. Specificity was confirmed either with an enzyme-linked immunosorbent assay (ELISA) that used immobilized rIFN-gamma or with a radioimmunoassay that employed soluble 125I-rIFN-gamma and heat-killed, fixed Staphylococcus aureus-bearing Protein A. Competition binding experiments suggested that the monoclonal antibodies (MoAb) displayed two distinct epitope specificities: one displayed by H1 and H2, and the other displayed by H21 and H22. By using murine-human recombinant IFN-gamma hybrid molecules, the H1/H2 epitope was shown to depend on the amino-terminus of IFN-gamma, whereas the H21/H22 epitope was formed by the carboxy-terminal amino acid sequence. The MoAb also reacted with natural IFN-gamma. When bound to a surface, all four MoAb, but not normal hamster IgG, removed 100% of the antiviral and MAF activities present in supernatants of cultures of the murine 24/G1 T cell hybridoma. In free solution, all four antibodies inhibited IFN-gamma dependent antiviral activity, but with different efficiencies. Soluble H21/H22 also blocked all of the 24/G1-derived activity that induces nonspecific tumoricidal activity in macrophages (MAF) while H1/H2 enhanced MAF activity. The differential inhibitory or enhancing activities of H21 or H1 reflected their ability to inhibit or enhance binding of 125I-rIFN-gamma to macrophages, respectively. Soluble H21/H22 and solid-phase H1/H2 inhibited 100% of the MAF, microbicidal, and Ia-inducing activities from lymphokine preparations produced by mitogen stimulation of normal murine splenic cells. These results help to establish definitive structure-function relationships for the IFN-gamma molecule, and indicate that IFN-gamma is the primary lymphokine responsible for inducing nonspecific tumoricidal activity and Ia antigen expression, and for enhancing microbicidal activity in macrophages.

Biology and clinical significance of virulence plasmids in Salmonella serovars.

Non-typhoid Salmonella strains containing virulence plasmids are highly associated with bacteria and disseminated infection in humans. These plasmids are found in Salmonella serovars adapted to domestic animals, such as Salmonella dublin and Salmonella choleraesuis, as well as in the widely distributed pathogens Salmonella typhimurium and Salmonella enteritidis. Although virulence plasmids differ between serovars, all contain a highly conserved 8-kb region containing the spv locus that encodes the spvR regulatory gene and four structural spvABCD genes. Studies in mice suggest that the spv genes enhance the ability of Salmonella strains to grow within cells of the reticuloendothelial system. The spv genes are not expressed during exponential growth in vitro but are rapidly induced following entry of Salmonella strains into mammalian cells, including macrophages. Transcription of the spv genes is controlled by the stationary-phase sigma factor RpoS, and mutations in RpoS abolish virulence. These studies suggest that the ability of Salmonella strains to respond to starvation stress in the host tissues is an essential component of virulence.

Central regulatory role for the RpoS sigma factor in expression of Salmonella dublin plasmid virulence genes.

The plasmid virulence genes spvABCD of Salmonella spp. are regulated by SpvR and the stationary-phase sigma factor RpoS. The transcription of spv genes is induced during the post-exponential phase of bacterial growth in vitro. We sought to investigate the relationship between growth phase and RpoS in spv regulation. rpoS insertion mutations were constructed in S. dublin Lane and plasmid-cured LD842 strains, and the mutants were found to be attenuated for virulence and deficient in spv gene expression. We utilized the plasmid pBAD::rpoS to express rpoS independent of the growth phase under the control of the arabinose-inducible araBAD promoter. SpvA expression was induced within 2 h after the addition of 0.1% arabinose, even when bacteria were actively growing. This suggested that the level of RpoS, instead of the growth phase itself, controls induction of the spv genes. However, RpoS did not activate transcription of spvA in the absence of SpvR protein. Using a constitutive tet promoter to express spvR, we found that the spvA gene can be partially expressed in the rpoS mutant, suggesting that RpoS is required for SpvR synthesis. We confirmed that spvR is poorly expressed in the absence of RpoS. With an intact rpoS gene, spvR expression is not dependent on an intact spvR gene but is enhanced by spvR supplied in trans. We propose a model for Salmonella spv gene regulation in which both RpoS and SpvR are required for maximal expression at the spvR and spvA promoters.

Cu,Zn superoxide dismutase of Mycobacterium tuberculosis contributes to survival in activated macrophages that are generating an oxidative burst.

Macrophages produce reactive oxygen species and reactive nitrogen species that have potent antimicrobial activity. Resistance to killing by macrophages is critical to the virulence of Mycobacterium tuberculosis. M. tuberculosis has two genes encoding superoxide dismutase proteins, sodA and sodC. SodC is a Cu,Zn superoxide dismutase responsible for only a minor portion of the superoxide dismutase activity of M. tuberculosis. However, SodC has a lipoprotein binding motif, which suggests that it may be anchored in the membrane to protect M. tuberculosis from reactive oxygen intermediates at the bacterial surface. To examine the role of the Cu,Zn superoxide dismutase in protecting M. tuberculosis from the toxic effects of exogenously generated reactive oxygen species, we constructed a null mutation in the sodC gene. In this report, we show that the M. tuberculosis sodC mutant is readily killed by superoxide generated externally, while the isogenic parental M. tuberculosis is unaffected under these conditions. Furthermore, the sodC mutant has enhanced susceptibility to killing by gamma interferon (IFN-gamma)-activated murine peritoneal macrophages producing oxidative burst products but is unaffected by macrophages not activated by IFN-gamma or by macrophages from respiratory burst-deficient mice. These observations establish that the Cu,Zn superoxide dismutase contributes to the resistance of M. tuberculosis against oxidative burst products generated by activated macrophages.

Macrophage activation to kill Leishmania major: activation of macrophages for intracellular destruction of amastigotes can be induced by both recombinant interferon-gamma and non-interferon lymphokines.

Macrophages treated with lymphokine (LK)-rich culture fluids from antigen- or mitogen-stimulated spleen cells or the hybridoma T cell 24/G1, or murine recombinant interferon-gamma (IFN-gamma) from either transfected monkey kidney cells (cos rIFN-gamma) or bacterial (E. coli) DNA (rIFN-gamma) developed the capacity to kill intracellular amastigotes of Leishmania major. Removal of IFN activity from LK by neutralizing fluid phase monoclonal anti-rIFN-gamma antibody, or by solid phase immunoadsorption, left residual macrophage activation factors that induced approximately 50% of the macrophage anti-leishmanial activity of untreated LK. In contrast, rIFN-gamma subjected to the same antibody treatments lost all capacity to induce this macrophage effector function. These results suggest that the intracellular destruction of amastigotes is regulated by several different factors. One of these factors is clearly IFN-gamma, which is pleiotropic in its effects on macrophage functions. The other non-IFN LK factors are immunochemically unrelated to IFN-gamma, and may regulate macrophage microbicidal activities in a more selective manner.

The alternative sigma factor katF (rpoS) regulates Salmonella virulence.

Nutrient limitation is a critical signal in Salmonella virulence gene regulation. The katF (rpoS) gene mediates the expression of the Salmonella spv plasmid virulence genes during bacterial starvation. A katF Salmonella mutant has increased susceptibility to nutrient deprivation, oxidative stress, acid stress, and DNA damage, conditions which are relevant to the intraphagosomal environment of host macrophages. Moreover, the katF mutant has significantly reduced virulence in mice. katF encodes an alternative sigma factor of RNA polymerase which coordinately regulates Salmonella virulence.

The spv genes on the Salmonella dublin virulence plasmid are required for severe enteritis and systemic infection in the natural host.

The pathogenic role of the spv (Salmonella plasmid virulence) genes of Salmonella dublin was determined in the natural, bovine host. Since the lack of overt signs of enteritis or enterocolitis due to Salmonella infections in mice has limited the development of a convenient experimental system to study enteric disease, we used calves to study the contribution of the spv genes to S. dublin-induced salmonellosis. Since the SpvR transcriptional regulator is required for expression of the spvABCD operon, we constructed an spvR knockout mutation in a calf-virulent strain of S. dublin. Calves were infected with the wild-type strain, an spvR mutant, and an spvR mutant containing a complementing plasmid. Calves that were infected with the wild type or the complemented spvR mutant rapidly developed severe diarrhea and became moribund. Calves that were infected with the spvR mutant showed little or no clinical signs of systemic salmonellosis and developed only mild diarrhea. The survival and growth of the wild-type strain and the spvR mutant were determined by using blood-derived bovine monocytes. Wild-type S. dublin survived and grew inside cells, while the spvR mutant did not proliferate. These results suggest that the spv genes of S. dublin promote enhanced intracellular proliferation in intestinal tissues and at extraintestinal sites in the natural host.