Rebecca L. Wilson

HilE Interacts with HilD and Negatively Regulates hilA Transcription and Expression of the Salmonella enterica Serovar Typhimurium Invasive Phenotype

ABSTRACT The ability of Salmonella enterica serovar Typhimurium to traverse the intestinal mucosa of a host is an important step in its ability to initiate gastrointestinal disease. The majority of the genes required for this invasive characteristic are encoded on Salmonella pathogenicity island 1 (SPI1), and their expression is controlled by the transcriptional activator HilA, a member of the OmpR/ToxR family of proteins. A variety of genes (hilC, hilD, fis, sirA/barA, csrAB, phoB, fadD, envZ/ompR, fliZ, hilE, ams, lon, pag, and hha) have been identified that exert positive or negative effects on hilA expression, although the mechanisms by which these gene products function remain relatively unclear. Recent work indicates that the small DNA-binding protein, Hha, has a significant role in repressing hilA transcription and the invasive phenotype, particularly in response to osmolarity signals. We have characterized the Salmonella-specific gene, hilE, and found that it plays an important regulatory role in hilA transcription and invasion gene expression. Mutation of hilE causes derepression of hilA transcription, and overexpression of hilE superrepresses hilA expression and the invasive phenotype. Bacterial two-hybrid experiments indicate that the HilE protein interacts with HilD, suggesting a possible mechanism for HilE negative regulation of hilA gene expression and the Salmonella invasive phenotype. Finally, we have found that the hilE gene resides on a region of the serovar Typhimurium chromosome that has many characteristics of a pathogenicity island.

Fis, a DNA nucleoid-associated protein, is involved in Salmonella typhimurium SPI-1 invasion gene expression

The ability of Salmonella enterica serovar Typhimurium to cause disease depends upon the co‐ordinated expression of many genes located around the Salmonella chromosome. Specific pathogenicity loci, termed Salmonella pathogenicity islands, have been shown to be crucial for the invasion and survival of Salmonella within host cells. Salmonella pathogenicity island 1 (SPI‐1) harbours the genes required for the stimulation of Salmonella uptake across the intestinal epithelia of the infected host. Regulation of SPI‐1 genes is complex, as invasion gene expression responds to a number of different signals, presumably signals similar to those found within the environment of the intestinal tract. As a result of our continued studies of SPI‐1 gene regulation, we have discovered that the nucleoid‐binding protein Fis plays a pivotal role in the expression of HilA and InvF, two activators of SPI‐1 genes. A S. typhimurium fis mutant demonstrates a two‐ to threefold reduction in hilA::Tn5lacZY and a 10‐fold reduction in invF::Tn5lacZY expression, as well as a 50‐fold decreased ability to invade HEp‐2 tissue culture cells. This decreased expression of hilA and invF resulted in an altered secreted invasion protein profile in the fis mutant. Furthermore, the virulence of a S. typhimurium fis mutant is attenuated 100‐fold when administered orally, but has wild‐type virulence when administered intraperitoneally. Expression of hilA::Tn5lacZY and invF::Tn5lacZY in the fis mutant could be restored by introducing a plasmid containing the S. typhimurium fis gene or a plasmid containing hilD, a gene encoding an AraC‐like regulator of Salmonella invasion genes.

Hha is a negative modulator of transcription of hilA, the Salmonella enterica serovar Typhimurium invasion gene transcriptional activator.

An early step in the establishment of Salmonella enterica serovar Typhimurium murine infection is the penetration of the intestinal mucosa of the small intestine. The majority of the genes responsible for the Salmonella invasive phenotype are encoded on Salmonella pathogenicity island 1, and their transcription is controlled by the hilA transcriptional activator. The expression of hilA is regulated by environmental signals including oxygen, osmolarity, pH, and growth phase such that the presence of any one suboptimal condition results in repression of hilA expression and the invasive phenotype. We have conducted a search for negative regulators of hilA by introduction of a Salmonella enterica serovar Typhimurium chromosomal DNA gene bank into a Salmonella enterica serovar Typhimurium hilA::Tn5lacZY reporter strain. This screen has identified the hha gene as a regulator that exerts a negative influence on hilA expression. Plasmid-encoded hha significantly reduces hilA::Tn5lacZY chromosomal expression, as well as expression of the invasion genes invF, prgH, and sipC. An hha null mutation results in substantial derepression of both chromosomally encoded and plasmid-encoded hilA::Tn5lacZY expression. Introduction of plasmid-encoded hha into strain SL1344 results in attenuation of invasion using in vitro and in vivo assays. Importantly, purified Hha protein was found to bind to a hilA DNA promoter fragment, suggesting that the regulatory activity of the Hha protein occurs at the hilA promoter. These data add detail to the developing model of the regulation of Salmonella invasion genes.

Salmonella enterica Serovars Gallinarum and Pullorum Expressing Salmonella enterica Serovar Typhimurium Type 1 Fimbriae Exhibit Increased Invasiveness for Mammalian Cells

ABSTRACT Salmonella enterica serovars Gallinarum and Pullorum are S. enterica biotypes that exhibit host specificity for poultry and aquatic birds and are not normally capable of causing disease in mammalian hosts. During their evolution toward host restriction serovars Gallinarum and Pullorum lost their ability to mediate mannose-sensitive hemagglutination (MSHA), a phenotype correlated with adherence to certain cell types. Because adherence is an essential requirement for invasion of cells by bacterial pathogens, we examined whether MHSA type 1 fimbriae would increase the ability of serovars Pullorum and Gallinarum to invade normally restrictive cells. Serovars Gallinarum and Pullorum expressing S. entericaserovar Typhimurium strain LT2 type 1 fimbriae exhibited a 10- to 20-fold increased ability to adhere to and a 20- to 60-fold increased invasion efficiency of the human epithelial HEp-2 cell line. Invasion was accompanied by extensive ruffling of the membranes of the HEp-2 cells. In a murine ligated ileal loop model, a 32% increase in the number of M-cell ruffles was seen when serovar Gallinarum expressed serovar Typhimurium type 1 fimbriae.

Identification of Listeria monocytogenes In Vivo-Induced Genes by Fluorescence-Activated Cell Sorting

ABSTRACT Listeria monocytogenes is a gram-positive, intracellular, food-borne pathogen capable of causing severe infections in immunocompromised or pregnant individuals, as well as numerous animal species. Genetic analysis of Listeriapathogenesis has identified several genes which are crucial for virulence. The transcription of most of these genes has been shown to be induced upon entry of Listeria into the host cell. To identify additional genes that are induced in vivo and may be required for L. monocytogenes pathogenesis, a fluorescence-activated cell-sorting technique was initiated. Random fragments of the L. monocytogenes chromosome were cloned into a plasmid carrying a promoterless green fluorescent protein (GFP) gene, and the plasmids were transformed into the L. monocytogenes actA mutant DP-L1942. Fluorescence-activated cell sorting (FACS) was used to isolate L. monocytogenes clones that exhibited increased GFP expression within macrophage-like J774 cells but had relatively low levels of GFP expression when the bacteria were extracellular. Using this strategy, several genes were identified, including actA, that exhibited such an expression profile. In-frame deletions of two of these genes, one encoding the putative L. monocytogenesuracil DNA glycosylase (ung) and one encoding a protein with homology to the Bacillus subtilis YhdP hemolysin-like protein, were constructed and introduced into the chromosome of wild-type L. monocytogenes 10403s. TheL. monocytogenes 10403s ung deletion mutant was not attenuated for virulence in mice, while theyhdP mutant exhibited a three- to sevenfold reduction in virulence.

CD8+ T cells in intracellular bacterial infections of mice

In the normal course of an immune response, both CD4+ and CD8+ T cells respond to each of the bacterial pathogens we have discussed and both responses may be required for the most potent immunity to infection. In this discussion, we have focused on the ability of these organisms to prime CD8+ T-cell responses in vivo and the ability of CD8+ T cells as sole mediators of acquired immunity, to protect against infection. It is clear that the vacuolar location of bacterial pathogens such as Salmonella or Mycobacteria does not prevent in vivo priming of CD8+ T-cell responses to these pathogens. However, vacuolar localization may affect the potency of CD8+ T-cell responses under experimental conditions that assess the capacity of CD8+ T cells as the sole mediators of acquired immunity. In the case of cytoplasmic L. monocytogenes, clear evidence exists that antigen-specific CD8+ T cells, in the absence of immune CD4+ T cells, can provide substantial acquired immunity to naive mice. Similar clear experimental results with Salmonella and Mycobacteria are lacking. Such results would provide stronger support for vaccines that elicit CD8+ T-cell responses to these vacuolar pathogens. Although our discussion has focused on only three specific organisms, we suggest that detection of an in vivo CD8+ T-cell response to a bacterial antigen does not ensure that the response will be protective against infection in a vaccine setting. In the case of Salmonella and Mycobacteria, this issue remains unresolved.

Transient expression of bacterial gene fragments in eukaryotic cells : implications for CD8+ T cell epitope analysis

CD8(+) T cells are potent effectors of acquired immunity against some viruses and intracellular bacterial pathogens. Antigens recognized by CD8(+) T cells are small, 8-9 amino acid peptides derived from proteins produced by the pathogen. These peptides are presented by MHC class I molecules on the surface of the infected cell. When characterizing the CD8(+) T cell response to a bacterial or viral pathogen, it is often necessary to express an antigenic protein in a eukaryotic host cell that is capable of processing and presenting peptide epitopes to antigen-specific CD8(+) T cells. We describe a system designed to transiently express bacterial polypeptides and MHC class I molecules in eukaryotic cells. Recognition of these peptide-MHC complexes stimulates TNF production by antigen-specific CD8(+) T cell lines. This system should be useful for analysis of CD8(+) T cell epitope-containing bacterial gene fragments when expression of the entire bacterial protein is detrimental to the eukaryotic cell, or when overexpression of the bacterial gene is detrimental to the bacterial cloning strain. Furthermore, this system can be used for the rapid mapping of CD8(+) T cell epitopes within a protein.