PrfA mediates specific binding of RNA polymerase of Listeria monocytogenes to PrfA-dependent virulence gene promoters resulting in a transcriptionally active complex.

There is accumulating evidence that the coordinate transcription of the virulence genes in Listeria monocytogenes constitutes a very complex regulation mechanism which might require other factors in addition to PrfA. We previously described an unknown proteinaceous component from crude bacterial cell extracts, which, together with PrfA, formed a specific complex (CI) in electrophoretic mobility shift assays (EMSA) with an hly promoter probe. Here we identify the RNA polymerase (RNAP) of L. monocytogenes as an essential component of the CI complex. Addition of purified RNAP plus PrfA to the hly promoter probe allowed reconstitution of a complex migrating at the same height as CI. By using EMSA and DNaseI footprint experiments it could be shown that PrfA leads to an enhanced and specific binding of RNAP. Transcriptional activity of RNAP in vitro, using the actA promoter, was strictly dependent on PrfA.

Functional similarities between the Listeria monocytogenes virulence regulator PrfA and cyclic AMP receptor protein: the PrfA* (Gly145Ser) mutation increases binding affinity for target DNA.

Most Listeria monocytogenes virulence genes are positively regulated by the PrfA protein, a transcription factor sharing sequence similarities with cyclic AMP (cAMP) receptor protein (CRP). Its coding gene, prfA, is regulated by PrfA itself via an autoregulatory loop mediated by the upstream PrfA-dependent plcA promoter. We have recently characterized prfA* mutants from L. monocytogenes which, as a result of a single amino acid substitution in PrfA, Gly145Ser, constitutively overexpress prfA and the genes of the PrfA virulence regulon. Here, we show that about 10 times more PrfA protein is produced in a prfA* strain than in the wild type. Thus, the phenotype of prfA* mutants is presumably due to the synthesis of a PrfA protein with higher promoter-activating activity (PrfA*), which keeps its intracellular levels constantly elevated by positive feedback. We investigated the interaction of PrfA and PrfA* (Gly145Ser) with target DNA. Gel retardation assays performed with a DNA fragment carrying the PrfA binding site of the plcA promoter demonstrated that the PrfA* mutant form is much more efficient than wild-type PrfA at forming specific DNA-protein complexes. In footprinting experiments, the two purified PrfA forms interacted with the same nucleotides at the target site, although the minimum amount required for protection was 6 to 7 times lower with PrfA*. These results show that the primary functional consequence of the Gly145Ser mutation is an increase in the affinity of PrfA for its target sequence. Interestingly, similar mutations at the equivalent position in CRP result in a transcriptionally active, CRP* mutant form which binds with high affinity to target DNA in the absence of the activating cofactor, cAMP. Our observations suggest that the structural similarities between PrfA and CRP are also functionally relevant and support a model in which the PrfA protein, like CRP, shifts from transcriptionally inactive to active conformations by interaction with a cofactor.

A novel PrfA-regulated chromosomal locus, which is specific for Listeria ivanovii, encodes two small, secreted internalins and contributes to virulence in mice.

Several large, cell wall-associated internalins and one small, secreted internalin (InlC) have been described previously in Listeria monocytogenes. Using degenerate primers derived from sequenced peptides of an L. ivanovii major secreted protein, we identified a new 4.25 kb internalin locus of L. ivanovii, termed i-inlFE. The two proteins encoded by this locus, i-InlE and i-InlF, belong to the group of small, secreted internalins. Southern blot analyses show that the i-inlFE locus does not occur in L. monocytogenes. These data also indicate that six genes encoding small, secreted internalins are present in L. ivanovii, in contrast to L. monocytogenes, in which inlC encodes the only small internalin. The mature i-InlE protein (198 amino acids) is secreted in large amounts into the brain-heart infusion (BHI) culture medium in the stationary growth phase. In minimum essential medium (MEM), which has been used previously to induce PrfA-dependent gene transcription, i-inlE mRNA and i-InlE protein are expressed at high levels. As shown by Northern blot analysis and primer extension, transcription of the tandemly arranged i-inlF and i-inlE genes is dependent on the virulence regulator PrfA, and characteristic palindromic sequences ('PrfA-boxes') were identified in the promoter regions of i-inlF and i-inlE. Non-polar i-inlE and i-inlF deletion mutants and an i-inlFE double deletion mutant were constructed and tested in the mouse infection model. After intravenous infection, all three mutants entirely failed to kill C57BL/6 mice even at high infectious doses of 109 bacteria per mouse, whereas the LD50 for the parental strain was determined as 4 x 107 bacteria per mouse. These data suggest an important role for i-InlE and i-InlF in L. ivanovii virulence.

Differential interaction of the transcription factor PrfA and the PrfA-activating factor (Paf) of Listeria monocytogenes with target sequences.

The interaction of the purified PrfA transcription factor with the regulatory sequences located upstream of the PrfA-dependent listeriolysin (hly) and internalin (inlA) genes was studied in the presence and in the absence of Paf (PrfA-activating factor)-containing extracts. It is shown that PrfA protein is able to bind, independently of additional factors, to a 109bp DNA fragment including the entire hly promoter sequence with the anticipated PrfA binding site ('PrfA-box'). PrfA alone, but not in combination with Paf, can also bind to a shorter target sequence of 28 bp comprising essentially the PrfA-box of the hly promoter. The addition of a Paf-containing extract does not lead to significant protein binding to these two hly target sequences in the absence of PrfA but converts the complex (CIII) consisting of PrfA and the 109 bp hly DNA fragment to a slower migrating PrfA-Paf-DNA complex (CI). Incubation of cell-free extracts of wild-type Listeria monocytogenes with the 109 bp DNA fragment leads to the formation of CI. The addition of polyclonal PrfA antibodies causes a supershift of CIII. Purified PrfA and PrfA-Paf also bind to a DNA fragment containing the PrfA-dependent promoter P2 of inlA, albeit at a lower rate when compared with the corresponding hly sequence. In contrast to the hly target DNA, the inlA promoter sequence efficiently binds Paf alone, and this Paf binding reduces that of PrfA and PrfA-Paf to the inlA target DNA. DNase I footprint experiments show that purified PrfA protects sequences of dyad symmetry previously proposed as PrfA binding sites in the hly and in the inlA promoter regions.

Sequence comparison of the chromosomal regions encompassing the internalin C genes (inlC) of Listeria monocytogenes and L. ivanovii.

We have recently cloned and characterized the inlC gene of Listeria monocytogenes which belongs to the listerial internalin multigene family and codes for a 30-kDa secreted protein containing five consecutive leucine-rich repeats. Here, we show that in L. monocytogenes inlC is located between the rplS gene (encoding the 50S ribosomal protein L19), and the infC gene (encoding the translation initiation factor 3). By direct and inverse polymerase chain reactions (PCR), we cloned a 5.4-kb region containing a homologous gene (termed i-inlC) from L. ivanovii, the other pathogenic member of the genus Listeria. In this microorganism, the i-inlC gene is preceded by another internalin gene, i-inlD, which seems to be specific for L. ivanovii, as this gene could not be detected in L. monocytogenes by Southern hybridization with an i-inlD gene probe. The i-inlD gene also encodes a small secretory internalin (i-InlD), which shares extended homology with (i-)InlC. Upstream of i-inlD are genes for 23S rRNA and 5S rRNA, and two tRNA genes [Asn-tDNA (GTT) and Thr-tDNA(GTT)]. The 3' terminus of the Thr-tRNA gene appears to be the site of an insertion of a genetic element including i-inlC and i-inlD. A putative transcriptional regulator gene, the product of which contains the TetR family signature, is located downstream of i-inlC. This chromosomal position of the two inlC genes on their respective chromosomes may be due to horizontal transfer of this gene. Transcription of i-inlC and i-inlD is strictly dependent on the transcriptional activator PrfA, which regulates transcription of most of the known virulence genes (including inlC) of L. monocytogenes and of L. ivanovii.

Specific binding of the Listeria monocytogenes transcriptional regulator PrfA to target sequences requires additional factor(s) and is influenced by iron.

The PrfA protein, which is a member of the Crp/Fnr family of prokaryotic transcription activators, regulates the virulence genes of Listeria monocytogenes. In this work, specific binding of PrfA to its target DNA was determined by electrophoretic mobility-shift assays (EMSAs) using cell-free extracts from the two L. monocytogenes strains EGD and NCTC 7973. PrfA-specific binding differs between the two strains, even when the concentration of PrfA was adjusted to similar levels. Both strains exhibited increased PrfA-specific binding after a shift into minimal essential medium (MEM) without showing a significant change in the amount of PrfA protein, relative to extracts from bacteria grown in brain-heart infusion (BHI). The purified PrfA protein from strain EGD produced in Escherichia coli did not exhibit specific binding to the target DNA but did so upon addition of PrfA-free extracts from various Listeria species and Bacillus subtilis. The observed activation of PrfA seems to be caused by a PrfA-activating factor (Paf), which is probably a protein since elevated temperature, but not RNase treatment, destroyed the activation potential of such PrfA-free extracts. Moreover, fractionation of these extracts by sucrose gradient centrifugation yielded the Paf activity in a fraction sedimenting at 3.2 S. Specific binding of PrfA-containing extracts from strain EGD to the hly and actA promoter sequences was strongly inhibited by iron, whereas that of extracts from strain NCTC 7973 was only slightly reduced. The iron effect seems to be mediated by Paf rather than by PrfA itself.

Differences in virulence and in expression of PrfA and PrfA-regulated virulence genes of Listeria monocytogenes strains belonging to serogroup 4.

Listeria monocytogenes isolates belonging to serogroup 4 (subtypes 4a, 4ab, 4b, 4c, 4d, and 4e) exhibit different levels of virulence in mice. Molecular studies indicate that in comparison with the control strain EGD (serotype 1/2a), these strains differ in the expression of the PrfA-regulated virulence genes, including prfA itself. Strains of serotypes 4c, 4d, 4e, and especially 4a show a low level of invasiveness in Caco-2 cells, which correlates in part with the low level of expression of the inlA gene. All serotypes reach the cytoplasm, at the latest, 2 h postinfection and become surrounded by polymerized actin within the next hour, but actin tail formation by serotype 4a, 4c, 4d, and 4e strains is drastically reduced. The actA genes in these serogroup 4 strains are expressed in minimum essential medium and within the phagocytic cell line J774. However, the amounts and (in part) the sizes of the ActA proteins in these strains differ under these conditions. The reduced actin tail formation by serotype 4a, 4c, 4d, and 4e strains may be due to the low level of in vivo expression of ActA. In addition, the loss of one repeat unit in the ActA proteins of serotype 4a and 4e strains may also contribute to the less efficient actin tail formation observed with these strains.