Gerald B. Koudelka

Shiga Toxin: Expression, Distribution, and Its Role in the Environment

In this review, we highlight recent work that has increased our understanding of the production and distribution of Shiga toxin in the environment. Specifically, we review studies that offer an expanded view of environmental reservoirs for Shiga toxin producing microbes in terrestrial and aquatic ecosystems. We then relate the abundance of Shiga toxin in the environment to work that demonstrates that the genetic mechanisms underlying the production of Shiga toxin genes are modified and embellished beyond the classical microbial gene regulatory paradigms in a manner that apparently “fine tunes” the trigger to modulate the amount of toxin produced. Last, we highlight several recent studies examining microbe/protist interactions that postulate an answer to the outstanding question of why microbes might harbor and express Shiga toxin genes in the environment.

Effect of Salt Shock on Stability of λimm434 Lysogens

The affinities of the bacteriophage 434 repressor for its various binding sites depend on the type and/or concentration of monovalent cations. The ability of bacteriophage 434 repressor to govern the lysis-lysogeny decision depends on the DNA binding activities of the phages cI repressor protein. We wished to determine whether changes in the intracellular ionic environment influence the lysis-lysogeny decision of the bacteriophage lambda(imm434). Our findings show that the ionic composition within bacterial cells varies with the cation concentration in the growth media. When lambda(imm434) lysogens were grown to mid-log or stationary phase and subsequently incubated in media with increasing monovalent salt concentrations, we observed a salt concentration-dependent increase in the frequency of bacteriophage spontaneous induction. We also found that the frequency of spontaneous induction varied with the type of monovalent cation in the medium. The salt-dependent increase in phage production was unaffected by a recA mutation. These findings indicate that the salt-dependent increase in phage production is not caused by activation of the SOS pathway. Instead, our evidence suggests that salt stress induces this lysogenic bacteriophage by interfering with 434 repressor-DNA interactions. We speculate that the salt-dependent increase in spontaneous induction is due to a direct effect on the repressors affinity for DNA. Regardless of the precise mechanism, our findings demonstrate that salt stress can regulate the phage lysis-lysogeny switch.

Indirect readout of DNA sequence by proteins: the roles of DNA sequence-dependent intrinsic and extrinsic forces.

Publisher Summary This chapter discusses the recent insights into how DNA sequence affects DNA structure and how solvent-mediated alterations in DNA structure may play a role in gene regulation. The stability and sequence specificity of many protein–DNA complexes is remarkably dependent on the sequences of bases that are not in contact with protein. In indirect readout, the stability and specificity of a protein–DNA complex is regulated by the sequence of bases not in contact with the protein. These noncontacted bases can inhibit or prevent the contacted DNA from being properly juxtaposed with protein groups. DNA sequence-dependent differences in the structure and flexibility of noncontacted bases lead to alterations in the strength and ease of forming protein–DNA contacts. Hence, noncontacted bases affect protein–DNA complex formation via sequence-dependent differences in their structure and flexibility. The sequence dependence of the effect of salt on a proteins affinity for DNA implies that for a given regulatory protein, the genes it controls can be differentially regulated by changes in salt type and concentration. An increasing number of examples exist of gene regulatory proteins whose affinity for DNA-binding sites are dependent on cation composition. Thus, cations may have a larger role in differentially regulating gene expression than has thus far been recognized.

Entry and Killing of Tetrahymena thermophila by Bacterially Produced Shiga Toxin

ABSTRACT Phage-encoded Shiga toxin (Stx) acts as a bacterial defense against the eukaryotic predator Tetrahymena thermophila. It is unknown how Stx enters Tetrahymena protozoa or how it kills them. Tetrahymena protozoa are phagocytotic; hence, Stx could gain entry to the cytoplasm through the oral apparatus or via endocytosis. We find that Stx2 can kill T. thermophila protozoa that lack an oral apparatus, indicating that Stx2 can enter these cells via endocytosis. As opposed to the lack of effect on mammalian phagocytes, Stx2 produced by bacteria encapsulated within phagocytotic vesicles is also capable of killing Tetrahymena. Addition of an excess of the carbohydrate binding subunits of Stx2 (StxB) and/or ricin (ricin B) blocks Stx2 cytotoxicity. Thus, regardless of whether Stx2 enters the cytoplasm by endocytosis or from the phagocytotic vesicle, this transport is mediated by a putative glycoconjugate receptor. Bacteriophage-mediated lysis of Stx-encoding bacteria is necessary for Stx toxicity in Tetrahymena; i.e., toxin released as a consequence of digestion of bacteria by Tetrahymena is harmless to the cell. This finding provides a rationale as to why the genes encoding Stx are found almost exclusively on bacteriophages; Stx must be released from the bacteria prior to the digestion of the cell, or it will not be able to exert its cytotoxic effect. It also suggests a reason why other bacterial exotoxins are also found only on temperate bacteriophages. Incubation of Tetrahymena with purified Stx2 decreases total protein synthesis. This finding indicates that, similar to mammalian cells, Stx2 kills Tetrahymena by inactivating its ribosomes. IMPORTANCE Tetrahymena is a bacterial predator and a model for mammalian phagocytosis and intracellular vesicular trafficking. Phage-encoded exotoxins apparently have evolved for the purpose of bacterial antipredator defense. These exotoxins kill mammalian cells by inactivating universally conserved factors and/or pathways. Tetrahymena and susceptible mammalian cells are killed when exposed to bacteriophage-encoded Shiga toxin (Stx). Stx toxicity in mammalian cells requires Stx binding to the globotriaosyl ceramide (Gb3) receptor, followed by receptor-mediated endocytosis (RME). We show that, similar to mammalian cells, internalized Stx inhibits protein synthesis in Tetrahymena. Although Tetrahymena lacks Gb3, our results suggest that the cytotoxic effect of Stx on Tetrahymena is apparently mediated by a receptor, thereby arguing for the existence of RME in Tetrahymena. As opposed to the case with mammalian phagocytes, Stx produced by bacteria inside Tetrahymena is cytotoxic, suggesting that these cells may represent a “missing link” between unicellular eukaryotic bacterial predators and phagocytotic mammalian cells. Tetrahymena is a bacterial predator and a model for mammalian phagocytosis and intracellular vesicular trafficking. Phage-encoded exotoxins apparently have evolved for the purpose of bacterial antipredator defense. These exotoxins kill mammalian cells by inactivating universally conserved factors and/or pathways. Tetrahymena and susceptible mammalian cells are killed when exposed to bacteriophage-encoded Shiga toxin (Stx). Stx toxicity in mammalian cells requires Stx binding to the globotriaosyl ceramide (Gb3) receptor, followed by receptor-mediated endocytosis (RME). We show that, similar to mammalian cells, internalized Stx inhibits protein synthesis in Tetrahymena. Although Tetrahymena lacks Gb3, our results suggest that the cytotoxic effect of Stx on Tetrahymena is apparently mediated by a receptor, thereby arguing for the existence of RME in Tetrahymena. As opposed to the case with mammalian phagocytes, Stx produced by bacteria inside Tetrahymena is cytotoxic, suggesting that these cells may represent a “missing link” between unicellular eukaryotic bacterial predators and phagocytotic mammalian cells.

Function-Based Selection and Characterization of Base-Pair Polymorphisms in a Promoter of Escherichia coli RNA Polymerase-ς70

We performed two sets of in vitro selections to dissect the role of the -10 base sequence in determining the rate and efficiency with which Escherichia coli RNA polymerase-sigma(70) forms stable complexes with a promoter. We identified sequences that (i) rapidly form heparin-resistant complexes with RNA polymerase or (ii) form heparin-resistant complexes at very low RNA polymerase concentrations. The sequences selected under the two conditions differ from each other and from the consensus -10 sequence. The selected promoters have the expected enhanced binding and kinetic properties and are functionally better than the consensus promoter sequence in directing RNA synthesis in vitro. Detailed analysis of the selected promoter functions shows that each step in this multistep pathway may have different sequence requirements, meaning that the sequence of a strong promoter does not contain the optimal sequence for each step but instead is a compromise sequence that allows all steps to proceed with minimal constraint.

Mutually exclusive utilization of P(R) and P(RM) promoters in bacteriophage 434 O(R).

Establishment and maintenance of a lysogen of the lambdoid bacteriophage 434 require that the 434 repressor both activate transcription from the P(RM) promoter and repress transcription from the divergent P(R) promoter. Several lines of evidence indicate that the 434 repressor activates initiation of P(RM) transcription by occupying a binding site adjacent to the P(RM) promoter and directly contacting RNA polymerase. The overlapping architecture of the P(RM) and P(R) promoters suggests that an RNA polymerase bound at P(R) may repress P(RM) transcription initiation. Hence, part of the stimulatory effect of the 434 repressor may be relief of interference between RNA polymerase binding to the P(RM) promoter and to the P(R) promoter. Consistent with this proposal, we show that the repressor cannot activate P(RM) transcription if RNA polymerase binds at P(R) prior to addition of the 434 repressor. However, unlike the findings with the related lambda phage, formation of RNA polymerase promoter complexes at P(RM) and at P(R) apparently are mutually exclusive. We find that the RNA polymerase-mediated inhibition of repressor-stimulated P(RM) transcription requires the presence of an open complex at P(R). Taken together, these results indicate that establishment of an open complex at P(R) directly prevents formation of an RNA polymerase-P(RM) complex.

DNA-based Positive Control Mutants in the Binding Site Sequence of 434 Repressor

As detected by chemical nuclease treatments, the conformation of the 434 repressor-DNA complex depends on the sequence of the bound DNA (Bell, A. C., and Koudelka, G. B. (1993)J. Mol. Biol. 234, 542–553). We show here that these DNA sequence-dependent conformational changes alter the efficiency with which the repressor activates transcription from 434 PRM. Several lines of evidence suggest that binding site sequence affects the repressor’s ability to activate transcription by altering the accessibility of the activation surface on the repressor to RNA polymerase. The results presented here show that in addition to affecting transcription by altering the overall binding affinity of protein for DNA, DNA sequence may also modulate the activity of the DNA-bound protein.

DNA-based Loss of Specificity Mutations EFFECTS OF DNA SEQUENCE ON THE CONTACTED AND NON-CONTACTED BASE PREFERENCES OF BACTERIOPHAGE P22 REPRESSOR

Although the two central bases of the P22 operator are not contacted by the P22 repressor, changes in these bases alter the affinity of operator for repressor. Previous studies (Wu, L., and Koudelka, G. B. (1993) J. Biol. Chem. 268, 18975-18981) show that the structure of the P22 repressor-operator complex varies with central base sequence. Here we show that central base sequence composition affects the strength of two, and likely all, specific amino acid-base pair contacts between synthetic P22 operators and P22 repressor. However, altering a specific protein-DNA contact via a loss-of-contact mutation in repressor results in a loss of specificity at only one contacted position. Thus, only changing the sequence of non-contacted bases affects repressors global base specificity. The observed effects of ionic concentration on the affinities of various operators for repressor and the DNase I patterns of protein complexes with these binding sites indicate certain central base sequences facilitate optimal juxtaposition of repressor with its contacted bases, while others prevent it. The existence of different structural forms of the repressor-operator complexes explains how the relative energetic importance of specific amino acid-base pair edge contacts is modulated.

Recognition of nonconserved bases in the P22 operator by P22 repressor requires specific interactions between repressor and conserved bases.

The ability of P22 repressor protein to distinguish between the six naturally occurring operator binding sites is critically important in determining whether the bacteriophage chooses to grow lytically or lysogenically. We have shown that changes in the highly conserved bases at P22 operator positions 3, 5, 6, and 7 prevent specific binding of P22 repressor. Moreover, studies of mutant proteins identified the three repressor amino acids that directly contact these conserved bases. The pattern of operator sequence conservation permits these direct amino acid-base pair interactions to occur in all except one of the 12 operator half-sites in the phage chromosome. Therefore, repressor differential affinity for these sites cannot be due to these highly conserved base pair-amino acid interactions. Our binding studies show that the nonconserved bases at positions 2 and 4 also play an important role in determining the relative affinity of the naturally occurring P22 operators for P22 repressor. Our data indicate that the direct contacts between the three solvent-exposed amino acids and the conserved bases in the binding site lock these amino acids in place, forming a scaffold allowing the rest of the amino acids side chains to form weaker interactions with the nonconserved bases in the binding site.

The Microcosm Mediates the Persistence of Shiga Toxin-Producing Escherichia coli in Freshwater Ecosystems

ABSTRACT Water is a major route for infection of humans by exotoxin-producing bacteria, including Shiga toxin-producing Escherichia coli (STEC). While STEC has the potential to be present in nearly every type of water source, its distribution is sporadic, and an understanding of factors that govern its emergence and persistence within water is lacking. In this study, we examined the influence of microbe content on STEC persistence in freshwater. We found that depletion of microbes in the water leads to a considerable increase in the persistence of STEC, an effect that can be mitigated by adding grazing protists to the water. STEC strains appear to be more resistant to the impact of grazing protists than E. coli strains that lack the Shiga toxin (stx) gene. Our results demonstrate that the microcosm can dramatically influence the persistence of STEC in aquatic ecosystems and that the overall impact by microbes on STEC strains is fundamentally different from that of non-STEC strains of bacteria. Overall, these results provide insight into why STEC and possibly other exotoxin-producing bacterial pathogens display such variability in abundance, distribution, and persistence in aquatic ecosystems.