A prophage encoded ribosomal RNA methyltransferase regulates the virulence of Shiga-toxin-producing Escherichia coli (STEC).

Shiga toxin (Stx) released by Shiga toxin producing Escherichia coli (STEC) causes life-threatening illness. Its production and release require induction of Stx-encoding prophage resident within the STEC genome. We identified two different STEC strains, PA2 and PA8, bearing Stx-encoding prophage whose sequences primarily differ by the position of an IS629 insertion element, yet differ in their abilities to kill eukaryotic cells and whose prophages differ in their spontaneous induction frequencies. The IS629 element in ϕPA2, disrupts an ORF predicted to encode a DNA adenine methyltransferase, whereas in ϕPA8, this element lies in an intergenic region. Introducing a plasmid expressing the methyltransferase gene product into ϕPA2 bearing-strains increases both the prophage spontaneous induction frequency and virulence to those exhibited by ϕPA8 bearing-strains. However, a plasmid bearing mutations predicted to disrupt the putative active site of the methyltransferase does not complement either of these defects. When complexed with a second protein, the methyltransferase holoenzyme preferentially uses 16S rRNA as a substrate. The second subunit is responsible for directing the preferential methylation of rRNA. Together these findings reveal a previously unrecognized role for rRNA methylation in regulating induction of Stx-encoding prophage.

The Oligosaccharide Region of LPS Governs Predation of E. coli by the Bacterivorous Protist, Acanthamoeba castellanii.

Protozoan predation is a major cause of bacterial mortality. The first step of predation for phagocytic amoebae is the recognition of their prey. Lipopolysaccharide (LPS) is a major component of Gram-negative bacteria and is only present on the outer leaflet of the outer membrane lipid bilayer. LPS consists of three distinct regions: lipid A, an oligosaccharide core, and O-polysaccharide. Previous research in our lab determined that the oligosaccharide (OS) region of LPS mediates the recognition and internalization of Escherichia coli by Acanthamoeba castellanii. The oligosaccharide region is conceptually divided into the inner core and outer core. The LPS of any given E. coli strain contains only one of five different OS structures: K-12 and R1 to R4. All OSs contain the same inner core sugars but different outer core sugars. Here, we show that the Kdo2 moiety of the inner core is necessary and sufficient for E. coli recognition and internalization by A. castellanii. We also show that the precise composition of the variable outer core OS region modulates the efficiency with which A. castellanii consumes bacteria. The latter finding indicates that outer core OS composition plays a role in bacterial defense against phagocytic predators. IMPORTANCE Rather than being transmitted from host to host, most opportunistic bacterial pathogens reside in the environment for significant amounts of time. Protist predation is a major cause of bacterial mortality. To enhance their survival in the environment, bacteria have evolved various defense strategies such as filamentation, increased motility, biofilm formation, toxin release, and modification of cell wall structure; strategies which also enhance their virulence to humans. This work shows that the major component of the bacterial cell wall, LPS, also known as bacterial endotoxin, is a "dual use" factor, regulating amoeba predation of bacteria in addition to its well-known role as a human virulence factor. Both these functions are governed by the same parts of LPS. Thus, the structure and composition of this "dual use" factor likely evolved as a response to constant voracious protist grazing pressure in the environment, rather than during short-term infections of human and animals.

Small molecule MMRi62 targets MDM4 for degradation and induces leukemic cell apoptosis regardless of p53 status.

MDM2 and MDM4 proteins are key negative regulators of tumor suppressor p53. MDM2 and MDM4 interact via their RING domains and form a heterodimer polyubiquitin E3 ligase essential for p53 degradation. MDM4 also forms heterodimer E3 ligases with MDM2 isoforms that lack p53-binding domains, which regulate p53 and MDM4 stability. We are working to identify small-molecule inhibitors targeting the RING domain of MDM2-MDM4 (MMRi) that can inactivate the total oncogenic activity of MDM2-MDM4 heterodimers. Here, we describe the identification and characterization of MMRi62 as an MDM4-degrader and apoptosis inducer in leukemia cells. Biochemically, in our experiments, MMRi62 bound to preformed RING domain heterodimers altered the substrate preference toward MDM4 ubiquitination and promoted MDM2-dependent MDM4 degradation in cells. This MDM4-degrader activity of MMRi62 was found to be associated with potent apoptosis induction in leukemia cells. Interestingly, MMRi62 effectively induced apoptosis in p53 mutant, multidrug-resistant leukemia cells and patient samples in addition to p53 wild-type cells. In contrast, MMRi67 as a RING heterodimer disruptor and an enzymatic inhibitor of the MDM2-MDM4 E3 complex lacked MDM4-degrader activity and failed to induce apoptosis in these cells. In summary, this study identifies MMRi62 as a novel MDM2-MDM4-targeting agent and suggests that small molecules capable of promoting MDM4 degradation may be a viable new approach to killing leukemia cells bearing non-functional p53 by apoptosis.

Carriage of Shiga toxin phage profoundly affects Escherichia coli gene expression and carbon source utilization.

BACKGROUND: Enterohemorrhagic Escherichia coli (E. coli) are intestinal pathogenic bacteria that cause life-threatening disease in humans. Their cardinal virulence factor is Shiga toxin (Stx), which is encoded on lambdoid phages integrated in the chromosome. Stx phages can infect and lysogenize susceptible bacteria, thus either increasing the virulence of already pathogenic bacterial hosts or transforming commensal strains into potential pathogens. There is increasing evidence that Stx phage-encoded factors adaptively regulate bacterial host gene expression. Here, we investigated the effects of Stx phage carriage in E. coli K-12 strain MG1655. We compared the transcriptome and phenotype of naive MG1655 and two lysogens carrying closely related Stx2a phages: ϕO104 from the exceptionally pathogenic 2011 E. coli O104:H4 outbreak strain and ϕPA8 from an E. coli O157:H7 isolate. RESULTS: Analysis of quantitative RNA sequencing results showed that, in comparison to naive MG1655, genes involved in mixed acid fermentation were upregulated, while genes encoding NADH dehydrogenase I, TCA cycle enzymes and proteins involved in the transport and assimilation of carbon sources were downregulated in MG1655::ϕO104 and MG1655::ϕPA8. The majority of the changes in gene expression were found associated with the corresponding phenotypes. Notably, the Stx2a phage lysogens displayed moderate to severe growth defects in minimal medium supplemented with single carbon sources, e.g. galactose, ribose, L-lactate. In addition, in phenotype microarray assays, the Stx2a phage lysogens were characterized by a significant decrease in the cell respiration with gluconeogenic substrates such as amino acids, nucleosides, carboxylic and dicarboxylic acids. In contrast, MG1655::ϕO104 and MG1655::ϕPA8 displayed enhanced respiration with several sugar components of the intestinal mucus, e.g. arabinose, fucose, N-acetyl-D-glucosamine. We also found that prophage-encoded factors distinct from CI and Cro were responsible for the carbon utilization phenotypes of the Stx2a phage lysogens. CONCLUSIONS: Our study reveals a profound impact of the Stx phage carriage on E. coli carbon source utilization. The Stx2a prophage appears to reprogram the carbon metabolism of its bacterial host by turning down aerobic metabolism in favour of mixed acid fermentation.

Cheating, facilitation and cooperation regulate the effectiveness of phage-encoded exotoxins as antipredator molecules.

Temperate phage encoded Shiga toxin (Stx) kills the bacterivorous predator, Tetrahymena thermophila, providing Stx+ Escherichia coli with a survival advantage over Stx- cells. Although bacterial death accompanies Stx release, since bacteria grow clonally the fitness benefits of predator killing accrue to the kin of the sacrificed organism, meaning Stx-mediated protist killing is a form of self-destructive cooperation. We show here that the fitness benefits of Stx production are not restricted to the kin of the phage-encoding bacteria. Instead, nearby "free loading" bacteria, irrespective of their genotype, also reap the benefit of Stx-mediated predator killing. This finding indicates that the phage-borne Stx exotoxin behaves as a public good. Stx is encoded by a mobile phage. We find that Stx-encoding phage can use susceptible bacteria in the population as surrogates to enhance toxin and phage production. Moreover, our findings also demonstrate that engulfment and concentration of Stx-encoding and susceptible Stx- bacteria in the Tetrahymena phagosome enhances the transfer of Stx-encoding temperate phage from the host to the susceptible bacteria. This transfer increases the population of cooperating bacteria within the community. Since these bacteria now encode Stx, the predation-stimulated increase in phage transfer increases the population of toxin encoding bacteria in the environment.

Evolution of STEC virulence: Insights from the antipredator activities of Shiga toxin producing E. coli.

Shiga toxin-producing Escherichia coli (STEC) are a diverse group of strains that are implicated in over 270,000 cases of human illness annually in the United States alone. Shiga toxin (Stx), encoded by a resident temperate lambdoid bacteriophage, is the main STEC virulence factor. Although the population structure of E. coli O157:H7, the most common disease-causing STEC strain, is highly homogenous, the range of clinical illness caused by this strain varies by dramatically outbreak, suggesting that human virulence is evolving. However, the factors governing this variation in disease severity are poorly understood. STEC evolved from an O55:H7-like progenitor into a human pathogen. In addition to causing human disease, Stx released from STEC kill bacterivorous protist predators and enhance bacterial survival in the face of protist predation. Cattle are the primary reservoir for STEC and protists and bacteria occur together within the ruminant intestinal tract. Cattle associated STEC are not highly pathogenic to humans. These observations suggest that disease causing STEC strains evolved from cattle-associated "antipredator" STEC strains. To test this idea and to gain insight into the features that govern the evolution of STEC from a commensal strain of ruminants strain to virulent human pathogen, we compared the predation resistance of STEC strains isolated from asymptomatic infected cows and human patients. We find that STEC O157:H7 progenitor lineages and clades are more effective than human associated ones at killing the types of protist predators. In addition, our results indicate that the presence of Stx2c-containing bacteriophage is associated with more efficient amoeba killing. Also, these phage apparently also encode Q21-like version of the Q antitermination protein, the protein that controls expression of Stx.

Molecular Mechanisms Governing "Hair-Trigger" Induction of Shiga Toxin-Encoding Prophages.

Shiga toxin (Stx)-encoding E. coli (STEC) strains are responsible for sporadic outbreaks of food poisoning dating to 1982, when the first STEC strain, E. coli O157:H7, was isolated. Regardless of STEC serotype, the primary symptoms of STEC infections are caused by Stx that is synthesized from genes resident on lambdoid prophage present in STEC. Despite similar etiology, the severity of STEC-mediated disease varies by outbreak. However, it is unclear what modulates the severity of STEC-mediated disease. Stx production and release is controlled by lytic growth of the Stx-encoding bacteriophage, which in turn, is controlled by the phage repressor. Here, we confirm our earlier suggestion that the higher spontaneous induction frequency of Stx-encoding prophage is a consequence, in part, of lower intracellular repressor levels in STEC strains versus non-STEC strains. We also show that this lowered intracellular repressor concentration is a consequence of the utilization of alternative binding/regulatory strategies by the phage repressor. We suggest that a higher spontaneous induction frequency would lead to increased virulence.

Tetrahymena phagocytic vesicles as ecological micro-niches of phage transfer.

The microbial communities in natural environments such as soil, pond water, or animal rumens are composed of a diverse mixture of bacteria and protozoa including ciliates or flagellates. In such microbiomes, a major source of bacterial mortality is grazing by phagocytic protists. Many protists are omnivorous heterotrophs, feeding on a range of different bacterial species. Due to this indiscriminate feeding, different bacterial species can assemble together in the same phagocytic vesicles where they can potentially exchange genetic material. Here we show that Tetrahymena thermophila imports and accumulates phage donor and recipient bacterial strains in its phagocytic vesicles and that under laboratory conditions the ingested bacteria remain viable for ≥2 h. Prophages in the ingested bacteria induce immediately after ingestion, and the released phages are concentrated in the phagocytic vesicles of the ciliate. These phages retain their ability to infect phage-susceptible bacterial strains. As a consequence of being confined within the phagosome, the frequency of lysogen formation in these vesicles increases 6-fold as compared with the bulk solution. Collectively, these observations suggest that T. thermophila aids in dissemination of bacteriophages by accumulating susceptible bacteria and phages in their phagocytic vesicles.

Mechanisms that Determine the Differential Stability of Stx⁺ and Stx(-) Lysogens.

Phages 933W, BAA2326, 434, and λ are evolutionarily-related temperate lambdoid phages that infect Escherichia coli. Although these are highly-similar phages, BAA2326 and 933W naturally encode Shiga toxin 2 (Stx⁺), but phage 434 and λ do not (Stx(-)). Previous reports suggest that the 933W Stx⁺ prophage forms less stable lysogens in E. coli than does the Stx(-) prophages λ, P22, and 434. The higher spontaneous induction frequency of the Stx⁺ prophage may be correlated with both virulence and dispersion of the Stx2-encoding phage. Here, we examined the hypothesis that lysogen instability is a common feature of Stx⁺ prophages. We found in both the absence and presence of prophage inducers (DNA damaging agents, salts), the Stx⁺ prophages induce at higher frequencies than do Stx(-) prophages. The observed instability of Stx⁺ prophages does not appear to be the result of any differences in phage development properties between Stx⁺ and Stx(-) phages. Our results indicate that differential stability of Stx⁺ and Stx(-) prophages results from both RecA-dependent and RecA-independent effects on the intracellular concentration of the respective cI repressors.

Determinants that govern the recognition and uptake of Escherichia coli O157 : H7 by Acanthamoeba castellanii.

Predation by phagocytic predators is a major source of bacterial mortality. The first steps in protozoan predation are recognition and consumption of their bacterial prey. However, the precise mechanisms governing prey recognition and phagocytosis by protists, and the identities of the molecular and cellular factors involved in these processes are, as yet, ill-characterized. Here, we show that that the ability of the phagocytic bacterivorous amoebae, Acanthamoeba castellanii, to recognize and internalize Escherichia coli, a bacterial prey, varies with LPS structure and composition. The presence of an O-antigen carbohydrate is not required for uptake of E. coli by A. castellanii. However, O1-antigen types, not O157 O-antigen types, inhibit recognition and uptake of bacteria by amoeba. This finding implies that O-antigen may function as an antipredator defence molecule. Recognition and uptake of E. coli by A. castellanii is mediated by the interaction of mannose-binding protein located on amoebae's surface with LPS carbohydrate. Phagocytic mammalian cells also use mannose-binding lectins to recognize and/or mediate phagocytosis of E. coli. Nonetheless, A. castellanii's mannose binding protein apparently displays no sequence similarity with any known metazoan mannose binding protein. Hence, the similarity in bacterial recognition mechanisms of amoebae and mammalian phagocytes may be a result of convergent evolution.

A Role for Autoinhibition in Preventing Dimerization of the Transcription Factor ETS1.

ETS1 is the archetype of the ETS transcription factor (TF) family. ETS TFs share a DNA-binding domain, the ETS domain. All ETS TFs recognize a core GGA(A/T) binding site, and thus ETS TFs are found to redundantly regulate the same genes. However, each ETS TF has unique targets as well. One prevailing hypotheses explaining this duality is that protein-protein interactions, including homodimerization, allow each ETS TF to display distinct behavior. The behavior of ETS1 is further regulated by autoinhibition. Autoinhibition apparently modulates ETS1 DNA binding affinity, but the mechanism of this inhibition is not completely understood. We sought to characterize the relationship between DNA binding and ETS1 homodimer formation. We find that ETS1 interrogates DNA and forms dimers even when the DNA does not contain an ETS recognition sequence. Mutational studies also link nonspecific DNA backbone contacts with dimer formation, in addition to providing a new role for the recognition helix of ETS1 in maintaining the autoinhibited state. Finally, in showing that residues in the DNA recognition helix affect autoinhibition, we define a new function of ETS1 autoinhibition: maintenance of a monomeric state in the absence of DNA. The conservation of relevant amino acid residues across all ETS TFs indicates that the mechanisms of nonspecific DNA interrogation and protein oligomer formation elucidated here may be common to all ETS proteins that autoinhibit.

Specific minor groove solvation is a crucial determinant of DNA binding site recognition.

The DNA sequence preferences of nearly all sequence specific DNA binding proteins are influenced by the identities of bases that are not directly contacted by protein. Discrimination between non-contacted base sequences is commonly based on the differential abilities of DNA sequences to allow narrowing of the DNA minor groove. However, the factors that govern the propensity of minor groove narrowing are not completely understood. Here we show that the differential abilities of various DNA sequences to support formation of a highly ordered and stable minor groove solvation network are a key determinant of non-contacted base recognition by a sequence-specific binding protein. In addition, disrupting the solvent network in the non-contacted region of the binding site alters the protein's ability to recognize contacted base sequences at positions 5-6 bases away. This observation suggests that DNA solvent interactions link contacted and non-contacted base recognition by the protein.

The Trojan Horse of the microbiological arms race: phage-encoded toxins as a defence against eukaryotic predators.

Phage-encoded Shiga toxin (Stx) acts as a bacterial defence against the eukaryotic predator Tetrahymena. To function as an effective bacterial anti-predator defence, Stx must kill a broad spectrum of predators. Consistent with that assertion, we show here that bacterially encoded Stx efficiently kills the bacteriovore Acanthamoeba castellanii in co-culture. We also show that, in addition to Stx, the phage-encoded exotoxin, diphtheria toxin (Dtx) expressed by Corynebacterium diphtheriae also can function as part of an anti-predator strategy; it kills Acanthamoeba in co-culture. Interestingly, only exotoxins produced by bacteria internalized by the Acanthamoeba predator are cytolethal; the presence of purified Dtx or Stx in culture medium has no effect on predator viability. This finding is consistent with our results indicating that intoxication of Acanthamoeba by these exotoxins does not require a receptor. Thus bacteria, in the disguise of a food source, function as a 'Trojan Horse', carrying genes encoding an exotoxin into target organisms. This 'Trojan Horse' mechanism of exotoxin delivery into predator cells allows intoxication of predators that lack a cell surface receptor for the particular toxin, allowing bacteria-bearing exotoxins to kill a broader spectrum of predators, increasing the fitness of the otherwise 'defenceless' prey bacteria.

The microcosm mediates the persistence of shiga toxin-producing Escherichia coli in freshwater ecosystems.

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.

Bacteriophage 434 Hex protein prevents recA-mediated repressor autocleavage.

In a λ(imm434) lysogen, two proteins are expressed from the integrated prophage. Both are encoded by the same mRNA whose transcription initiates at the P(RM) promoter. One protein is the 434 repressor, needed for the establishment and maintenance of lysogeny. The other is Hex which is translated from an open reading frame that apparently partially overlaps the 434 repressor coding region. In the wild type host, disruption of the gene encoding Hex destabilizes λ(imm434) lysogens. However, the hex mutation has no effect on lysogen stability in a recA(-) host. These observations suggest that Hex functions by modulating the ability of RecA to stimulate 434 repressor autocleavage. We tested this hypothesis by identifying and purifying Hex to determine if this protein inhibited RecA­stimulated autocleavage of 434 repressor in vitro. Our results show that in vitro a fragment of Hex prevents RecA-stimulated autocleavage of 434 repressor, as well as the repressors of the closely related phage P22. Surprisingly, Hex does not prevent RecA­stimulated autocleavage of phage lambda repressor, nor the E. coli LexA repressor.

Indirect readout of DNA sequence by p22 repressor: roles of DNA and protein functional groups in modulating DNA conformation.

The repressor of bacteriophage P22 (P22R) discriminates between its various DNA binding sites by sensing the identity of non-contacted base pairs at the center of its binding site. The "indirect readout" of these non-contacted bases is apparently based on DNA's sequence-dependent conformational preferences. The structures of P22R-DNA complexes indicate that the non-contacted base pairs at the center of the binding site are in the B' state. This finding suggests that indirect readout and therefore binding site discrimination depend on P22R's ability to either sense and/or impose the B' state on the non-contacted bases of its binding sites. We show here that the affinity of binding sites for P22R depends on the tendency of the central bases to assume the B'-DNA state. Furthermore, we identify functional groups in the minor groove of the non-contacted bases as the essential modulators of indirect readout by P22R. In P22R-DNA complexes, the negatively charged E44 and E48 residues are provocatively positioned near the negatively charged DNA phosphates of the non-contacted nucleotides. The close proximity of the negatively charged groups on protein and DNA suggests that electrostatics may play a key role in the indirect readout process. Changing either of two negatively charged residues to uncharged residues eliminates the ability of P22R to impose structural changes on DNA and to recognize non-contacted base sequence. These findings suggest that these negatively charged amino acids function to force the P22R-bound DNA into the B' state and therefore play a key role in indirect readout by P22R.

Entry and killing of Tetrahymena thermophila by bacterially produced Shiga toxin.

UNLABELLED: 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.

Determinants of bacteriophage 933W repressor DNA binding specificity.

We reported previously that 933W repressor apparently does not cooperatively bind to adjacent sites on DNA and that the relative affinities of 933W repressor for its operators differ significantly from that of any other lambdoid bacteriophage. These findings indicate that the operational details of the lysis-lysogeny switch of bacteriophage 933W are unique among lambdoid bacteriophages. Since the functioning of the lysis-lysogeny switch in 933W bacteriophage uniquely and solely depends on the order of preference of 933W repressor for its operators, we examined the details of how 933W repressor recognizes its DNA sites. To identify the specificity determinants, we first created a molecular model of the 933W repressor-DNA complex and tested the predicted protein-DNA interactions. These results of these studies provide a picture of how 933W repressor recognizes its DNA sites. We also show that, opposite of what is normally observed for lambdoid phages, 933W operator sequences have evolved in such a way that the presence of the most commonly found base sequences at particular operator positions serves to decrease, rather than increase, the affinity of the protein for the site. This finding cautions against assuming that a consensus sequence derived from sequence analysis defines the optimal, highest affinity DNA binding site for a protein.

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.

The lysis-lysogeny decision of bacteriophage 933W: a 933W repressor-mediated long-distance loop has no role in regulating 933W P(RM) activity.

Our data show that unlike bacteriophage λ, repressor bound at O(L) of bacteriophage 933W has no role in regulation of 933W repressor occupancy of 933W O(R)3 or the transcriptional activity of 933W P(RM). This finding suggests that a cooperative long-range loop between repressor tetramers bound at O(R) and O(L) does not form in bacteriophage 933W. Nonetheless, 933W forms lysogens, and 933W prophage display a threshold response to UV induction similar to related lambdoid phages. Hence, the long-range loop thought to be important for constructing a threshold response in lambdoid bacteriophages is dispensable. The lack of a loop requires bacteriophage 933W to use a novel strategy in regulating its lysis-lysogeny decisions. As part of this strategy, the difference between the repressor concentrations needed to bind O(R)2 and activate 933W P(RM) transcription or bind O(R)3 and repress transcription from P(RM) is <2-fold. Consequently, P(RM) is never fully activated, reaching only ∼25% of the maximum possible level of repressor-dependent activation before repressor-mediated repression occurs. The 933W repressor also apparently does not bind cooperatively to the individual sites in O(R) and O(L). This scenario explains how, in the absence of DNA looping, bacteriophage 933W displays a threshold effect in response to DNA damage and suggests how 933W lysogens behave as "hair triggers" with spontaneous induction occurring to a greater extent in this phage than in other lambdoid phages.