Alexander Zaborin

Red death in Caenorhabditis elegans caused by Pseudomonas aeruginosa PAO1

During host injury, Pseudomonas aeruginosa can be cued to express a lethal phenotype within the intestinal tract reservoir—a hostile, nutrient scarce environment depleted of inorganic phosphate. Here we determined if phosphate depletion activates a lethal phenotype in P. aeruginosa during intestinal colonization. To test this, we allowed Caenorhabditis elegans to feed on lawns of P. aeruginosa PAO1 grown on high and low phosphate media. Phosphate depletion caused PAO1 to kill 60% of nematodes whereas no worms died on high phosphate media. Unexpectedly, intense redness was observed in digestive tubes of worms before death. Using a combination of transcriptome analyses, mutants, and reporter constructs, we identified 3 global virulence systems that were involved in the “red death” response of P. aeruginosa during phosphate depletion; they included phosphate signaling (PhoB), the MvfR–PQS pathway of quorum sensing, and the pyoverdin iron acquisition system. Activation of all 3 systems was required to form a red colored PQS+Fe3+ complex which conferred a lethal phenotype in this model. When pyoverdin production was inhibited in P. aeruginosa by providing excess iron, red death was attenuated in C. elegans and mortality was decreased in mice intestinally inoculated with P. aeruginosa. Introduction of the red colored PQS+Fe3+ complex into the digestive tube of C. elegans or mouse intestine caused mortality associated with epithelial disruption and apoptosis. In summary, red death in C. elegans reveals a triangulated response between PhoB, MvfR–PQS, and pyoverdin in response to phosphate depletion that activates a lethal phenotype in P. aeruginosa.

Membership and Behavior of Ultra-Low-Diversity Pathogen Communities Present in the Gut of Humans during Prolonged Critical Illness

ABSTRACT We analyzed the 16S rRNA amplicon composition in fecal samples of selected patients during their prolonged stay in an intensive care unit (ICU) and observed the emergence of ultra-low-diversity communities (1 to 4 bacterial taxa) in 30% of the patients. Bacteria associated with the genera Enterococcus and Staphylococcus and the family Enterobacteriaceae comprised the majority of these communities. The composition of cultured species from stool samples correlated to the 16S rRNA analysis and additionally revealed the emergence of Candida albicans and Candida glabrata in ~75% of cases. Four of 14 ICU patients harbored 2-member pathogen communities consisting of one Candida taxon and one bacterial taxon. Bacterial members displayed a high degree of resistance to multiple antibiotics. The virulence potential of the 2-member communities was examined in C. elegans during nutrient deprivation and exposure to opioids in order to mimic local conditions in the gut during critical illness. Under conditions of nutrient deprivation, the bacterial members attenuated the virulence of fungal members, leading to a “commensal lifestyle.” However, exposure to opioids led to a breakdown in this commensalism in 2 of the ultra-low-diversity communities. Application of a novel antivirulence agent (phosphate-polyethylene glycol [Pi-PEG]) that creates local phosphate abundance prevented opioid-induced virulence among these pathogen communities, thus rescuing the commensal lifestyle. To conclude, the gut microflora in critically ill patients can consist of ultra-low-diversity communities of multidrug-resistant pathogenic microbes. Local environmental conditions in gut may direct pathogen communities to adapt to either a commensal style or a pathogenic style. IMPORTANCE During critical illness, the normal gut microbiota becomes disrupted in response to host physiologic stress and antibiotic treatment. Here we demonstrate that the community structure of the gut microbiota during prolonged critical illness is dramatically changed such that in many cases only two-member pathogen communities remain. Most of these ultra-low-membership communities display low virulence when grouped together (i.e., a commensal lifestyle); individually, however, they can express highly harmful behaviors (i.e., a pathogenic lifestyle). The commensal lifestyle of the whole community can be shifted to a pathogenic one in response to host factors such as opioids that are released during physiologic stress and critical illness. This shift can be prevented by using compounds such as Pi-PEG15-20 that interrupt bacterial virulence expression. Taking the data together, this report characterizes the plasticity seen with respect to the choice between a commensal lifestyle and a pathogenic lifestyle among ultra-low-diversity pathogen communities that predominate in the gut during critical illness and offers novel strategies for prevention of sepsis. During critical illness, the normal gut microbiota becomes disrupted in response to host physiologic stress and antibiotic treatment. Here we demonstrate that the community structure of the gut microbiota during prolonged critical illness is dramatically changed such that in many cases only two-member pathogen communities remain. Most of these ultra-low-membership communities display low virulence when grouped together (i.e., a commensal lifestyle); individually, however, they can express highly harmful behaviors (i.e., a pathogenic lifestyle). The commensal lifestyle of the whole community can be shifted to a pathogenic one in response to host factors such as opioids that are released during physiologic stress and critical illness. This shift can be prevented by using compounds such as Pi-PEG15-20 that interrupt bacterial virulence expression. Taking the data together, this report characterizes the plasticity seen with respect to the choice between a commensal lifestyle and a pathogenic lifestyle among ultra-low-diversity pathogen communities that predominate in the gut during critical illness and offers novel strategies for prevention of sepsis.

Depletion of intestinal phosphate after operative injury activates the virulence of P aeruginosa causing lethal gut-derived sepsis

BACKGROUND We explored the possibility that the opportunistic pathogen, Pseudomonas aeruginosa senses low phosphate (Pi) as a signal of host injury and shifts to a lethal phenotype. METHODS Virulence expression in P aeruginosa was examined in vitro under low phosphate conditions by assessing expression of the PA-I lectin, a barrier dysregulating protein, pyocyanin, and biofilm production, and PstS, a phosphate scavenging protein. Virulence expression in vivo was assessed using operatively injured mice (30% hepatectomy) intestinally inoculated with P aeruginosa. RESULTS In vitro experiments demonstrated that acute phosphate depletion resulted in an increase (P = .001) in the expression the PA-I lectin, biofilm, pyocyanin, and PstS. Operative injury caused a depletion (P = .006) of intestinal phosphate concentration and increased mortality (60%) owing to intestinal P aeruginosa, which was prevented completely with oral phosphate supplementation and restoration of intestinal phosphate, neither of which were observed with systemic (IV) administration. PstS gene expression was 32-fold higher in P aeruginosa recovered from the cecum after hepatectomy indicating inadequate intestinal Pi. CONCLUSIONS Operative injury-induced intestinal phosphate depletion shifts the phenotype of P aeruginosa to express enhanced virulence in vitro and lethality in vivo. Intestinal phosphate repletion may be a novel strategy to contain pathogens associated with lethal gut-derived sepsis.

Collagen degradation and MMP9 activation by Enterococcus faecalis contribute to intestinal anastomotic leak

Enterococcus faecalis depletes intestinal collagen, activates the host tissue protease MMP9, and contributes to anastomotic leak. Can our gut microbes prevent wound healing? In a new study, Shogan et al. examined whether the bacterium Enterococcus faecalis, normally present in the intestine, contributes to anastomotic leak, the most feared complication after intestinal surgery. They demonstrated that intestinal E. faecalis can produce a tissue-destroying enzyme that affects the normal healing process by breaking down collagen, a protein that is critical to fully seal the intestine after its removal and reconnection. E. faecalis also activates a host gut enzyme, MMP9, further contributing to anastomotic leak. Finally, the authors demonstrated that the most common antibiotic used in intestinal surgery does not eliminate E. faecalis and thus does not prevent anastomotic leak. Even under the most expert care, a properly constructed intestinal anastomosis can fail to heal, resulting in leakage of its contents, peritonitis, and sepsis. The cause of anastomotic leak remains unknown, and its incidence has not changed in decades. We demonstrate that the commensal bacterium Enterococcus faecalis contributes to the pathogenesis of anastomotic leak through its capacity to degrade collagen and to activate tissue matrix metalloproteinase 9 (MMP9) in host intestinal tissues. We demonstrate in rats that leaking anastomotic tissues were colonized by E. faecalis strains that showed an increased collagen-degrading activity and also an increased ability to activate host MMP9, both of which contributed to anastomotic leakage. We demonstrate that the E. faecalis genes gelE and sprE were required for E. faecalis–mediated MMP9 activation. Either elimination of E. faecalis strains through direct topical antibiotics applied to rat intestinal tissues or pharmacological suppression of intestinal MMP9 activation prevented anastomotic leak in rats. In contrast, the standard recommended intravenous antibiotics used in patients undergoing colorectal surgery did not eliminate E. faecalis at anastomotic tissues nor did they prevent leak in our rat model. Finally, we show in humans undergoing colon surgery and treated with the standard recommended intravenous antibiotics that their anastomotic tissues still contained E. faecalis and other bacterial strains with collagen-degrading/MMP9-activating activity. We suggest that intestinal microbes with the capacity to produce collagenases and to activate host metalloproteinase MMP9 may break down collagen in the intestinal tissue contributing to anastomotic leak.

Intestinal Tissues Induce an SNP Mutation in Pseudomonas aeruginosa That Enhances Its Virulence: Possible Role in Anastomotic Leak

The most feared complication following intestinal resection is anastomotic leakage. In high risk areas (esophagus/rectum) where neoadjuvant chemoradiation is used, the incidence of anastomotic leaks remains unacceptably high (∼10%) even when performed by specialist surgeons in high volume centers. The aims of this study were to test the hypothesis that anastomotic leakage develops when pathogens colonizing anastomotic sites become in vivo transformed to express a tissue destroying phenotype. We developed a novel model of anastomotic leak in which rats were exposed to pre-operative radiation as in cancer surgery, underwent distal colon resection and then were intestinally inoculated with Pseudomonas aeruginosa, a common colonizer of the radiated intestine. Results demonstrated that intestinal tissues exposed to preoperative radiation developed a significant incidence of anastomotic leak (>60%; p<0.01) when colonized by P. aeruginosa compared to radiated tissues alone (0%). Phenotype analysis comparing the original inoculating strain (MPAO1- termed P1) and the strain retrieved from leaking anastomotic tissues (termed P2) demonstrated that P2 was altered in pyocyanin production and displayed enhanced collagenase activity, high swarming motility, and a destructive phenotype against cultured intestinal epithelial cells (i.e. apoptosis, barrier function, cytolysis). Comparative genotype analysis between P1 and P2 revealed a single nucleotide polymorphism (SNP) mutation in the mexT gene that led to a stop codon resulting in a non-functional truncated protein. Replacement of the mutated mexT gene in P2 with mexT from the original parental strain P1 led to reversion of P2 to the P1 phenotype. No spontaneous transformation was detected during 20 passages in TSB media. Use of a novel virulence suppressing compound PEG/Pi prevented P. aeruginosa transformation to the tissue destructive phenotype and prevented anastomotic leak in rats. This work demonstrates that in vivo transformation of microbial pathogens to a tissue destroying phenotype may have important implications in the pathogenesis of anastomotic leak.

Trauma/SepsisDepletion of intestinal phosphate after operative injury activates the virulence of P aeruginosa causing lethal gut-derived sepsis

BACKGROUND We explored the possibility that the opportunistic pathogen, Pseudomonas aeruginosa senses low phosphate (Pi) as a signal of host injury and shifts to a lethal phenotype. METHODS Virulence expression in P aeruginosa was examined in vitro under low phosphate conditions by assessing expression of the PA-I lectin, a barrier dysregulating protein, pyocyanin, and biofilm production, and PstS, a phosphate scavenging protein. Virulence expression in vivo was assessed using operatively injured mice (30% hepatectomy) intestinally inoculated with P aeruginosa. RESULTS In vitro experiments demonstrated that acute phosphate depletion resulted in an increase (P = .001) in the expression the PA-I lectin, biofilm, pyocyanin, and PstS. Operative injury caused a depletion (P = .006) of intestinal phosphate concentration and increased mortality (60%) owing to intestinal P aeruginosa, which was prevented completely with oral phosphate supplementation and restoration of intestinal phosphate, neither of which were observed with systemic (IV) administration. PstS gene expression was 32-fold higher in P aeruginosa recovered from the cecum after hepatectomy indicating inadequate intestinal Pi. CONCLUSIONS Operative injury-induced intestinal phosphate depletion shifts the phenotype of P aeruginosa to express enhanced virulence in vitro and lethality in vivo. Intestinal phosphate repletion may be a novel strategy to contain pathogens associated with lethal gut-derived sepsis.

Structure–Function Aspects of PstS in Multi-Drug–Resistant Pseudomonas aeruginosa

The increasing prevalence of multi-drug–resistant (MDR) strains of Pseudomonas aeruginosa among critically ill humans is of significant concern. In the current study, we show that MDR clinical isolates of P. aeruginosa representing three distinct genotypes that display high virulence against intestinal epithelial cells, form novel appendage-like structures on their cell surfaces. These appendages contain PstS, an extracellular phosphate binding protein. Using anti-PstS antibodies, we determined that the PstS-rich appendages in MDR strains are involved in adherence to and disruption of the integrity of cultured intestinal epithelial cell monolayers. The outer surface–expressed PstS protein was also identified to be present in P. aeruginosa MPAO1, although to a lesser degree, and its role in conferring an adhesive and barrier disruptive phenotype against intestinal epithelial cells was confirmed using an isogenic ΔPstS mutant. Formation of the PstS rich appendages was induced during phosphate limitation and completely suppressed in phosphate-rich media. Injection of MDR strains directly into the intestinal tract of surgically injured mice, a known model of phosphate limitation, caused high mortality rates (60%–100%). Repletion of intestinal phosphate in this model completely prevented mortality. Finally, significantly less outer surface PstS was observed in the MPAO1 mutant ΔHxcR thus establishing a role for the alternative type II secretion system Hxc in outer surface PstS expression. Gene expression analysis performed by RT-PCR confirmed this finding and further demonstrated abundant expression of pstS analogous to pa5369, pstS analogous to pa0688/pa14–55410, and hxcX in MDR strains. Taken together, these studies provide evidence that outer surface PstS expression confers a highly virulent phenotype of MDR isolates against the intestinal epithelium that alters their adhesive and barrier disrupting properties against the intestinal epithelium.

Candida albicans isolates from the gut of critically ill patients respond to phosphate limitation by expressing filaments and a lethal phenotype.

Candida albicans is an opportunistic pathogen that proliferates in the intestinal tract of critically ill patients where it continues to be a major cause of infectious-related mortality. The precise cues that shift intestinal C. albicans from its ubiquitous indolent colonizing yeast form to an invasive and lethal filamentous form remain unknown. We have previously shown that severe phosphate depletion develops in the intestinal tract during extreme physiologic stress and plays a major role in shifting intestinal Pseudomonas aeruginosa to express a lethal phenotype via conserved phosphosensory-phosphoregulatory systems. Here we studied whether phosphate dependent virulence expression could be similarly demonstrated for C. albicans. C. albicans isolates from the stool of critically ill patients and laboratory prototype strains (SC5314, BWP17, SN152) were evaluated for morphotype transformation and lethality against C. elegans and mice during exposure to phosphate limitation. Isolates ICU1 and ICU12 were able to filament and kill C. elegans in a phosphate dependent manner. In a mouse model of intestinal phosphate depletion (30% hepatectomy), direct intestinal inoculation of C. albicans caused mortality that was prevented by oral phosphate supplementation. Prototype strains displayed limited responses to phosphate limitation; however, the pho4Δ mutant displayed extensive filamentation during low phosphate conditions compared to its isogenic parent strain SN152, suggesting that mutation in the transcriptional factor Pho4p may sensitize C. albicans to phosphate limitation. Extensive filamentation was also observed in strain ICU12 suggesting that this strain is also sensitized to phosphate limitation. Analysis of the sequence of PHO4 in strain ICU12, its transcriptional response to phosphate limitation, and phosphatase assays confirmed that ICU12 demonstrates a profound response to phosphate limitation. The emergence of strains of C. albicans with marked responsiveness to phosphate limitation may represent a fitness adaptation to the complex and nutrient scarce environment typical of the gut of a critically ill patient.

Pseudomonas aeruginosa virulence expression is directly activated by morphine and is capable of causing lethal gut-derived sepsis in mice during chronic morphine administration.

Objective: This study was designed to examine the effect of morphine administration on the intestinal mucus barrier and determine its direct effect on the virulence and lethality of Pseudomonas aeruginosa, one of the most frequent pathogens to colonize the gut of critically ill patients. Background Data: Surgical injury is associated with significant exposure of host tissues to morphine from both endogenous release and its use as a potent analgesic agent. Morphine use in surgical patients exposed to extreme physiologic stress is well established to result in increased infection risk. Although morphine is a known immunosuppressant, whether it directly induces virulence expression and lethality in microbes that colonize the human gut remains unknown. Methods: Mice were implanted with a slow release morphine or placebo pellet with and without intestinal inoculation of P. aeruginosa created by direct cecal injection. Mucus production and epithelial integrity was assessed in cecal tissue via Alcian blue staining and histologic analysis. In vivo and in vitro P. aeruginosa virulence expression was examined using reporter strains tagged to the epithelial barrier disrupting protein PA-I lectin. P. aeruginosa chemotaxis toward morphine was also assayed in vitro. Finally, the direct effect of morphine to induce PA-I lectin expression was determined in the absence and presence of methylnaltrexone, a &mgr; opioid receptor antagonist. Results: Mice intestinally inoculated with P. aeruginosa and implanted with a morphine pellet demonstrated significant suppression of intestinal mucus, disrupted intestinal epithelium, and enhanced mortality; whereas exposure of mice to either systemic morphine or intestinal P. aeruginosa alone enhanced intestinal mucus without mortality, suggesting a shift in P. aeruginosa during morphine exposure to a mucus suppressing, barrier disrupting, and lethal phenotype. Direct exposure of P. aeruginosa to morphine in vitro confirmed that morphine can transform P. aeruginosa to a more virulent phenotype that is attenuated in part by methylnaltrexone. Conclusions: Morphine administration shifts intestinal P. aeruginosa to express a virulent phenotype and may play a role in its ability to causes lethal gut-derived sepsis in a susceptible host.

The Shift of an Intestinal "Microbiome" to a "Pathobiome" Governs the Course and Outcome of Sepsis Following Surgical Injury.

ABSTRACT Sepsis following surgical injury remains a growing and worrisome problem following both emergent and elective surgery. Although early resuscitation efforts and prompt antibiotic therapy have improved outcomes in the first 24 to 48 h, late onset sepsis is now the most common cause of death in modern intensive care units. This time shift may be, in part, a result of prolonged exposure of the host to the stressors of critical illness which, over time, erode the health promoting intestinal microbiota and allow for virulent pathogens to predominate. Colonizing pathogens can then subvert the immune system and contribute to the deterioration of the host response. Here, we posit that novel approaches integrating the molecular, ecological, and evolutionary dynamics of the evolving gut microbiome/pathobiome during critical illness are needed to understand and prevent the late onset sepsis that develops following prolonged critical illness.