Browsing by Subject "Urinary tract infection"

The mammalian urinary bladder is a highly specialized organ that must be able to withstand considerable amounts of osmotic pressure at its mucosal surface, in addition to maintaining an impenetrable barrier against potential pathogens. The lower urinary tract's virtually inevitable exposure to external microbial pathogens warrants efficient tissue-specialized defenses to maintain sterility. The observation that the bladder can become chronically infected with uropathogenic E.coli (UPEC) in combination with clinical observations that antibody responses following bladder infections are not detectable, suggest defects in the formation of adaptive immunity and immunological memory. We have identified a broadly immunosuppressive transcriptional program specific to the bladder, but not the kidney, during infection of the urinary tract that is dependent on tissue-resident mast cells. This mast cell-dependent phenomenon involves localized production of IL-10 and results in suppressed humoral and cell-mediated responses and bacterial persistence. Therefore, in addition to the previously described role of mast cells orchestrating the early innate immune responses in the bladder during infection, they subsequently play a tissue-specific immunosuppressive role. These findings may explain the prevalent recurrence of bladder infections and suggest the bladder as a site exhibiting an intrinsic degree of mast cell-maintained immune privilege.

Interestingly, though the bladder is not capable of initiating an effective adaptive immune response during bladder infections, we have generated data showing that it was possible to circumvent the immune limitations of the bladder to provoke a strong adaptive and protective immune response by vaccinating against UPEC at an alternate mucosal site. We reasoned that by immunizing the nasal regions of mice with a vaccine formulation comprising of FimH adhesin, a highly conserved adhesive moiety of type 1 fimbriae expressed on UPEC, and an effective mucosal adjuvant we would evoke protective immunity against UPEC infections. We found that a FimH vaccine coupled with either a mast cell activating adjuvant c48/80 or CpG oligodeoxynucleotide, a TLR9 agonist, evoked high levels of FimH specific IgG antibody in the serum and IgA in the urine of immunized mice. We also observed that following UPEC challenge, these FimH/adjuvant immunized mice exhibited significantly reduced bacterial load in the bladders compared to mice challenged with just FimH. These studies reveal that immunization of nasal regions with a FimH vaccine is an effective strategy to overcome the limitation in adaptive immunity observed in the bladder.

Urinary tract infections (UTIs) are typically caused by bacteria that colonize different regions of the urinary tract, mainly the bladder and the kidney. Approximately 25% of women that suffer from UTIs experience a recurrent infection within 6 months of the initial bout, making UTIs a serious economic burden resulting in more than 10 million hospital visits and $3.5 billion in healthcare costs in the United States alone. Type-1 fimbriated Uropathogenic E. coli (UPEC) is the major causative agent of UTIs, accounting for almost 90 % of bacterial UTIs. The unique ability of UPEC to bind and invade the superficial bladder epithelium allows the bacteria to persist inside epithelial niches and survive antibiotic treatment. Persistent, intracellular UPEC are retained in the bladder epithelium for long periods, making them a source of recurrent UTIs. Hence, the ability of UPEC to persist in the bladder is a matter of major health and economic concern, making studies exploring the underlying mechanism of UPEC persistence highly relevant.

In my thesis, I will describe how intracellular Uropathogenic E.coli (UPEC) evade host defense mechanisms in the superficial bladder epithelium. I will also describe some of the unique traits of persistent UPEC and explore strategies to induce their clearance from the bladder. I have discovered that the UPEC virulence factor Alpha-hemolysin (HlyA) plays a key role in the survival and persistence of UPEC in the superficial bladder epithelium. In-vitro and in-vivo studies comparing intracellular survival of wild type (WT) and hemolysin deficient UPEC suggested that HlyA is vital for UPEC persistence in the superficial bladder epithelium. Further in-vitro studies revealed that hemolysin helped UPEC persist intracellularly by evading the bacterial expulsion actions of the bladder cells and remarkably, this virulence factor also helped bacteria avoid t degradation in lysosomes.

To elucidate the mechanistic basis for how hemolysin promotes UPEC persistence in the urothelium, we initially focused on how hemolysin facilitates the evasion of UPEC expulsion from bladder cells. We found that upon entry, UPEC were encased in “exocytic vesicles” but as a result of HlyA expression these bacteria escaped these vesicles and entered the cytosol. Consequently, these bacteria were able to avoid expulsion by the cellular export machinery.

Since bacteria found in the cytosol of host cells are typically recognized by the cellular autophagy pathway and transported to the lysosomes where they are degraded, we explored why this was not the case here. We observed that although cytosolic HlyA expressing UPEC were recognized and encased by the autophagy system and transported to lysosomes, the bacteria appeared to avoid degradation in these normally degradative compartments. A closer examination of the bacteria containing lysosomes revealed that they lacked V-ATPase. V-ATPase is a well-known proton pump essential for the acidification of mammalian intracellular degradative compartments, allowing for the proper functioning of degradative proteases. The absence of V-ATPase appeared to be due to hemolysin mediated alteration of the bladder cell F-actin network. From these studies, it is clear that UPEC hemolysin facilitates UPEC persistence in the superficial bladder epithelium by helping bacteria avoid expulsion by the exocytic machinery of the cell and at the same time enabling the bacteria avoid degradation when the bacteria are shuttled into the lysosomes.

Interestingly even though UPEC appear to avoid elimination from the bladder cell their ability to multiple in bladder cells seem limited.. Indeed, our in-vitro and in-vivo experiments reveal that UPEC survive in superficial bladder epithelium for extended periods of time without a significantly change in CFU numbers. Indeed, we observed these bacteria appeared quiescent in nature. This observation was supported by the observation that UPEC genetically unable to enter a quiescence phase exhibited limited ability to persist in bladder cells in vitro and in vivo, in the mouse bladder.

The studies elucidated in this thesis reveal how UPEC toxin, Alpha-hemolysin plays a significant role in promoting UPEC persistence via the modulation of the vesicular compartmentalization of UPEC at two different stages of the infection in the superficial bladder epithelium. These results highlight the importance of UPEC Alpha-hemolysin as an essential determinant of UPEC persistence in the urinary bladder.

Urinary tract infections (UTIs) are the second most common type of infection identified in the clinical setting and disproportionately afflict women. UTIs most frequently manifest in the form of infection of the lower urinary tract, involving the bladder. Uropathogens, particularly uropathogenic E. coli, progressively colonize the urethra and ascend to the bladder, where they initiate cystitis. In some cases, infection further ascends through the ureters and reaches the kidneys, where it causes pyelonephritis. Infection of both the upper and lower urinary tract can have serious ramifications for the host, and this is in large part due not to infection itself but to host-directed responses to bacterial insults.

In this thesis, I will describe and discuss two distinct aspects of UTIs. In the first study, in vivo work in a mouse model of urinary tract infection revealed a novel role for mast cells, which are tissue-resident granulated innate immune cells, in directing the detachment and death of epithelial cells during cystitis, facilitating the clearance of bacteria from the bladder. An ex vivo porcine bladder infection model suggested a specific role for mast cell granules and the proteases contained therein, which was corroborated with in vitro experiments utlizing isolated mast cell granules and human epithelial cells to demonstrate granule-induced exfoliation and cell death. From this work, it is clear that mast cells play a highly targeted role in modulating urothelial integrity during bladder infection by mediating host-directed epithelial loss.

In the second study described in this dissertation, the synergistic roles of both pyelonephritis and vesico-ureteric reflux (VUR), a congenital urinary tract defect that results in the improper backflow of urine from the bladder to the kidney, in the development of reflux nephropathy, a fibrotic host response characterized by renal scar formation, were elucidated in a series of in vivo experiments. Specifically, the C3H mouse, which is naturally susceptible to VUR, was utilized to characterize the dynamics of kidney infection and the onset of reflux nephropathy. Renal scarring was dependent on the presence of sustained kidney infection and the accompanying inflammatory response due to VUR, while neither transient infection nor reflux alone were sufficient to provoke nephropathy. Thus, the development of reflux nephropathy is dependent upon the confluence of both infection and VUR.

This body of work reveals the double-edged sword of the host inflammatory response to urinary tract infection. In the bladder, mast cell activation and degranulation leads to granule-induced epithelial exfoliation and consequently a reduction in the bacterial burden in the bladder. However, the sustained inflammatory response that accompanies pyelonephritis in vesico-ureteric reflux-affected individuals results in significant damage to the kidney without any accompanying reduction in infection. These findings highlight the dueling roles of the host inflammatory response to infection in the upper and lower urinary tract and strongly suggest that differential clinical approaches to cystitis and pyelonephritis are necessary to promote an effective mast cell in the bladder in the former and facilitate the clearance of renal infection while mitigating tissue damage in the latter.

Due to its close proximity to the gastrointestinal tract, the human urinary tract is

subjected to constant barrage by gut-­associated bacteria. However, for the most part, this tract has resisted infection by various microbes. The impregnability of the urinary tract to microbial colonization is attributable to the ability of the bladder to promptly sense and mount robust responses to microbial challenge. A powerful mechanism for the elimination of invading bacteria was recently described in bladder epithelial cells, involving non-­lytic ejection of intracellular bacteria back into the extracellular milieu. In spite of the effectiveness of this defense strategy, much of the underlying mechanisms surrounding how this powerful cellular defense activity detects intracellular UPEC and shuttles them from their intracellular location to the plasma membrane of BECs to be exported remains largely a mystery.

Here, we describe uropathogenic E.coli (UPEC) expelled from infected bladder

epithelium cells (BECs) within membrane-­bound vesicles as a distinct cellular defense

response. Examination of the intracellular UPEC revealed that intracellular bacteria were

initially processed via autophagy, the conventional degradative pathway, then delivered

into multivesicular bodies (MVBs) and encapsulated in nascent intraluminal vesicle membrane. We further show the bacterial expulsion is triggered when intracellular UPEC follow the natural degradative trafficking pathway and reach lysosomes and attempt to neutralize its pH to avoid degradation. This pathogen-­mediated activity is detected by mucolipin TRP channel 3 (TRPML3), a transient receptor potential cation channel localized on lysosomes, which spontaneously initiates lysosome exocytosis resulting in expulsion of exosome-­encased bacteria. These studies reveal a cellular default system for lysosome homeostasis and also, how it is coopted by the autonomous defense program to clear recalcitrant pathogens.

The urinary tract is one of the most intractable mucosal surfaces for pathogens to colonize. In addition to the natural barriers at this site, potential pathogens have to contend with the vigorous local innate immune response that is initiated by engagement of surveillance molecule TLRs. TLR4 appears to be not only exclusively expressed on superficial BECs but also critical to triggering robust local innate immune responses. TLR4 recognizes Gram-negative bacterial component LPS and initiates a series of intracellular NF-kappaB associated signaling events resulting in a cytokine response. We examined intracellular signaling events in human BECs leading to the production of IL-6, a major urinary cytokine, following activation by E. coli and isolated LPS, and observed that, in addition to the classical NF-kappaB associated pathway, BEC TLR4 triggers a distinct and more rapid signaling response involving, sequentially, Ca2+, AC3 generated cAMP, and the transcriptional factor CREB. This capacity of BECs to mobilize secondary messengers and evoke a more rapid IL-6 response might be critical in their role as first responders to microbial challenge in the urinary tract.

Here, we also report two additional distinct TLR4-mediated defense mechanisms in BECs. First, BEC TLR4 inhibits bacterial invasion, a necessary step for successful infection. TLR4-mediated suppression of bacterial invasion was linked to increased intracellular cAMP levels which negatively impacted Rac-1 mediated mobilization of the cytoskeleton. Additionally, we found that BECs continue to fight UPEC even after bacterial invasion by triggering bacterial exocytosis through a distinct TLR4-mediated mechanism following activation by LPS. In addition, we reveal that Caveolin-1, Rab27b, PKA, and MyRIP are components of the exocytic compartment and that they form a complex involved in the exocytosis of bacteria. The ability of TLR4 to mediate the rapid cytokine response, the inhibition of bacterial invasion, and the expulsion of intracellular bacteria from infected cells represents three previously unrecognized functions for this innate immune receptor.