Purine Biosynthesis Metabolically Constrains Intracellular Survival of Uropathogenic Escherichia coli

Shaffer, Carrie L.; Zhang, Ellisa W.; Dudley, Anne; Dixon, Beverly R. E. A.; Guckes, Kirsten R.; Breland, Erin J.; Floyd, Kyle A.; Casella, Daniel P.; Algood, Holly M. Scott; Clayton, Douglass B.; Hadjifrangiskou, Maria

doi:10.1128/iai.00471-16

Cited by 52 publications

(46 citation statements)

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“…The specificity of the Lamp1 antibody was confirmed by staining lamp1 −/− BECs (Figure S1b). To verify that infection on soft gels resulted in cytoplasmic UPEC we used a chloroquine‐resistance assay (Fernandez‐Prada et al, ; Paetzold, Lourido, Raupach, & Zychlinsky, ; Shaffer et al, ). Chloroquine is lysosomotropic and concentrates within vesicular compartments; treating BECs with 2.5 mg/ml chloroquine leads to therapeutic levels of the drug within vesicles thereby selectively killing endosomal UPEC (Shaffer et al, ).…”

Section: Resultsmentioning

confidence: 99%

“…These morphological changes were not due merely to seeding on PA gels; when BECs were grown on gels with an elastic modulus of 30 kPa they became morphologically indistinguishable from those grown on glass coverslips ( Figure 1b The specificity of the Lamp1 antibody was confirmed by staining lamp1 −/− BECs ( Figure S1b). To verify that infection on soft gels resulted in cytoplasmic UPEC we used a chloroquine-resistance assay (Fernandez-Prada et al, 2000;Paetzold, Lourido, Raupach, & Zychlinsky, 2007;Shaffer et al, 2016). Chloroquine is lysosomotropic and concentrates within vesicular compartments;…”

Section: Substrate Stiffness Is a Physiological Regulator Of Endosomentioning

confidence: 99%

“…treating BECs with 2.5 mg/ml chloroquine leads to therapeutic levels of the drug within vesicles thereby selectively killing endosomal UPEC (Shaffer et al, 2016). In infected BECs seeded on rigid substrates, chloroquine caused a 10-fold reduction in UPEC viability, whereas no significant effect was seen with cells seeded on soft gels ( Figure 1d); a similar dependence on substrate stiffness was observed with UPEC strain CFT073 (Mobley et al, 1990) demonstrating that mechanical regulation of endosomal escape was not strain specific ( Figure 1e).…”

Section: Substrate Stiffness Is a Physiological Regulator Of Endosomentioning

confidence: 99%

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Matrix stiffness regulates endosomal escape of uropathogenicE. coli

Moorthy

Byfield

Janmey

et al. 2020

Cellular Microbiology

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Uropathogenic E. coli (UPEC) infection in vivo is characterized by invasion of bladder umbrella epithelial cells followed by endosomal escape and proliferation in the cytoplasm to form intracellular bacterial communities. By contrast, UPEC infection in tissue culture models results in bacteria being trapped within Lamp1‐positive endosomes where proliferation is limited. Pharmacological disruption of the actin cytoskeleton has been shown to facilitate UPEC endosomal escape in vitro and extracellular matrix stiffness is a well‐characterized physiological regulator of actin dynamics; therefore, we hypothesized that substrate stiffness may play a role in UPEC endosomal escape. Using functionalized polyacrylamide substrates, we found that at physiological stiffness, UPEC escaped the endosome and proliferated rapidly in the cytoplasm of bladder epithelial cells. Dissection of the cytoskeletal signaling pathway demonstrated that inhibition of the Rho GTPase RhoB or its effector PRK1 was sufficient to increase cytoplasmic bacterial growth and that RhoB protein level was significantly reduced at physiological stiffness. Our data suggest that tissue stiffness is a critical regulator of intracellular bacterial growth. Due to the ease of doing genetic and pharmacological manipulations in cell culture, this model system may provide a useful tool for performing mechanistic studies on the intracellular life cycle of uropathogens.

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Section: Resultsmentioning

confidence: 99%

Section: Substrate Stiffness Is a Physiological Regulator Of Endosomentioning

confidence: 99%

Section: Substrate Stiffness Is a Physiological Regulator Of Endosomentioning

confidence: 99%

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Matrix stiffness regulates endosomal escape of uropathogenicE. coli

Moorthy

Byfield

Janmey

et al. 2020

Cellular Microbiology

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“…6A) . cvpA lies upstream of the purine biosynthesis locus purF , and some Δ cvpA mutant phenotypes have been attributed to reduced expression on purF due to polar effects (103,106). The growth of the EHEC Δ cvpA mutant was not impaired in the absence of exogenous purines (Fig S5C), suggesting the cvpA deletion does not adversely modify purF expression.…”

Section: Resultsmentioning

confidence: 99%

Transposon-insertion sequencing screens unveil requirements for EHEC growth and intestinal colonization

Warr

Hubbard

Múnera

et al. 2019

Preprint

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31 Enterohemorrhagic Escherichia coli O157:H7 (EHEC) is an important food-borne 32 pathogen that colonizes the colon. Transposon-insertion sequencing (TIS) was used to 33 identify genes required for EHEC and commensal E. coli K-12 growth in vitro and for 34 EHEC growth in vivo in the infant rabbit colon. Surprisingly, many conserved loci 35 contribute to EHEC's but not to K-12's growth in vitro, suggesting that gene acquisition 36 during EHEC evolution has heightened the pathogen's reliance on certain metabolic 37 processes that are dispensable for K-12. There was a restrictive bottleneck for EHEC 38 colonization of the rabbit colon, which complicated identification of EHEC genes 39 facilitating growth in vivo. Both a refined version of an existing analytic framework as 40 well as PCA-based analysis were used to compensate for the effects of the infection 41 bottleneck. These analyses confirmed that the EHEC LEE-encoded type III secretion 42 apparatus is required for growth in vivo and revealed that only a few effectors are critical 43 for in vivo fitness. Numerous mutants not previously associated with EHEC 44 survival/growth in vivo also appeared attenuated in vivo, and a subset of these putative 45 in vivo fitness factors were validated. Some were found to contribute to efficient type-46 three secretion while others, including tatABC, oxyR, envC, acrAB, and cvpA, promote 47 EHEC resistance to host-derived stresses encountered in vivo. cvpA, which is also 48 required for intestinal growth of several other enteric pathogens, proved to be required 49 for EHEC, Vibrio cholerae and Vibrio parahaemolyticus resistance to the bile salt 50 deoxycholate. Collectively, our findings provide a comprehensive framework for 51 understanding EHEC growth in the intestine. 523 53 Author Summary 54 Enterohemorrhagic E. coli (EHEC) are important food-borne pathogens that infect the 55 colon. We created a highly saturated EHEC transposon library and used transposon 56 insertion sequencing to identify the genes required for EHEC growth in vitro and in vivo 57 in the infant rabbit colon. We found that there is a large infection bottleneck in the rabbit 58 model of intestinal colonization, and refined two analytic approaches to facilitate 59 rigorous identification of new EHEC genes that promote fitness in vivo. Besides the 60 known type III secretion system, more than 200 additional genes were found to 61 contribute to EHEC survival and/or growth within the intestine. The requirement for 62 some of these new in vivo fitness factors was confirmed, and their contributions to 63 infection were investigated. This set of genes should be of considerable value for future 64 studies elucidating the processes that enable the pathogen to proliferate in vivo and for 65 design of new therapeutics. 66 4 67 Introduction 68 Enterohemorrhagic Escherichia coli (EHEC) is an important food-borne pathogen that 69 causes gastrointestinal (GI) infections worldwide. EHEC is a non-invasive pathogen that 70 colonizes the human colon and gives rise to sporadi...

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“…These include type 1 pili, the adhesin Ag43, capsule, OmpA, purine biosynthesis enzymes, and various regulators like Integration Host Factor (IHF), the QseC sensor kinase, the RNA chaperone Hfq, and the periplasmic prolyly isomerase and chaperone SurA (Fig. 5) (28, 121–129). Bacteria growing within IBCs appear to utilize non-glucose carbon sources such as galactoside and express stress resistance genes like yeaR that enable UPEC to better deal with oxidative and nitrosative stresses (97, 130).…”

Section: Regulation Of Intracellular Bacterial Growth and Persistencementioning

confidence: 99%

Invasion of Host Cells and Tissues by Uropathogenic Bacteria

2016

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Within the mammalian urinary tract uropathogenic bacteria face many challenges, including the shearing flow of urine, numerous antibacterial molecules, the bactericidal effects of phagocytes, and a scarcity of nutrients. These problems may be circumvented in part by the ability of uropathogenic Escherichia coli (UPEC) and several other uropathogens to invade the epithelial cells that line the urinary tract. By entering host cells, uropathogens can gain access to additional nutrients and protection from both host defenses and antibiotic treatments. Translocation through host cells can facilitate bacterial dissemination within the urinary tract, while the establishment of stable intracellular bacterial populations may create reservoirs for relapsing and chronic urinary tract infections (UTIs). Here we review the mechanisms and consequences of host cell invasion by uropathogenic bacteria, with consideration of the defenses that are brought to bear against facultative intracellular pathogens within the urinary tract. The relevance of host cell invasion to the pathogenesis of UTIs in human patients is also assessed, along with some of the emerging treatment options that build upon our growing understanding of the infectious life cycle of UPEC and other uropathogenic bacteria.

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Purine Biosynthesis Metabolically Constrains Intracellular Survival of Uropathogenic Escherichia coli

Cited by 52 publications

References 50 publications

Matrix stiffness regulates endosomal escape of uropathogenicE. coli

Matrix stiffness regulates endosomal escape of uropathogenicE. coli

Transposon-insertion sequencing screens unveil requirements for EHEC growth and intestinal colonization

Invasion of Host Cells and Tissues by Uropathogenic Bacteria

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