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Characterizarion of the Regulation and Function of Neisseria Gonorrhoeae TonB-dependent Transporters: TdfG, TdfH and TdfJJean, Sophonie 01 January 2015 (has links)
The obligate human pathogen Neisseria gonorrhoeae successfully overcomes host strategies to limit essential nutrients, termed “nutritional immunity” by expression of TonB-dependent transporters (TdTs): outer membrane receptors that facilitate nutrient transport in an energy-dependent manner. N. gonorrhoeae encodes eight TdTs, five of which facilitate utilization of iron or iron-chelates from host derived proteins including transferrin, lactoferrin and hemoglobin, in addition to siderophores from neighboring bacteria. The transferrin utilization system was previously shown to be critical for establishing infection in human males; demonstrating the possible contributions of TdTs to gonococcal pathogenesis. As such, studies describing the biological function and contribution to pathogenesis of the remaining three uncharacterized TdTs (TdfG, TdfH and TdfJ) are needed. In this study we report that neither TdfG, TdfH nor TdfJ are heme receptors as gonococcal heme utilization occurs passively, independent of energy derived from the TonB system. We also report that TdfH and TdfJ are zinc (Zn) regulated and identify virulence associated regulators that modulate expression of these TdTs, which is in some cases strain-specific. We report that both TdfH and TdfJ contribute to Zn acquisition in N. gonorrhoeae and we characterize TdfH as a calprotectin receptor. Calprotectin, an immune effector protein highly expressed in neutrophils, has antimicrobial activity due to its ability to sequester Zn and Mn. We present evidence that TdfH confers resistance to calprotectin and that TdfH facilitates gonococcal calprotectin binding and Zn accumulation in the presence or absence of calprotectin. Finally, we demonstrate that TdfH expression enhances N. gonorrhoeae NET survival. These studies identify for the first time a novel gonococcal defense strategy to host-mediated nutritional immunity, in which N. gonorrhoeae, via the TdT TdfH, utilizes calprotectin as a Zn source neutralizing its antimicrobial activity. These studies have yielded novel insights into the function and regulation of TdfG, TdfH and TdfJ in N. gonorrhoeae and have laid the framework for future investigation of TdT-mediated Zn acquisition and its role in bacterial pathogenesis.
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TonB-Dependent Transport of Thiopeptide Antibiotics to Kill Gram-Negative Pathogens / Transport of Thiopeptides Across the Outer MembraneChan, Chuk-Kin Derek January 2023 (has links)
The outer membrane (OM) of P. aeruginosa is a semi-permeable barrier that contributes to antibiotic resistance by reducing uptake. Finding strategies to circumvent this barrier is a major challenge. One approach involves screening in physiologically relevant conditions to identify novel activity in existing molecules. We discovered that thiostrepton (TS), a thiopeptide antibiotic with no reported activity against Gram-negative bacteria, hijacks the pyoverdine siderophore transporters FpvA and FpvB to cross the OM under iron limitation to inhibit translation. Using TS, we subsequently showed that FpvB is not primarily a pyoverdine transporter, but rather a promiscuous transporter for siderophores ferrichrome and ferrioxamine B. Our work with TS suggested that other thiopeptides may use siderophore transporters for entry into the cell. This hypothesis led to a screen to identify other thiopeptides with activity against P. aeruginosa, uncovering two other thiopeptides, thiocillin and micrococcin, that use the ferrioxamine transporter FoxA for uptake. We discovered another siderophore, bisucaberin, could also use FoxA for uptake and our collaborators solved the crystal structure of bisucaberin bound to FoxA. Through biochemical approaches, we characterized how FoxA accommodates structurally distinct ligands. Finally, we screened known large natural product antibiotics with no pseudomonal activity under nutrient limitation and discovered that the glycopeptide vancomycin inhibits growth by blocking peptidoglycan crosslinking. This pilot screen emphasizes the importance of screening for antibiotics under physiologically relevant conditions to avoid overlooking potential hits. Overall, the findings from these studies can be used to guide medicinal chemistry efforts to develop novel siderophore-antibiotic conjugates for the treatment of P. aeruginosa infections. These results also help us gain a deeper understanding of the mechanism of binding and uptake through siderophore transporters and the range of substrates that can be taken up. / Dissertation / Doctor of Philosophy (PhD) / Antibiotic resistance is a growing crisis that threatens modern medicine, and it is becoming more challenging to discover truly new antibiotics to combat this threat. Intrinsic resistance conferred by the outer membrane of Gram-negative bacteria restricts the entry of many antibiotics, especially larger antibiotics that would otherwise inhibit the growth of Gram-positive bacteria. Consequently, there are fewer treatment options for infections caused by Gram-negative bacteria and developing new antibiotics that can cross the outer membrane remains a significant challenge in drug discovery. My work describes the discovery of a class of antibiotics that can bypass the outer membrane using specific outer-membrane nutrient transporters. Using biochemical, structural biology, fluorescence microscopy, and molecular biology techniques, we uncover the molecular determinants of uptake of these antibiotics for their respective transporters. These results can inform the design of novel narrow-spectrum antibiotics that can overcome the outer membrane barrier to combat antimicrobial resistance.
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Characterization of the Novel Interaction Between Neisseria gonorrhoeae TdfJ and its Human Ligand S100A7Maurakis, Stavros 01 January 2019 (has links)
Neisseria gonorrhoeae is an obligate human pathogen that causes the common STI gonorrhea, which presents a growing threat to global health. The WHO estimated 78 million new cases of gonorrhea worldwide in 2017, with estimates of 820,000 new cases in the United States alone according to the CDC. High-frequency phase and antigenic variation inherent in N. gonorrhoeae, coupled with its natural ability to rapidly acquire and stably integrate antimicrobial resistance factors into its genome, have culminated in an infection against which there is no effective vaccine, and for which the list of viable therapeutic options is quickly shrinking. Moreover, no protective immunity against subsequent infections is elicited upon exposure to N. gonorrhoeae, which highlights the need for research of novel antimicrobial and vaccination strategies. Within the human host, N. gonorrhoeae utilizes a unique strategy to overcome host sequestration of essential nutrients – termed nutritional immunity (NI) – such as ions of trace metals. The pathogen produces a family of outer membrane proteins called TonB-dependent transporters (TdTs) capable of binding to host NI factors and stripping them of their nutritional cargo for use by the pathogen. Importantly, these TdTs are very highly conserved and expressed among Neisseria species. TbpA is a well-characterized TdT that allows N. gonorrhoeae to acquire iron from human transferrin, and recent studies from our lab have shown that TdfH is capable of binding to a zinc-sequestering S100 protein called calprotectin and stripping it of its zinc ion. The S100 proteins are EF-hand calcium-binding proteins that naturally play an integral role in Ca2+ homeostasis, but due to their ability to bind transition metals, they have also demonstrated an innate immunity role by participating in nutrient sequestration.
The S100 proteins are expressed in all human cells, and all are capable of binding transition metals including zinc, manganese, and cobalt. Calprotectin, S100A7, and S100A12 have demonstrated an ability to hinder the infection potential of pathogenic E. coli, S. aureus, C. albicans, and various other pathogens via zinc sequestration. Herein, we demonstrate that N. gonorrhoeae is able to overcome this phenomenon and actually utilize these proteins as a zinc source in vitro. Furthermore, we identify S100A7 as the specific ligand for TdfJ, which utilizes this ligand to internalize zinc during infection. S100A7 growth support in vitro is dependent upon a functional TonB, TdfJ, and the cognate ABC transport system ZnuABC, and isogenic mutants incapable of producing znuA or tdfJ recover S100A7 utilization by complementation. Whole-cell binding assays and affinity pulldowns show that S100A7 binds specifically to both gonococcal and recombinant TdfJ, and growth and binding experiments show that these described phenomena are specific to human and not mouse S100A7. Finally, we show that a His-Asn double mutant S100A7 that is incapable of binding zinc cannot be utilized for growth by gonococci. These data illustrate the unique nature of the gonococcus’ ability to co-opt host defense strategies for its own purposes, and further identify the TdTs as promising targets for strategies to combat and prevent gonococcal infection.
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