Pseudomonas aeruginosa minor pilins regulate virulence via modulation of FimS-AlgR activity

Marko, Victoria

January 2017

The type IV pilus is a motility organelle found in a range of bacteria, including the opportunistic pathogen Pseudomonas aeruginosa. These flexible fibres mediate twitching motility, biofilm maturation, surface adhesion, and virulence. The principle structural protein of the pilus is the major pilin, PilA, while a set of low abundance “minor pilins” are proposed to constitute the pilus tip. The minor pilins, FimU and PilVWXE, along with the non-pilin protein PilY1, prime assembly of surface-exposed pili. The fimU-pilVWXY1E operon is positively regulated by the FimS-AlgR two-component system. Independent of pilus assembly, PilY1 is an adhesin and mechanosensor that, along with PilW and PilX, triggers virulence upon surface attachment. Here, we aimed to uncover the mechanism for PilWXY1-mediated virulence. We hypothesized that loss of PilWXY1 would relieve feedback inhibition on FimS-AlgR, resulting in increased transcription of the minor pilin operon and dysregulation of virulence factors in the AlgR regulon. Caenorhabditis elegans slow killing assays revealed that pilW, pilX, and pilY1 mutants had reduced virulence relative to a pilA mutant, implying a role in virulence independent of pilus assembly. FimS-AlgR were required for the increased promoter activity of the minor pilin operon upon loss of pilV, pilW, pilX, or pilY1. Overexpression or hyperactivation of AlgR by point mutation led to reduced virulence, and the virulence defects of pilW, pilX, and pilY1 mutants were dependent on FimS-AlgR expression. We propose that PilWXY1 inhibit their own expression at the level of FimS-AlgR, such that loss of pilW, pilX, or pilY1 leads to FimS-mediated activation of AlgR, and reduced expression of acute-phase virulence factors. Accumulation of mutations in the minor pilin operon may represent an evolutionary strategy for P. aeruginosa populations in chronic lung infections, as loss of PilWXY1 would upregulate the expression of AlgR-dependent virulence factors – such as alginate – characteristic of such infections. / Thesis / Master of Science (MSc) / Pseudomonas aeruginosa is a bacterium that causes dangerous infections, including lung infections in cystic fibrosis patients. The bacteria use many strategies to infect their hosts, one of which involves a grappling hook-like fibre called the type IV pilus. There are many components involved in assembly and function of the pilus, including five proteins called “minor pilins” and a larger protein called PilY1 that may help the pilus detect surface attachment. We used a roundworm infection model to show that loss of PilY1 and specific minor pilins leads to delayed killing, while loss of other pilus proteins has no effect on worm survival. This effect was due to increased activation of a regulatory system called FimS-AlgR that inhibits expression of other factors used by this bacterium to infect its hosts. By studying how P. aeruginosa causes infection, we can design better strategies to disarm it and reduce the severity of infections.

pseudomonas aeruginosa

type iv pili

virulence

caenorhabditis elegans

alginate

biofilms

The Type IV Pilus Assembly ATPase PilB as a Regulator of Biofilm Formation and an Antivirulence Target

Dye, Keane

02 June 2022

Bacterial type IV pili (T4P) are filamentous surface appendages with a variety of functions including motility, surface attachment, and biofilm formation. In many species of bacteria a clear understanding of how the functions of T4P in lifestyle switching are regulated remains to be elucidated. Here, we focus on understanding the regulation of the T4P assembly ATPase PilB. We examined its interactions with the secondary messenger cyclic-di-GMP (cdG). Specifically we investigated how cdG binding regulates PilB functions not only as the assembly ATPase, but also as an EPS signaling molecule in Myxococcus xanthus biofilm regulation. Chapter 2 focuses on the development of a microplate-based biofilm assay for M. xanthus. This new assay allows for the analysis of the M. xanthus submerged biofilms under vegetative conditions in a high throughput format which has been absent in the published literature. M. xanthus biofilm formation tightly correlates with EPS production, suggesting that the assay can be used as a convenient method of examining EPS production. Chapter 3 examines the regulation of M. xanthus PilB (MxPilB) by cdG binding in vivo. We carried out a mutational analysis of the MshEN cdG binding domain in MxPilB. Mutations were created that either diverge with or converge from the MshEN consensus sequence. These two classes of MxPilB variants are expected to either decrease or increase cdG binding affinity, respectively. We examined the motility, EPS production, and piliation phenotypes of these mutants. Our results were consistent with a model where the function of MxPilB is altered in response to cdG binding, and suggesting that PilB responds to different thresholds of cdG concentration. In Chapter 4, we examine the ligand binding to the N-terminal cdG binding domain and C-terminal ATPase domain of Chloracidobacterium thermophilum PilB (CtPilB) in vitro. Our results confirm that these two domains bind to their respective ligands specifically, and demonstrate these domains communicate with each other in response to ligand binding. The results from all of the studies help us to establish a model where cdG binding fine tunes the functions of PilB to regulate the switch of bacteria between the motile and planktonic states. In addition to their roles in motility and biofilm formation, T4P are key virulence factors in many significant human pathogens. Antivirulence chemotherapeutics are considered to be a promising alternative to antibiotics, as they target disease processes rather than bacterial viability. Because PilB is essential for T4P biogenesis, we sought to identify PilB inhibitors for the development of antivirulence therapies. In Chapter 5, we describe the development of the first high throughput screen (HTS), for PilB inhibitors. This assay is uses the reduction of the binding of a fluorescent ATP analog to CtPilB in vitro, leading to the discovery of the plant flavonoid quercetin as a PilB inhibitor. Using M. xanthus as a model a bacterium, quercetin was found to inhibit T4P-dependent motility and T4P assembly in vivo. Builds on this initial success with CtPilB, Chapter 6 describes the development and implementation of a second HTS based on the inhibition of CtPilB as an ATPase. Screening a large chemical library led to the identification of benserazide and levodopa as CtPilB inhibitors. We show that both compounds inhibit T4P assembly in M. xanthus without any detrimental effects on bacterial growth. Furthermore we demonstrate that both levodopa and benserazide inhibit T4P-mediated motility in Acinetobacter nosocomialis, a human pathogen, providing the first evidence that the compounds identified with CtPilB can be effective against a pathogenic bacterium. Both of these studies validate the effectiveness not only of our HTSs, with of CtPilB as a model protein for the identification of PilB inhibitors. / Doctor of Philosophy / Bacteria can be motile or sessile. Motile bacteria can use hair like structures on their surface, called pili, to move in their natural environment, whereas sessile bacteria produce intricate structures attached to solid surfaces known as biofilms. Bacteria are able to switch between being motile and sessile states depending on their environment conditions. However, it isn't clear how this switch is controlled in bacteria that use pili to move. To answer this question, we studied how PilB the protein that assembles pili, might control this switching process. We specifically investigated PilB because it has two known roles. The first is that it can assemble pili, to enable pili-mediated motility. The second is that it can stimulate or promote biofilm formation. This places PilB at the intersection of these two lifestyles, suggesting that this protein may play a key role in deciding whether a bacterium is to be motile or sessile. Another important reason to understand how PilB functions is because pili are used by some antibiotic resistant pathogenic bacteria. Since PilB is essential for the formation of pili, if the actions of PilB could be blocked, bacteria would be unable to make pili. This could stop bacteria from causing disease. By searching for new chemicals which stop PilB from creating pili, we can potentially identify new drugs to treat bacterial infections.

Type IV pili

Myxococcus xanthus

PilB

biofilm

anti-virulence

Use of an Inducible Promoter to Characterize Type IV Pili Homologues in Clostridium perfringens

Hartman, Andrea H.

18 October 2012

Researchers of <i>Clostridium perfringens</i>, a Gram-positive anaerobic pathogen, were lacking a tightlyregulated, inducible promoter system in their genetic toolbox. We constructed a lactose-inducible plasmid-based system utilizing the transcriptional regulator, BgaR. Using the <i>E. coli</i> reporter GusA, we characterized its induction in three different strains of <i>C. perfringens</i>. We then used a newly-developed mutation system to create in-frame deletion mutants in three genes with homology to Type IV pilins, and we used the promoter system described above to complement the mutants. We analyzed each pilin for localization and expression, as well as tested each of the mutants for various phenotypes frequently associated with type IV pili (TFP) and type II secretion systems. PilA2, PilA3, and PilA4 localized to the poles of the cells. PilA2 was expressed in the wildtype when <i>C. perfringens</i> was grown on agar plates, and the PilA3 mutant lacked a von Willebrand factor A domain-containing protein in its secretome. We used our promoter system to express GFP-tagged versions of the TFP ATPase homologues and view them in cells growing on surfaces. We saw that PilB1 and PilB2 co-localized nearly all of the time, while a portion of PilT was independent of the PilB proteins. PilT appeared necessary for the localization of PilB, and it localized independently of TFP proteins in <i>Bacillus subtilis</i>. PilT's typical localization in <i>Bacillus subtilis</i> was disrupted when the GTPase and polymerization activity of cell division protein FtsZ was blocked, suggesting that PilT associates with cell division proteins. / Master of Science

Clostridium perfringens

Type II secretion

inducible promoter

Type IV pili

Understanding PilB, The Type IV Pilus (T4P) Assembly ATPase

Sukmana, Andreas Binar Aji

29 June 2018

The type IV pilus (T4P) is a dynamic long thin fiber found on the surface of many bacterial groups. T4P is a versatile nanomachine; it plays many important roles such as for surface attachment, virulence factor, and surface motility apparatus. This research focuses on understanding the kinetics of PilB, the T4P assembly ATPase. PilB crystal structure exhibits an elongated hexamer with 2-fold symmetry indicating a symmetric rotary mechanism model. Except for its structure, the symmetric rotary mechanism of PilB has not been demonstrated experimentally. Its conformation and relatively low activity constrained previous in vitro studies of PilB. This study identified PilB from thermophilic organism Chloracidobacterium thermophilum (Ct) to be a model for in vitro studies. An active CtPilB was successfully expressed and purified as a hexamer. Malachite green phosphate assay was used to examine CtPilB ATPase activity. The examination indicated that CtPilB is a robust ATPase with a complex kinetics profile. The profile has a stepwise incline in ATPase activity as a function of [ATP] that led to a decline in higher [ATP]. The decline was confirmed to be a substrate inhibition by the enzyme-coupled assay. As for the incline, the detailed mechanism is still less clear to explain the multiphasic profile. The overall incline did not conform with classical Michaelis-Menten kinetic but the first part of the incline was shown to conform with Michaelis-Menten kinetics. The complex kinetics profile of PilB is consistent with the symmetric rotary mechanism of catalysis. / Master of Science

Type IV Pilus

Chloracidobacterium thermophilum

PilB

ATPase

Kinetics

Characterization of Type IV Pilus System Genes and Their Regulation in Clostridium perfringens

Murray, Samantha Rose

06 June 2017

Clostridium perfringens is a Gram-positive (Gr+) anaerobic pathogen that was found to contain Type IV pilus (T4P) system genes within the genomes of all its sequenced strains. T4P are widely used in Gram-negative organisms for aggregation, biofilm formation, adherence, and DNA uptake. Because few examples of T4P-utilizing Gram-positive bacteria are studied to date, we wanted to characterize the T4P system in this Gr+ bacterium. To understand the regulation of T4P genes and therefore better understand their expression, we employed the highly powerful next-generation sequencing tool RNA-seq in a variety of conditions. RNA-seq uncovered previously unknown regulatory mechanisms surrounding T4P genes as well as provided transcriptional information for most of the genes in the C. perfringens strain 13 genome. We also utilized reporter gene assays to look at post-transcriptional regulation of T4P promoters. The wealth of RNA-seq data acted as a jumping-off point for many smaller projects involving transcriptional regulators that may influence T4P expression. We investigated a novel small RNA in close proximity to the major T4P operon, as well as two little-characterized transcriptional regulators that function in the same conditions as T4P genes. RNA-seq also provided data to develop a method for protein purification from C. perfringens without induction. / Master of Science

Clostridium perfringens

Type IV Pili

gene regulation

RNA sequencing

Type IV Pili-Dependent Secretion of Biofilm Matrix Material Proteins in Clostridium perfringens

Kivimaki, Sarah Elise

21 January 2022

Clostridium perfringens is a Gram-positive bacterium that secretes a biofilm matrix material. The goal of these experiments was to identify pilin mutants that are needed for secretion of the biofilm matrix and develop a functional model for a type II secretion system (T2SS) in C. perfringens. Protein tagging, western blot, and slot blot experiments were done to quantify protein secretion. After performing experiments using a CPE0515-FLAG construct, it was concluded from immunoblot densitometry data that, except for the pilA1 deletion mutant, none of the 18 tested pilin mutants had a statistically significant difference from the wild type (WT) with regard to protein secretion. From slot blot densitometry assays, it was concluded that the pilA1 and CPE2280 mutants showed statistically significant lower values than the WT but the pilA2 and CPE1841 mutants had values that were higher than the wild type. Testing the construct containing only CPE0514 and CPE0515-FLAG showed that CPE0516 and CPE0517 are not needed for secretion of the protein CPE0515. HA-tagged CPE0516 qualitative immunoblots showed that, unlike CPE0515, oligomerization of CPE0516 is not occurring, and that this protein likely forms a heat stable dimer. Overall, the data did not allow us to construct a T2SS model, since there were not enough proteins revealed to be involved to create a complete Type II secretion system. / Master of Science / The methods by which C. perfringens can persist and survive in environmental conditions is something that would be useful to learn more about. One of the methods that many bacteria use to survive is by creating a biofilm matrix material, which provides protection for the bacteria from environmental stresses. In this study, the goal was to determine which specific proteins are needed for the secretion of the biofilm matrix material. Using molecular biology techniques, the proteins thought to be involved in biofilm formation quantified. The results showed that while two proteins ultimately appeared to be needed for secretion, there were not enough proteins involved to create a complete model for a functional secretion system in C. perfringens.

Biofilm

C. perfringens

Gram-positive

Protein secretion

Type IV pili

Generation IV and SMR nuclear reactors as future energy sources

Nicolau Ciborro, Guillem

January 2024

As Europe confronts a substantial surge in energy demand, the pressing necessity to integrate nuclear energy and others low-carbon energy sources into the energy mix has become evident. This integration is of paramount importance to achieving the objective of zero emissions by 2050, as outlined in various European Union climate policies. The role of nuclear energy, particularly through the deployment of Small Modular Reactors and Generation IV reactors, is pivotal in ensuring a dependable and sustainable energy supply that meets rigorous environmental standards.The public perception of nuclear energy plays a critical role in its acceptance and implementation. This thesis examines the importance of societal views on nuclear power, addressing common concerns and misconceptions through transparent communication and education. Engaging the public in discussions about the advancements in nuclear technology, especially the enhanced safety features and reduced environmental impact of modern reactors, is essential for gaining widespread support. Furthermore, the development of Generation IV reactors is imperative for addressing the challenge of nuclear waste management. These advanced reactors are designed to be more efficient and generate less waste, with some concepts capable of recycling spent fuel and using it as a resource. By focusing on these technologies, it is possible to mitigate the long-term environmental impact of nuclear energy and enhance its sustainability.This research is a purely literature review that highlights the necessity of advancing nuclear technology and fostering public trust to successfully integrate nuclear energy into Europe’s future energy strategy. The achievement of a zero-emissions energy mix by 2050 will necessitate a multifaceted approach that combines technological innovation, robust regulatory frameworks, and proactive public engagement. The findings of this thesis underscore the potential of SMRs and Generation IV reactors to transform the nuclear energy landscape, making them a cornerstone of a clean and reliable energy future.

Nuclear

literature review

Generation IV

SMR

Energy Systems

Energisystem

Structural studies of titanium(IV) picolinamide alkoxide and oxide derivatives

Lord, Rianne M., Lord, S.M., Pask, C.M., McGowan, P.C.

27 April 2016

Yes / Reactions have been carried out using the titanium(IV) precursors TiCl4 and Ti(OiPr)4, with addition of two equivalents of a functionalized picolinamide ligand. The reactions with TiCl4 led to the formation of either a mononuclear titanium species, [Ti(N,O)Cl2X2] or a dinuclear titanium species [Ti(N,O)X3]2[l- O] (X = OMe or Cl), with incorporation of one picolinamide ligand. The ligand is bound to the titanium centre as the protonated amide. The reactions with Ti(OiPr)4 resulted in the formation of mononuclear titanium bis-picolinamide species [Ti(N,O)2(OiPr)2], and also dinuclear and trinuclear products, [(N,O)Ti (OiPr)2][l-OiPr]2 and [(N,O)Ti(OiPr)2]2[l-OiPr]2[(OiPr)2Ti][l3-O] respectively. In these cases the picolinamide ligand was found to be deprotonated and bound to the titanium as the iminolate. These molecules have been characterized by X-ray crystallographic analysis and structural characteristics are discussed.

Titanium

Amides

Iminolates

Isopropoxide

Catalysis

Titanium(IV) picolinamide alkoxide

Structure

Mechanistic and Cytotoxicity Studies of Group IV b-Diketonate Complexes

Lord, Rianne M., Mannion, J.J., Hebden, A.J., Nako, A.E., Crossley, B.D., McMullon, M.W., Janeway, F.D., Phillips, Roger M., McGowan, P.C.

06 1900

No / Group IV metal complexes have previously shown promise as novel anticancer agents. Here, we discuss the mechanistic and cytotoxic nature of a series of group IV b-diketonate coordination complexes. Clear evidence that the ligands are exchangeable on the metal centre and that the b-diketonate ligands can act as potential drug delivery vehicles of the group IV metal ions was obtained. When evaluated for the cytotoxicity against human colon adenocarcinoma (HT-29) and human breast adenocarcinoma (MCF-7) cell lines, a general trend of decreasing potency down the group IV metals was observed. The most promising results obtained were for the hafnium complexes, with the tris diphenyl b-diketonate hafnium complex exhibiting IC50 values of 4.9 0.9 mm and 3.2 0.3 mm against HT-29 and MCF-7, respectively, which are comparable with the activity of cisplatin against the same cell lines. This tri b-diketonate hafnium complex is the first to show potent in vitro cytotoxic activity. The results reported show that ligand design has a significant effect on the cytotoxic potential of the complexes, and that these group IV complexes warrant further evaluation as novel metal-containing anticancer agents.

Cytotoxicity

Group IV b-Diketonate Complexes

Anticancer agents

Evaluation the performance of the tin (IV) oxide (SnO2) in the removal of sulfur compounds via oxidative-extractive desulfurization process for production an eco-friendly fuel

Humadi, J.I., Issa, Y.S., Aqar, D.Y., Ahmed, M.A., Ali Alak, H.H., Mujtaba, Iqbal M.

22 September 2022

Yes / Catalysts play a vital role in petroleum and chemical reactions. Intensified concerns for cleaner air with strict environmental regulations on sulfur content in addition to meet economic requirements have generated significant interests for the development of more efficient and innovative oxidative catalysts recently. In this study, a novel homemade nano catalyst (manganese oxide (MnO2) over tin (IV) oxide (SnO2)) was used for the first time as an effective catalyst in removing dibenzothiophene (DBT) from kerosene fuel using hydrogen peroxide (H2O2) as oxidant in catalytic oxidative-extractive desulfurization process (OEDS). The catalyst was prepared by impregnation method with various amount of MnO2 loaded on SnO2. The oxidation step was carried out at different operating parameters such as reaction temperature and reaction time in batch reactor. The extractive desulfurization step was performed by using acetonitrile as solvent under several operating conditions (agitation speed and mixing time). The activity of MnO2/SnO2 catalyst in removing various sulfur compounds from kerosene fuel at the best operating conditions was investigated in this work. The results of the catalyst characterization proved that a high dispersion of MnO2 over the SnO2 was obtained. The experiments showed that the highest DBT and various sulfur compounds removal efficiency from kerosene fuel under the best operating conditions (oxidation: 5% MnO2/SnO2, reaction temperature of 75 0C, and reaction time of 100 min, extraction: acetonitrile, agitation speed of 900 rpm, and mixing time of 30 min) via the catalytic oxidative-extractive desulfurization process was 92.4% and 91.2%, respectively. Also, the MnO2/SnO2 catalyst activity was studied after six consecutive oxidation cycles at the best operating conditions, and the catalyst prove satisfactory stability in terms of sulfur compounds removal. After that, the spent catalyst were regenerated by utilizing different solvents (methanol, ethanol and iso-octane), and the experimental data explained that iso-octane achieved highest regeneration efficiency. / This study was supported by College of Petroleum Processes Engineering, Tikrit University, Iraq and Ministry of Oil, Iraq.

Nano-catalyst

Tin (IV) oxide

Manganese oxide

Oxidative- extractive desulfurization