INSIGHTS INTO KEY GENE REGULATORY NETWORKS IN <em>BORRELIA BURGDORFERI</em>

Arnold, William Kenneth

01 January 2018

Gene regulatory networks are composed of interconnected regulatory nodes created by regulatory factors of multiple types. All organisms finely tune gene expression in order to adapt to and survive within their current niche. Obligate parasitic bacteria are under extreme pressure to quickly and appropriately adapt their gene regulatory programs in order to survive within their given host. Borrelia burgdorferi is one such organism and persists in nature by alternating between two hosts; Ixodes spp. ticks and small vertebrate animals. These two hosts represent drastically different environments; requiring a unique gene regulatory program to survive and transmit between them. Microbiologists have long sought to better understand exactly what stimuli pathogens sense and how that information is relayed in to physiologic adaptation. In this work I aimed to examine two parts of this interesting field. First, I sought to better understand the stimuli B. burgdorferi sense in order to adapt to their hosts by testing several hypotheses centered on the general notion that B. burgdorferi senses both internal and external metabolic cues as primary signals for adaptation. I demonstrated that a second messenger system immediately downstream of a critical metabolic pathway is important during vertebrate infection and that a key regulator of virulence is itself regulated by a factor involved in DNA replication. Second, I sought to better define the topology of gene regulatory networks, known and unknown, that are important for the ability of the bacteria to adapt. The work in this section focus on the idea that B. burgdorferi gene regulatory networks are extremely complex and are not currently well defined in the literature. My studies revealed that B. burgdorferi possesses a large number of previously undefined regulatory targets, including extended 5’ and 3’ UTRs of known genes, and encodes several hundred-putative small non-coding RNAs. Furthermore, I demonstrate that two essential regulatory factors share substantial, independent, overlap in their regulons highlighting the still undefined complexity of regulatory networks at play in B. burgdorferi.

pathogen

gene regulatory networks

gene regulation

growth rate

bacteria

Bacteriology

Microbial Physiology

Symbiosis in Archaea: Functional and Phylogenetic Diversity of Marine and Terrestrial Nanoarchaeota and their Hosts

St. John, Emily Joyce

13 March 2019

The Nanoarchaeota are an enigmatic lineage of Archaea found in deep-sea hydrothermal vents and geothermal springs across the globe. These small (~100-400 nm) hyperthermophiles live ectosymbiotically with diverse hosts from the Crenarchaeota. Despite their broad distribution in high-temperature environments, very few Nanoarchaeota have been successfully isolated in co-culture with their hosts and nanoarchaeote genomes are poorly represented in public databases. However, the Nanoarchaeota provide unique insights into the structure and function of symbiosis in the archaeal domain. This study describes novel nanoarchaeotes from multiple geothermal habitats, using a combination of direct cultivation techniques and genomic analysis. A new nanoarchaeote from a New Zealand hot spring, Candidatus Nanoclepta minutus, was isolated in co-culture with its host. Like other terrestrial Nanoarchaeota, Cand. Ncl. minutus harbors genes for gluconeogenesis and archaeal flagella. Zestosphaera tikiterensis, the New Zealand host, was also isolated in pure culture and characterized. Phylogenetic analysis showed that both Cand. Ncl. minutus and Z. tikiterensis are new genera in the Nanoarchaeota and Crenarchaeota, respectively. Metagenome-assembled genomes (MAGs) from the Nanoarchaeota were also recovered from deep-sea hydrothermal vent sites. These MAGs capture a wide range of diversity in the Nanoarchaeota, representing three new species and two novel genera. Key nanoarchaeotal features were identified in the MAGs, including marker genes for archaeal flagella, gluconeogenesis and CRISPR-Cas regions. These studies greatly contribute to our understanding of nanoarchaeotal ecophysiology and provide key insights into the coding potential and diversity of Nanoarchaeota and their hosts.

Host-bacteria relationships

Thermophilic bacteria -- New Zealand

Bacteriology

Biology

Microbiology

ASSESSMENT OF A PREDICTED DIGUANYLATE CYCLASE IN TREPONEMA DENTICOLA

Patel, Dhara T

01 January 2018

Periodontal disease is a progressive inflammatory condition that is characterized by the reabsorption of alveolar bone, the destruction of connective tissue, and edentulism. It is caused by a dysbiosis in the oral microbiome as a result of a shift from a Gram-positive aerobic bacterial population, to one that becomes more Gram-negative and anaerobic. Treponema denticola is thought to drive this diseased state based on its role as a keystone periopathogen. A major component of T.denticola’s invasiveness is its motility, which allows the spirochete to penetrate and disseminate through tissues. This motility, which has been seen to be crucial to the invasiveness in other spirochetes through deletion studies, is often regulated by the second messenger, c-di-GMP. In this study, biochemical and biophysical assays were utilized to determine that the predicted diguanylate cyclase TDE0125 converts GTP to c-di-GMP. This elucidates further function of the c-di-GMP regulatory network in T. denticola.

Treponema denticola

Diguanylate cyclase

c-di-GMP

TDE0125

Spirochete

Bacteriology

Microbiology

The Anaplasma phagocytophilum adhesin Asp14 directs PDI-mediated disulfide reduction to promote infection

Green, Ryan S

01 January 2019

Obligate intracellular pathogens must invade host cells to survive and pose a global health risk. As such, internalization is a critical life stage and represents an excellent therapeutic target. Oxidoreductase exploitation is a thematic invasion strategy among obligate intracellular pathogens. Delineating the mechanisms and proteins mediating this exploitation could identify novel therapeutic targets for many important pathogens. Anaplasma phagocytophilum infects neutrophils by an incompletely defined mechanism, resulting in the emerging potentially fatal disease, human granulocytic anaplasmosis. The bacterial adhesin, Asp14, contributes to invasion by virtue of its C-terminus engaging an unknown receptor. Yeast two-hybrid analysis identified protein disulfide isomerase (PDI) as a putative Asp14 binding partner. Co-immunoprecipitation confirmed this interaction and identified the Asp14 C-terminus as critical to it. PDI reductase activity inhibition impaired bacterial infection of, but not binding to, host cells. A. phagocytophilum failed to productively infect myeloid-specific PDI conditional knock-out mice. This is the first demonstration of microbial PDI exploitation in vivo. Infection of PDI inhibited cells was rescued when bacterial, but not host surfaces were reduced with the reducing agent tris(2-carboxyethyl)phosphine (TCEP). Furthermore, TCEP restored bacterial infectivity after Asp14 inhibition using an antibody that reduces infection. Mutational analyses identified Asp14 residues critical for binding PDI. These data demonstrate that Asp14 binds and brings PDI to disulfide bonds within A. phagocytophilum surface protein(s) that it reduces, enabling infection. Targeting the Asp14 C-terminus could benefit approaches to prevent/treat granulocytic anaplasmosis. A similar approach would identify proteins from other obligate intracellular pathogens that could prove to be protective targets.

Anaplasma phagocytophilum

Protein disulfide isomerase

intracellular bacterium

rickettsiales

internalization

adhesin

Bacteriology

Novel Role of Pseudomonas Aeruginosa LptD Operon

Pandey, Sundar

29 June 2018

Pseudomonas aeruginosais an opportunistic pathogen that infects cystic fibrosis (CF) patients contributing to their high morbidity and mortality. P. aeruginosaundergoes a phenotypic conversion in the CF lung, from nonmucoid to mucoid, by constitutively producing a polysaccharide called alginate. These mucoid strains often revert to nonmucoid in vitrodue to second-site suppressor mutations. We hypothesized that mapping these mutations would lead to the identification of novel genes involved in alginate production. In a previous study, a mucoid strain, PDO300 (PAOmucA22), was used to isolate suppressors of alginate phenotype (sap). One of the uncharacterized nonmucoid revertants, sap27, is the subject of this study. The mucoid phenotype in sap27was restored by pMO012217 from a minimal tiling path cosmid library. The cosmid pMO012217 harbors 18 P. aeruginosaopen reading frames (ORF). The cosmid was mutagenized with a transposon to map the contributing gene. It was mapped tolptD(PA0595) encoding lipopolysaccharide transport protein. E. coliLptD transports lipopolysaccharide to the outer leaflet of the outer membrane. The Alg+phenotype was restored upon complementation with P. aeruginosa lptDalone, suggesting that sap27likely harbor a chromosomal mutation inlptD. Sequencing analysis of sap27showed the presence of a mutation not in lptDbut in algO, which encodes a periplasmic protease protein. This suggests LptD is able to bypass analgO mutation by positively regulating alginate production. The lptD is a part of a three-gene operon lptD-surA-pdxA. SurA is an essential protein for survival in starvation and a major chaperone protein for all outer membrane proteins and PdxA is a NAD-dependent dehydrogenase and is involved in the vitamin B6biosynthetic pathway. Pyridoxal 5’-phosphate (PLP) is the active form of vitamin B6.P. aeruginosagrown in a media supplemented with PLP increased production of pyocyanin, a virulence factor. The PLP and aromatic amino acids are synthesized from a common precursor chorismic acid. We demonstrated an increase in pyocyanin production when the bacteria were cultured supplemented by the aromatic amino acids phenylalanine. We concluded that the lptDoperon plays a role in the P. aeruginosavirulence by regulating alginate and pyocyanin production.

LptD

SurA

PdxA

Outer membrane protein

alginate

CF

Vitamin B6

PLP

Bacteriology

Biology

Microbiology

Pathogenic Microbiology

Affinity Purification and Characterization of <em>E. coli</em> Molecular Chaperones

Nam, Seung-Hee

01 May 2002

The molecular chaperones are a group of proteins that are effective in vitro and in vivo folding aids and show a well documented affinity for proteins lacking tertiary structure. Heat-induced Escherichia coli BL21 cell lysate (10 mg protein) was applied to immobilized ɑ-casein (45 mg/g beads) or β-casein (30 mg/g beads) column. After removing a majority of nonspecifically bound proteins with 1 M NaCl, the molecular chaperones were eluted with cold water, 1 mM Mg-ATP, or 6 M urea. Western analysis identified five Escherichia coli molecular chaperones including DnaK, DnaJ, GrpE, GroEL, and GroES. Among samples, ATP eluates showed the highest chaperone purity of 80-87% followed by cold water eluates with 62-68% purity. The β-Casein column showed a higher binding capacity than the ɑ-casein column since β-casein urea eluates contained 3.18 mg total protein (or 58% chaperone) compared to a-casein urea eluates with 2.68 mg total protein (or 32% chaperone). For strain comparison, Escherichia coli NM522 eluates showed more unidentified proteins in cold water eluates from both affinity columns. Chaperones were induced from BL21 strain with three treatments: heat shock at 39°C, heat shock at 42°C, and alcohol shock with 3% ethanol (v/v). Lysates were applied to an immobilized β-casein (30 mg/g beads) column. The molecular chaperones were eluted with cold water or 1 mM Mg-ATP after washing with 1 M NaCl. The purity of eluted chaperones was 58% with cold water and 100% with Mg-ATP. The treatment at 42°C was the most efficient for chaperone induction with highest chaperone yield of 1.0 mg among samples. Refolding denatured carbonic anhydrase B enzyme in the presence of Mg-ATP resulted in a 97% recovery of heat-denatured enzyme and a 68% recovery of chemically denatured enzyme. It was concluded that the novel casein affinity chromatography is a rapid and efficient method for purification of chaperone. The affinity purified chaperones were effective in vitro folding aids.

Affinity purification

characterization

E. coli

molecular chaperones

Bacteriology

Microbiology

Organismal Biological Physiology

Rapid Detection of <em>Listeria monocytogenes</em>

Lippens, Wim

01 May 2003

Listeria monocytogenes is a foodbome pathogen that can cause severe illness and even death. It is found in dairy and meat products. The focus is on rapid detection since conventional methods are time consuming (4-5 days). Pre-enrichment steps, as part of those methods, are time consuming. Our objective was to develop a detection system without a pre-enrichment step, giving a final result within 2 to 4 h. In the concept of "the need for speed," a detection system with an antibody-based capture technique, followed by polymerase chain reaction (PCR), was developed. Glass beads coated with a Listeria polyclonal antibody were added to the food sample. After a static incubation/capturing step, beads-cell complexes were separated from the food, and boiled to lyse the cells and release the DNA. In a final PCR/electrophoresis step the DNA samples were analyzed. The use of a flow-based capturing system (ImmunoFlow) was also investigated. Using a bead-antibody complex in this ImmunoFlow setup has several advantages, including the possibility of concentrating the microorganisms out of large food samples (with flow through setup), the exclusion of a pre-enrichment step, and the potential for automation. Besides buffer solution (Tris), different kinds of milk, e.g., pasteurized, Ultra High Temperature (UHT), and raw milk, were also investigated. The detection limit in buffer solution was 1 x 106 CFU/ml no matter if the ImmunoFlow system or the static incubation was used. For the different pasteurized milk samples, the detection limit varied between 1 x 107 and 1 x 108 cells/ml in the static procedure. For UHT and raw milk, however, capturing of Listeria monocytogenes cells was not possible in the static or the ImmunoFlow setup. In conclusion, we developed a rapid and specific detection system for Listeria monocytogenes at high concentration in pasteurized milk using a static capturing procedure. The total test time for this detection system is less than 4 h, which is much faster than the present detection systems (which are using an enrichment step prior to testing). Implementing a real-time PCR system after capture would further reduce this detection time.

Rapid Detection

Listeria monocytogenes

foodborne pathogen

dairy

meat

Bacteriology

Food Microbiology

Microbiology

Direct selection and phage display of the Lactobacillus rhamnosus HN001 secretome : a thesis presented to Massey University in partial fulfillment of the requirements for the degree of Doctor of Philosophy

Jankovic, Dragana

January 2008

Bacteria communicate with their hosts in part via surface, secreted and transmembrane proteins (collectively the secretome) resulting in probiotic (beneficial) or pathogenic (harmful) outcomes to the host. Therapeutic benefits of probiotic bacteria have been shown previously, but the molecular mechanisms and the health-promoting effector components involved are still being elucidated. Some evidence suggests that probiotic bacteria can competitively adhere to intestinal mucus and displace pathogens. The adherence of probiotic bacteria to human intestinal mucus and cells appears to be mediated, at least in part, by secretome proteins. Secretome proteins-encoding open reading frames can be identified in bacterial genome sequences using bioinformatics. However, functional analysis of the translated secretome is possible only if many secretome proteins are expressed and purified individually. Phage display technology offers a very efficient way to purify and functionally characterise proteins by displaying them on the surface of the bacteriophage. While a phage display system for cloning secretome proteins has been previously reported it is not efficient for enrichment and display of Gram-positive secretome proteins. In this study a new phage display system has been developed and applied in direct selection, identification, expression and purification of Gram-positive Lactobacillus rhamnosus strain HN001 secretome proteins. The new phage display system is based on the requirement of a signal sequence for assembly of sarcosyl-resistant filamentous phage virions. Using this system 89 secretome open reading frames were identified from a library of only 106 clones, performing at least 20-fold more efficiently than the previously reported enrichment method. Seven of the identified secretome proteins are unique for L. rhamnosus HN001. A L. rhamnosus HN001 shot-gun phage display library was also constructed to capture proteins that mediate adhesion or aggregation, initial steps in establishing host-microbe contact or forming multicellular aggregates, both of which may lead to beneficial effects – colonisation of the gastro-intestinal tract and exclusion of pathogens. In search for proteins involved in adhesion, a L. rhamnosus HN001 shot-gun phage display library was screened against the human extracellular matrix component fibronectin commonly used as binding target by bacteria that colonise diverse tissues. This screen selected, instead of a fibronectin-binding protein, a protein that binds to avidin, used to immobilise biotinylated fibronectin. Affinity screening of the shot-gun library for binding to L. rhamnosus HN001 cells identified a secretome protein, Lrh33, as an HN001-cell surface binding protein. This protein contains two bacterial immunoglobulin-like domains type 3. Analysis of phage-displayed nested deletions of Lrh33 determined that the proximal (N-terminal) immunoglobulin-like domain is not sufficient for binding; only the constructs displaying both domains demonstrated binding to HN001. Lrh33 does not have any similarity to previously identified Lactobacillus-binding proteins and no match in the NCBI database (at a cutoff value of > e-13), hence it represents potentially a new type of bacterial auto-aggregation protein.

probiotic bacteria

secretome proteins

Studies on the stress response in Fusobacterium nucleatum.

Zilm, Peter S.

January 2008

Fusobacterium nucleatum is a saccharolytic Gram-negative anaerobic organism belonging to the so-called ‘orange complex’ which is believed to play an important role in the microbial succession associated with the pathogenesis of periodontal disease. Its genome contains niche-specific genes shared with the other inhabitants of dental plaque, which may help to explain its ability to survive and grow in the changing environmental conditions experienced in the gingival sulcus during the progression from health to disease. The pH of the gingival sulcus increases during the development of periodontitis and is thought to occur by the metabolism of nutrients supplied by gingival crevicular fluid. Studies have shown that F. nucleatum is partly responsible for the rise in pH and have concluded that in comparison to other plaque inhabitants, F. nucleatum has the greatest ability to neutralise acidic environments. In common with a number of other oral bacteria, F. nucleatum has also been shown to produce intracellular polyglucose (IP) from simple sugars such as glucose, galactose and fructose. Its response and adaptation to stressful environmental conditions such as pH is unknown. The overall aim of this study was, therefore, to determine how F. nucleatum copes with environmental stresses induced by pH changes. F. nucleatum was grown by continuous culture in a chemically defined medium at a growth rate corresponding to those measured in vivo. The effect on protein expression, and IP synthesis was examined during steady-state growth at high (>7.2<7.8) or low pH (pH 6.4). The present study also investigated the response of F. nucleatum to growth at pH 8.2. It was found that the organism grew as a biofilm and this corresponded with an increase in cellular hydrophobicity and decreased IP levels. Optimal growth pH’s differed between the different sub-species used in this study. In response to pH stress, F. nucleatum changed its amino acid and glucose utilisation and increased IP synthesis at the expense of cell numbers. Pulsing the chemostat with glutamic acid or serine produced an increase in IP synthesis and the pattern of end-products observed was dependent upon the amino acid being fermented. The effect on IP synthesis in response to increased levels of exogenous fermentable amino acids was also compared during concomitant fructose or glucose fermentation. Growth media containing fermentable amino acids and supplemented with fructose produced higher cell numbers and non-detectable levels of IP compared to media containing glucose. The differential expression of cytoplasmic- and cell envelope-proteins induced by changes in pH were identified by two-dimensional gel electrophoresis. The results represent the first proteomic investigation of F. nucleatum. Twenty-two cytoplasmic proteins were found to have altered expression in response to external pH. At low (sub-optimal) pH, proteins associated with the generation of ATP and ammonia were up-regulated, the latter contributing to the alkalinisation of the gingival sulcus. Conversely, neutral to alkaline pH conditions led to the upregulation of enzymes involved in energy storage. The study also identified several proteins associated with iron limitation and fatty acid synthesis which might not otherwise have been identified as part of the pH-dependent response. In response to growth at pH 7.8, 14 cell envelope proteins were identified as having significantly altered expression. Down-regulated proteins included those associated with uptake of C4 di-carboxylates and phosphorus, a potential membrane protease and an enzyme associated with amino acid fermentation. The up-regulation of a transcriptional regulator linked to the repression of sugar metabolism was also reported along with proteins linked to the transport of iron. The periplasmic chaperone, peptidyl prolyl cis trans isomerase, which is responsible for the folding of outer membrane proteins, was also found to be up-regulated. In conclusion, the proteomic investigation of protein expression by F. nucleatum identified gene products which form part of the organism’s coordinated stress response to changes in environmental pH. In addition to these, the physiological based studies also presented help to explain the organism’s persistence during the transition from health to disease in vivo. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1339503 / Thesis (Ph.D.) - University of Adelaide, Dental School, 2008

Caractérisation d'une bactériocine produite par une bactérie lactique Leuconostoc pseudomesenteroides isolée du boza

Makhloufi, Kahina Maya

08 July 2011

Les bactéries lactiques préviennent la contamination de produits alimentaires par des bactéries pathogènes en inhibant leur prolifération, essentiellement par la production d'acide lactique et de peptides antimicrobiens nommés bactériocines. Les bactériocines sont synthétisées par voie ribosomique. Elles sont actives contre des bactéries phylogénétiquement proches incluant des pathogènes tels que Listeria et Enterococcus. Notre étude a porté sur l'isolement et la caractérisation d'une bactériocine produite par la souche KM432Bz isolée d'une boisson fermentée des Balkans, le boza et que nous avons identifiée comme un Leuconostoc pseudomesenteroides. Des analyses structurales par spectrométrie de masse et dégradation d'Edman de la bactériocine produite par Ln. pseudomesenteroides KM432Bz ont montré que sa structure primaire était similaire à celles de deux bactériocines de classe IIa, les leucocines A et B et à la leucocine A-QU15 récemment découverte. Le système génétique impliqué dans la biosynthèse de cette leucocine a été identifié et analysé. Le gène codant la préleucocine KM432Bz est identique à ceux codant les préleucocines B et A-QU15. La leucocine produite par la souche KM432Bz présente un spectre d'activité dirigé contre des espèces proches de la souche productrice telles que Lactobacillus, Leuconostoc et Weissella ainsi que des espèces pathogènes appartenant aux genres Listeria, Enterococcus et Streptococcus avec des concentrations minimales inhibitrices comprises entre 0,08 et 10 μM. Par ailleurs, il a été montré que le facteur de transcription s54, impliqué dans la transcription de la mannose perméase du système phosphotransférase, est impliqué dans la sensibilité de Listeria monocytogenes à cette bactériocine.

Peptide antimicrobien

bactériocine

leucocine

bactérie lactique

système génétique

Et Man