Function, structure and evolution of the RXLR effector AVR3a of Phytophthora infestans

Bos, Jorunn Indra Berit.

January 2007

Thesis (Ph. D.)--Ohio State University, 2007. / Full text release at OhioLINK's ETD Center delayed at author's request

Interferon-gamma Mediated Host Responses to Enteric Pathogen, Citrobacter rodentium

Reid-Yu, Sarah A.

06 1900

Diarrheal disease caused by attaching and effacing pathogens, such as enteropathogenic E. coli (EPEC), is a worldwide health concern. As the second leading cause of diarrheal-related death in young children, new investigations into host defense against EPEC, as well as future therapeutics, is greatly needed. To elucidate the host immune responses to these enteric pathogens, the attaching and effacing (A/E) murine pathogen, Citrobacter rodentium, has been widely used. It is well understood that C. rodentium infection induces a robust Th1 response within the host. Yet how these pleiotropic IFNγ immune responses are initiated, propagated, and the accessory immune cell types involved remains poorly understood. In this thesis, I investigated how innate immune cell types such as natural killer cells, which are significant producers of IFNγ, mediate these Th1 directed responses. This work identified that both NK and NK-like innate lymphoid type 1 cells (ILC1s) are capable of producing IFNγ in response to C. rodentium, and NK cells rapidly increase in numbers within the colon during the early stages of infection. Depletion of these cell types causes a delayed Th1 CD4+ T cell response within the colon, resulting in increased bacterial load, and greater degree of colonic pathology at later time points. Additionally, depletion of these cells results in decreased CXCL9 chemokine expression in mice. I later determined that CXCL9 exhibited direct antimicrobial action against Citrobacter in vitro. Depletion of this chemokine in vivo, in the absence of adaptive immune responses, or its receptor CXCR3, results in increased mortality rates, elevated bacterial loads, greater degree of pathology, and deeper penetration of bacteria within the colonic crypts. These data indicate a potential direct antimicrobial role for this IFNγ-induced chemokine, independent of its known properties for the homing of T cells to the site of infection. These findings demonstrate the importance of accessory IFNγ-producing immune cells in not only mediating Th1 CD4+ T cells responses, but also other innate host defense mechanisms against A/E pathogens. / Thesis / Doctor of Philosophy (PhD)

Mathematical Modeling of Epidemics: Parametric Heterogeneity and Pathogen Coexistence

Sarfo Amponsah, Eric

January 2020

No two species can indefinitely occupy the same ecological niche according to the competitive exclusion principle. When competing strains of the same pathogen invade a homogeneous population, the strain with the largest basic reproductive ratio R0 will force the other strains to extinction. However, over 51 pathogens are documented to have multiple strains [3] coexisting, contrary to the results from homogeneous models. In reality, the world is heterogeneous with the population varying in susceptibility. As such, the study of epidemiology, and hence the problem of pathogen coexistence should entail heterogeneity. Heterogeneous models tend to capture dynamics such as resistance to infection, giving more accurate results of the epidemics. This study will focus on the behavior of multi-pathogen heterogeneous models and will try to answer the question: what are the conditions on the model parameters that lead to pathogen coexistence? The goal is to understand the mechanisms in heterogeneous populations that mediate pathogen coexistence. Using the moment closure method, Fleming et. al. [22] used a two pathogen heterogeneous model (1.9) to show that pathogen coexistence was possible between strains of the baculovirus under certain conditions. In the first part of our study, we consider the same model using the hidden keystone variable (HKV) method. We show that under some conditions, the moment closure method and the HKV method give the same results. We also show that pathogen coexistence is possible for a much wider range of parameters, and give a complete analysis of the model (1.9), and give an explanation for the observed coexistence. The host population (gypsy moth) considered in the model (1.9) has a year life span, and hence, demography was introduced to the model using a discrete time model (1.12). In the second part of our study, we will consider a multi-pathogen compartmental heterogeneous model (3.1) with continuous time demography. We show using a Lyapunov function that pathogen coexistence is possible between multiple strains of the same pathogen. We provide analytical and numerical evidence that multiple strains of the same pathogen can coexist in a heterogeneous population.

epidemic modeling

heterogeneity

heterogeneous model

multi-pathogen models

multi-strain models

pathogen coexistence

Detection of a Surrogate Biological Threat Agent (Bacillus globigii) with a Portable Surface Plasmon Resonance Biosensor

Adducci, Benjamin Augustus

08 June 2015

New methods and technology are needed to detect biological agents that threaten the health of humans and domestic animals. The bacterium Bacillus anthracis, causal agent of anthrax, has been used as a biological warfare agent. Here, we extend the work of Chinowksy et al. (2007) to the detection of a surrogate of B. anthracis, B. globigii (also known as B. atrophaeus, B. subtilis var. niger, B. subtilis var. subtilis) in a mixed sample containing two different species of Bacillus using a portable surface plasmon resonance (SPR) biosensor (SPIRIT 4.0, Seattle Sensor Systems). Two methods (direct capture and antibody injection) were used to determine the limit of detection for spores of B. globigii and to detect spores of B. globigii in a mixed sample containing at least one other Bacillus spp. Spores of B. globigii were detected on freshly coated sensors (not previously exposed to spores) with direct capture at a minimum concentration of 10^7 spores/mL, and with antibody injection at a concentration of 10^5 spores/mL. Spores of B. globigii were also detected when mixed with B. pumilus spores in the same sample at equal concentrations (107 spores/mL) using antibody injection. An SPR method using synthetic miRNA was adapted to the portable SPR unit (SPIRIT), and preliminary experiments suggested that the target sequence could be detected. SPR methods using nucleic acids have an exciting future in the detection of biological agents, such as B. anthracis. With the availability of portable instrumentation to accurately detect biological warfare agents such as B. anthracis, emergency responders can implement emergency protocols in a timely fashion, limiting the amount of people and domestic animals exposed. / Master of Science

anthrax

Bacillus anthracis

bacteria

biosecurity

biosensor

detection

pathogen

SPR

pathogen

spore

SPR

Host-pathogen interactions and conservation implications of snake fungal disease over broad geographical scales

Blanvillain, Gaelle Jh

27 June 2024

Emerging infectious diseases represent a threat to biodiversity, posing significant challenges to wildlife conservation globally. Infectious diseases can cause population declines, local extirpations and, in rare cases, complete species extinction. Among emerging pathogens, pathogenic fungi have been responsible for drastic declines in several high-profile vertebrate taxa, such as Batrachochytrium dendrobatidis causing chytridiomycosis in many species of amphibians worldwide. Recently, an emerging infectious disease, 'snake fungal disease' (SFD), caused by the fungal pathogen Ophidiomyces ophidiicola, is affecting the health of snake populations in North America by causing skin infections which can be fatal. Given the potential impact of this disease on snake biodiversity worldwide, compounded by the pressure of anthropogenic stressors that already jeopardize the viability of many snake populations, there is a clear need for ecological research in this understudied system. This dissertation is comprised of 4 data chapters focusing on the disease dynamics of snake fungal disease in Europe, and the factors resulting in differential infection. In chapter 2, I develop a large field-based data collection in 10 countries in Europe to investigate the presence of disease hotspots and the variation of disease prevalence across host species, and to examine the pathogen genotypes that are present on the landscape. I found isolated areas of disease hotspots, and models including an interactive effect of host species and which pathogen clade are present on the landscape were best at explaining disease prevalence. In chapter 3, I perform a virulence challenge assay using 120 corn snakes (Pantherophis guttatus) and 7 strains of O. ophidiicola (3 collected from Europe, 4 from the USA). This experiment reveals that pathogen genotypes associated with higher disease prevalence in Europe also have higher pathogen virulence, and that different strains from the USA show variation in virulence. These results also match both physiological host responses measured in the lab and landscape patterns of disease. In chapter 4, I explore two mitigation-driven snake translocation projects in Europe that were complicated due to O. ophidiicola outbreaks. One snake species, N. tessellata, appears highly susceptible to SFD, indicating that under stressful conditions, O. ophidiicola can cause mortality regardless of pathogen genotype, and that this snake species may be important in pathogen maintenance. Finally in chapter 5, I report the presence of a different fungal pathogen in Spain, Parannannizziopsis sp., never reported in wild snakes in Europe before. Broadly, my dissertation demonstrates coevolutionary relationships between hosts and pathogens and has important implications to snake conservation over large scales. / Doctor of Philosophy / Biodiversity conservation is under significant threat globally due to the ever-growing human population. Threats such as habitat loss, climate change, pollution and infectious diseases are all important factors that are affecting wildlife populations. Snakes, and specifically infectious diseases of snakes, have been understudied compared to that of other types of wildlife in Europe. My dissertation focuses on understanding the disease ecology and conservation implications of snake fungal disease, an infectious disease that can be life-threatening to snakes. I first developed a study of this disease in multiple countries over three years to understand how common the disease is across the landscape, which species of snakes are most infected, and how severe skin infections are. I found specific areas in Europe where disease prevalence is high and attributed these higher disease areas to specific snake species and fungal strains that interact together to cause higher infection rates (chapter 2). Secondly, I designed a controlled experimental study in the laboratory to test the capacity of different pathogenic strains, collected in Europe and the USA, to harm its host. I chose a single host species, the corn snake (Pantherophis guttatus) to test this question. I found that different pathogen strains vary in their ability to cause severe disease, and these results were confirmed with field observations. I also found that one strain collected from coastal Virginia is able to cause more severe disease when compared to all other strains (chapter 3). Finally, I found that under captive stress, strains that might not be able to cause severe disease in the wild can lead to snake mortality, specifically in one snake species that might be more susceptible than others (chapter 4). Broadly, this dissertation describes complex interactions between snakes and fungal pathogens and has relevance to reptile conservation.

Disease ecology

host-pathogen interaction

pathogen virulence

snake fungal disease

Ophidiomyces ophidiicola

An overview of emerging trends in pathogen reduction in the processing of fruit juices

Campbell, Ian Gavin A.

January 1900

Master of Science / Department of Animal Sciences and Industry Food Science / Elizabeth Boyle / Unpasteurized fruit juices have been implicated as the source of foodborne outbreaks due to pathogens such as Salmonella, Escherichia coli O157: H7 and Cryptosporidium parvum. The growth of pathogens can usually be slowed through freezing or largely eliminated through pasteurization. Although pasteurization is often effective in eliminating pathogens, it often yields undesirable flavors that are unlike those of fresh juice. Growing consumer trends towards “healthy” unpasteurized alternatives are fueling the development of alternative processing techniques. Several promising techniques for pathogen reduction in the processing of fruit juices are currently being developed. A new technique that is already being marketed worldwide is hyperbaric processing (HPP) which subjects the fruit juice to a high pressure of up to 1000 MPa. The high-pressure treatment results in up to a 7 log reduction kill in pathogens while preserving the naturally occurring flavor profile, sensory attributes and nutritional benefits. Pulsed electric fields (PEF) and ionizing radiation are also being widely explored as viable techniques to process unpasteurized fruit juices. PEF promises to be a commercially viable energy efficient alternative to pasteurization, adding only $0.03 – $0.05 per liter to final food costs. Although irradiation enjoys support for use in the processing of fruit juice by regulatory agencies, support in public opinion is lacking and hinders its growth as an alternative to pasteurization. Other experimental techniques are also present in the development pipeline. Ultrasonic radiation and high intensity pulsed light radiation are both experimental techniques that are being researched. A particularly exciting alternative is the use of plant-based antimicrobials. Several fruits and spices are known to be natural antimicrobials and are therefore being researched as alternatives to the traditional chemical preservatives.

Pathogen reduction

Fruit juice processing

Food Science (0359)

Innate host responses to Bovine Viral Diarrhea Virus

2016 February 1900

Bovine viral diarrhea virus (BVDV) is a pestivirus that suppresses the innate and adaptive host immune responses. Each of the two classified genotypes (BVDV1 and BVDV2) has two distinct biotypes – cytopathic (cp) and non-cytopathic (ncp) – and evidence has suggested that cytopathic strains may disrupt host interferon (IFN) synthesis and IFN-mediated responses. However, inconsistent results examining ncpBVDV strains have generated controversy regarding whether they also exhibit this capability. The purpose for this study was to determine the occurrence and functionality of IFN-induced responses within the serum cattle infected with ncpBVDV2-1373. Specifically, this involved analysing the changes in both the serum levels of IFN-α and IFN-γ and the expression of genes that are classically regulated by these cytokines. Serum analysis showed that the infected cattle induced both serum IFN-α and IFN-γ during BVDV infection while PBMC analysis showed increased expression of genes that classically respond to IFN-α – Mx-1, OAS-1, and STAT-1 – and IFN-γ – SOCS-1 and SOCS-3. These findings are supported by temporal kinome analysis, which verified activation of the JAK-STAT signalling network within the PBMCs of the virus-infected animals. In addition to establishing evidence for its synthesis, results from this challenge identified IFN-γ as a possible indicator of animal mortality as analysis of its change within the non-surviving, infected animals was statistically greater than the levels of the surviving, infected animals. Collectively, these results demonstrate 1373-mediated induction of, and host cell response to, both IFN-α and IFN–γ, and the potential for IFN-γ to be a predictive marker for mortality during BVDV infection.

Bovine Viral Diarrhea Virus

Kinome

Interferon

Host-Pathogen Interaction

Proteogenomic mapping of Mycoplasma hyopneumoniae virulent strain 232

Pendarvis, Ken, Padula, Matthew, Tacchi, Jessica, Petersen, Andrew, Djordjevic, Steven, Burgess, Shane, Minion, F.

January 2014

BACKGROUND:Mycoplasma hyopneumoniae causes respiratory disease in swine and contributes to the porcine respiratory disease complex, a major disease problem in the swine industry. The M. hyopneumoniae strain 232 genome is one of the smallest and best annotated microbial genomes, containing only 728 annotated genes and 691 known proteins. Standard protein databases for mass spectrometry only allow for the identification of known and predicted proteins, which if incorrect can limit our understanding of the biological processes at work. Proteogenomic mapping is a methodology which allows the entire 6-frame genome translation of an organism to be used as a mass spectrometry database to help identify unknown proteins as well as correct and confirm existing annotations. This methodology will be employed to perform an in-depth analysis of the M. hyopneumoniae proteome.RESULTS:Proteomic analysis indicates 483 of 691 (70%) known M. hyopneumoniae strain 232 proteins are expressed under the culture conditions given in this study. Furthermore, 171 of 328 (52%) hypothetical proteins have been confirmed. Proteogenomic mapping resulted in the identification of previously unannotated genes gatC and rpmF and 5-prime extensions to genes mhp063, mhp073, and mhp451, all conserved and annotated in other M. hyopneumoniae strains and Mycoplasma species. Gene prediction with Prodigal, a prokaryotic gene predicting program, completely supports the new genomic coordinates calculated using proteogenomic mapping.CONCLUSIONS:Proteogenomic mapping showed that the protein coding genes of the M. hyopneumoniae strain 232 identified in this study are well annotated. Only 1.8% of mapped peptides did not correspond to genes defined by the current genome annotation. This study also illustrates how proteogenomic mapping can be an important tool to help confirm, correct and append known gene models when using a genome sequence as search space for peptide mass spectra. Using a gene prediction program which scans for a wide variety of promoters can help ensure genes are accurately predicted or not missed completely. Furthermore, protein extraction using differential detergent fractionation effectively increases the number of membrane and cytoplasmic proteins identifiable my mass spectrometry.

Mycoplasma hyopneumoniae

Proteome

Swine pathogen

Proteogenomic

Mapping

Mass spectrometry

Genome wide association mapping and assessment of allelic variation in strigolactone synthesis genes involved in rice plant parasite interactions

Dimkpa, Stanley Obumneke Nyebuhi

January 2014

No description available.

580

The Niches of Bacterial Populations in Productive Waters : Examples from Coastal Waters and Four Eutrophic Lakes

Eiler, Alexander

January 2006

Recent research in microbial ecology has focused on how aquatic bacterial communities are assembled. Only a few of these studies follow a “Gleasonian” approach where the roles of single bacterial populations are in focus. In this thesis, novel molecular tools were used to describe the distribution and evolutionary relationships of microbes in productive aquatic environments. Many new phylogenetic groups of bacteria were identified, likely representing bacterial populations restricted to productive freshwaters. I also addressed the dynamics and functional role of individual bacterial populations in eutrophic lakes and brackish environments with a focus on either biogeochemically significant or potentially pathogenic representatives. Flavobacteria blooms were observed, on occasions characterized by high heterotrophic production. In addition to high temporal dynamics microbial community composition and function differed on the spatial scale, as exemplified by free-living and Cyanobacteria-associated habitats. At the community scale, microbial processes, such as biomass production and substrate uptake could be predicted from the presence and absence of individual bacterial populations. I also studied the niches of potentially pathogenic Vibrio populations in various coastal waters. Using a novel culture-independent method, a V. cholerae population was detected along the entire Swedish coastline. Results from an environmental survey and a laboratory mesocosm experiment reveal that phytoplankton-derived dissolved organic matter enhance the growth of V. cholerae and other Vibrio spp. and hence create a largely overlooked niche for these heterotrophic bacteria. This thesis and future work on the role of individual bacterial populations will facilitate predictions of biogeochemical cycles and the distribution of bacteria in the context of global climate change and local eutrophication.

Ecology

diversity

16S rRNA

phytoplankton

bloom

pathogen

carbon cycle

Ekologi