Functional Changes in the Gut Microbiome Contribute to Transforming Growth Factor β-Deficient Colon Cancer

Daniel, Scott G., Ball, Corbie L., Besselsen, David G., Doetschman, Tom, Hurwitz, Bonnie L.

26 September 2017

Colorectal cancer (CRC) is one of the most treatable cancers, with a 5-year survival rate of similar to 64%, yet over 50,000 deaths occur yearly in the United States. In 15% of cases, deficiency in mismatch repair leads to null mutations in transforming growth factor beta (TGF-beta) type II receptor, yet genotype alone is not responsible for tumorigenesis. Previous work in mice shows that disruptions in TGF-beta signaling combined with Helicobacter hepaticus cause tumorigenesis, indicating a synergistic effect between genotype and microbial environment. Here, we examine functional shifts in the gut microbiome in CRC using integrated - omics approaches to untangle the role of host genotype, inflammation, and microbial ecology. We profile the gut microbiome of 40 mice with/without deficiency in TGF-beta signaling from a Smad3 (mothers against decapentaplegic homolog-3) knockout and with/without inoculation with H. hepaticus. Clear functional differences in the microbiome tied to specific bacterial species emerge from four pathways related to human colon cancer: lipopolysaccharide (LPS) production, polyamine synthesis, butyrate metabolism, and oxidative phosphorylation (OXPHOS). Specifically, an increase in Mucispirillum schaedleri drives LPS production, which is associated with an inflammatory response. We observe a commensurate decrease in butyrate production from Lachnospiraceae bacterium A4, which could promote tumor formation. H. hepaticus causes an increase in OXPHOS that may increase DNA-damaging free radicals. Finally, multiple bacterial species increase polyamines that are associated with colon cancer, implicating not just diet but also the microbiome in polyamine levels. These insights into cross talk between the microbiome, host genotype, and inflammation could promote the development of diagnostics and therapies for CRC. IMPORTANCE Most research on the gut microbiome in colon cancer focuses on taxonomic changes at the genus level using 16S rRNA gene sequencing. Here, we develop a new methodology to integrate DNA and RNA data sets to examine functional shifts at the species level that are important to tumor development. We uncover several metabolic pathways in the microbiome that, when perturbed by host genetics and H. hepaticus inoculation, contribute to colon cancer. The work presented here lays a foundation for improved bioinformatics methodologies to closely examine the cross talk between specific organisms and the host, important for the development of diagnostics and pre/probiotic treatment.

Helicobacter hepaticus

Smad3

bioinformatics

butyrate

colon cancer

gut inflammation

gut microbiome

host-pathogen interactions

metagenomics

metatranscriptomics

polyamines

The Starch Granule Surface: Technological and Biological Implications of Puroindoline and Host-pathogen Interactions

Wall, Michael L.

January 2011

The sun is the primary source of all chemical energy on the planet. Starch granules have evolved as storage deposits for captured light energy. Many complex biological functions take place at the starch granule surface, including starch granule metabolism and defense. The starch granule-associated protein puroindoline is a known antimicrobial with unique functional and biological properties, attributed to the presence of a unique tryptophan-rich domain. To test puroindoline's tight association, puroindoline removed from the starch granule surface during water-washing was assessed. Washing more than eight times failed to further reduce puroindoline content of starch granules, suggesting a strong association of puroindoline with the starch granule surface. To identify the tryptophan-rich domain tightly associated with the starch granule surface, we used a combination of in situ tryptic digestion and mass spectrometry. We identified the tryptophan-rich domain of puroindoline directly bound to the starch granule surface of wheat. This is the first instance of the tryptophan-rich domain directly observed at the starch granule surface. In addition, using mass spectrometry, we determined that during development and maturation, wheat seeds appear to have resisted infection and lysed the pathogens where, upon desiccation, the molecular evidence remained fixed at the starch granule surface. Proteins with known antimicrobial activity were identified, as well as several proteins from the plant pathogens Agrobacterium tumefaciens, Pectobacterium carotovorum, Fusarium graminearum, Magnaporthe grisea, Xanthomonas axonopodis, and X. oryzae. Future characterization may reveal previously unknown host-pathogen interactions. Finally, we have demonstrated that puroindoline, when expressed in the seeds of transgenic corn, will localize and associate with the starch granule surface in a pattern similar to the puroindoline expression pattern observed in wheat. Surprisingly, puroindoline expression in transgenic corn is correlated with an increase in total seed oil content.

puroindoline

host-pathogen interactions

mass spectrometry

wheat

corn

microscopy

starch granule

triticum aestivum

zea mays

defense

pathogen

Survie intracellulaire, effets cytopathiques et virulence de Vibrio tasmaniensis LGP32, pathogène de l’huître Crassostrea gigas / Intracellular survival, cytopathic effects and virulence of Vibrio tasmaniensis, a pathogen of Crassostrea gigas oyster

Vanhove, Audrey

11 December 2014

Des souches de Vibrio appartenant au clade Splendidus sont retrouvées de manière récurrente lors des mortalités estivales d'huîtres juvéniles. La souche V. tasmaniensis LGP32 est un pathogène intracellulaire facultatif des hémocytes d'huître, dont elle altère les fonctions de défense. Nous montrons ici que LGP32 se comporte comme un pathogène intravacuolaire qui survit au sein de larges vacuoles intrahémocytaires. Il induit des effets cytopathiques tels qu'une perméabilisation membranaire et un lessivage du contenu cytosolique des hémocytes. Cette cytotoxicité est dépendante de l'invasion hémocytaire. Par ailleurs, à l'intérieur du phagosome, LGP32 sécrète des vésicules de membrane externe (OMVs). Chez LGP32, ces OMVs jouent un rôle protecteur contre les défenses de l'hôte et servent de véhicules pour la délivrance de facteurs de virulence aux cellules de l'hôte. En effet, elles sont capables de titrer les peptides antimicrobiens et présentent un fort contenu en hydrolases (25% du protéome des OMVs). Une sérine protéase, nommée Vsp car elle est uniquement sécrétée par voie vésiculaire participe à la virulence de LGP32 en infections expérimentales mais ne dégraderait pas les peptides antimicrobiens. Par une approche transcriptomique, nous avons identifié une série de gènes impliqués dans la réponse anti-oxydante et l'efflux de cuivre, qui sont surexprimés dans les stades intracellulaires précoces de LGP32. La génomique fonctionnelle a montré que ces deux fonctions importantes sont requises pour la survie intracellulaire, la cytotoxicité et la virulence de LGP32. Leur grande conservation parmi les vibrios laisse supposer qu'elles puissent contribuer à la survie intracellulaire d'autres espèces de Vibrio. / Vibrio strains belonging to the Splendidus Clade have been repeatedly found in juvenile diseased oysters affected by summer mortalities. V. tasmaniensis LGP32 is an intracellular pathogen of oyster hemocytes which has been reported to alter the oxidative burst and inhibit phagosome maturation. We show here that LGP32 behaves as an intravacuolar pathogen that survives within large cytoplasmic vacuoles. LGP32 induces cytotoxic effects such as membrane disruptions and cytoplasmic disorders. Cytotoxicity was shown to be entirely dependent on LGP32 entry into hemocytes. Moreover, LGP32 releases outer membrane vesicles (OMVs) inside the phagosome. LGP32 OMVs were found to be protective against host defenses and to serve as vehicles for the delivery of LGP32 virulence factors to oyster immune cells. Indeed, OMVs conferred a high resistance to antimicrobial peptides. They also displayed a high content in hydrolases (25 % of total proteome) among which a serine protease, named Vsp for vesicular serine protease, was found to be specifically secreted through OMVs. Vsp was shown to participate in the virulence phenotype of LGP32 in oyster experimental infections but did not degrade AMPs entrapped in OMVs. By developing a transcriptomic approach, we identified a series of Vibrio antioxidant and copper efflux genes whose expression is strongly induced within oyster hemocytes. Construction of isogenic deletion mutants showed that resistance to reactive oxygen species and copper efflux are two important functions required for LGP32 intracellular survival, cytotoxic effects and virulence. Their high conservation among vibrios suggests they could contribute to intracellular survival of other Vibrio species.

Interaction hôte-Pathogène

Vibrio

Processus infectieux

Mécanismes d’échappement

Immunité innée

Host-Pathogen interaction

Vibrio

Infectious process

Escape

Innate immunity

574

Inhibition of Epidermal Growth Factor Receptor (EGFR) Leads to Autophagy-mediated Killing of Toxoplasma gondii and Control of Disease

Lopez Corcino, Yalitza Z.

28 August 2019

No description available.

Biomedical Research

Immunology

Microbiology

Pathology

Parasitology

EGFR

Toxoplasma gondii

autophagy

apicomplexan

host-pathogen ineraction

cell signaling

immunology

Hybridations inter-spécifiques chez le pommier et co-évolution hôte-pathogène / Inter-specific hybridizations in apple trees and host-pathogen co-evolution

Feurtey, Alice

29 November 2016

Dans une première partie de mon projet de thèse, je me suis intéressée aux hybridations interspécifiques et à l’histoire évolutive des espèces de pommiers en Europe. L’analyse de génomes complets m’a permis de confirmer que l’ancêtre du pommier cultivé est bien le pommier sauvage asiatique M. sieversii, mais aussi que de nombreuses variétés cultivées originaires de l’Europe forment un groupe génétique distinct de cette espèce sauvage. Ces variétés montrent des traces d’introgressions par le pommier sauvage européen M. sylvestris et une structuration de populaton selon un axe est-ouest. Les introgressions depuis le pommier cultivé sont également abondantes dans les populations de pommier sauvage européen M. sylvestris, et menacent leur intégrité génétique. Les niveaux des introgressions étaient corrélés aux activités anthropiques d’exploitation des pommiers et les hybrides n’avaient pas de réduction détectable de valeur sélective sur les caractères mesurés. Notre étude de la phylogéographie du pommier sauvage européen dans l’ensemble de son aire de distribution nous a permis de détecter des groupes génétiques différenciés résultant de l’histoire climatique passée de la planète. Ces groupes représentent autant d’unités de conservation différentes.Dans une seconde partie, j'ai étudié la coévolution entre espèces de plantes et espèces de champignons pathogènes dans deux systèmes différents. Je me suis tout d'abord intéréssée à l’histoire évolutive combinée des pommiers cultivés et sauvages d’Asie centrale et du champignon causant la tavelure, Venturia inaequalis. Dans les montagnes du Kazakhstan, le pommier cultivé a été réintroduit au cours des deux derniers siècles, créant une zone de contact secondaire, non seulement entre M. domestica et M. sieversii, mais aussi entre les populations de V. inaequalis de types agricole et sauvage. Alors que l’invasion des populations sauvages par le pommier cultivé semble encore limité géographiquement, le pathogène de type agricole est largement répandu dans les forêts et sur l’hôte sauvage. Cependant, le nombre d’hybrides détectés chez le pathogène reste limité, probablement en raison de barrières intrinsèques à la reproduction, puisque les deux types de pathogènes infectent les mêmes arbres hôtes. Dans un second temps, j’ai comparé les structures génétiques et spatiales à l’échelle européenne de la plante Silene latifolia et de son pathogène Microbotryum lychnidis-dioicae. Notre jeu de données constitué du génotype d’un pathogène et de la plante qu’il infectait nous a permis de comparer la structure à très fine échelle et celle-ci apparait remarquablement congruente. Trois groupes phylogéographiques ont été identifiés chez les deux organismes, correspondant à l’histoire de contraction-expansion des aires de distribution des espèces tempérées lors de la dernière glaciation. Une structure génétique plus fine a également été détectée chez le pathogène, suggérant la possibilité d’une histoire plus complexe. / In the first part of my thesis project, I studied the evolutive history of apple tree species in Europe, including interspecific hybridizations. Analyses of whole genome data confirmed that the progenitor species of the cultivated apple tree was M. sieversii, a Central Asia wild apple tree, but also that a high proportion of European cultivated varieties form a genetic group distinct from the wild species. These varieties show traces of introgressions from M. sylvestris and of population subdivision along an East-West axis. Microsatellite markers also showed that introgressions from the cultivated apple were also quite frequent in wild apple tree populations and thus threaten their genetic integrity. We found that introgression levels were correlated to anthropic activities of apple tree cultivation and gave rise to hybrids with no detectable reduced fitness on the traits measured. Our study of the European wild apple tree phylogeography allowed us to detect differentiated genetic groups resulting from the past climatic history of the planet and which should be considered as different evolutionary significant units in conservation.In the second part of my thesis project, I studied coevolution between plant species and their pathogenic fungi in two different systems. I first compared the evolutive history of cultivated and wild apple trees in Central Asia and that of their scab pathogen, Venturia inaequalis. In the Kazakhstan Mountains, the cultivated apple tree has been reintroduced back from Europe during the last two centuries. This created a secondary contact zone, not only between the two apple tree species, but also between the agricultural and the wild types of V. inaequalis. While the invasion of natural populations by the cultivated apple trees still seems geographically limited, the agricultural pathogen is widespread in the forests and on the wild host trees. However, the number of hybrids in the pathogen was limited, probably because of intrinsic reproductive barriers since no ecological barriers were found. I also compared spatial genetic structures at the European scale in the plant Silene latifolia and its anther-smut pathogen Microbotryum lychnidis-dioicae. Our dataset included genotypes from the pathogens and the plants on which they were collected, and the population structures appeared remarquably congruent. Three phylogenetic groups were identified in these both species, corresponding with the temperate species range contraction-expansion cycles during the past glaciations. A substructure was identified in the pathogen suggesting the possibility of a more complex history.

Génétique des populations

Malus

Flux de gènes

Co-Évolution

Hôte-Pathogène

Population genetics

Malus

Gene flow

Co-Evolution

Host-Pathogen

Caractérisation de protéines nucléaires ciblées par la bactérie pathogène Listeria monocytogenes / Characterization of nuclear proteins targeted by the pathogenic bacterium Listeria monocytogenes

Pourpre, Renaud

25 October 2019

Listeria monocytogenes est un pathogène intracellulaire facultatif responsable d’une infection sévère d’origine alimentaire, la listériose. L’étude du processus d’infection cellulaire de cette bactérie a permis d’élucider divers mécanismes impliqués dans les interactions hôte-pathogène et dans le fonctionnement de la cellule eucaryote. En particulier, L. monocytogenes a été l’un des modèles pionniers dans la découverte du ciblage de la chromatine et de régulateurs nucléaires par des microbes. L’étude d’un facteur de virulence de L. monocytogenes, LntA, a permis l’identification d’un de ces régulateurs : BAHD1. En recrutant des protéines impliquées dans la formation de l’hétérochromatine, telles HDAC1/2 et HP1, BAHD1 stimule la formation d’une chromatine compacte à effet répressif. Lors d’une infection de cellules épithéliales par L. monocytogenes, BAHD1 réprime la réponse immunitaire stimulée par les interférons, une fonction inhibée par LntA. BAHD1 demeurant peu étudiée, mon doctorat a eu pour premier objectif de poursuivre la caractérisation de ce régulateur épigénétique. Par ailleurs, des données préliminaires suggéraient qu’un facteur de virulence de Listeria récemment découvert, InlP, avait la potentialité d’être, comme LntA, une nucléomoduline. Mon deuxième objectif a été d’explorer cette hypothèse.Les résultats de mon premier axe montrent que BAHD1 interagit avec MIER1 et que cette interaction est cruciale pour l’association de BAHD1 aux HDAC1/2. Nous reportons également que BAHD1 modifie la chromatine en changement la méthylation et l’acétylation des histones, ainsi que la méthylation de l’ADN, au niveau d’un gène cible, ESR1. Ces résultats nous permettent de proposer que BAHD1 forme, avec MIER1, un échafaudage assemblant un nouveau complexe de remodelage de la chromatine associé aux HDAC1/2 : le complexe BAHD1. Nous avons ensuite étudié un rôle de BAHD1 dans un organe ciblé par la Listeria, le cerveau. Nos résultats indiquent qu’une déficience totale en BAHD1 altère le transcriptome global de cet organe chez la souris. Les gènes majoritairement surexprimés sont impliqués dans des fonctions du système nerveux, le métabolisme et des troubles neurologiques. Les gènes majoritairement sous-exprimés sont impliqués dans des voies de l’immunité innée, dont des gènes de réponses aux interférons. Par ailleurs, une haplo-déficience en Bahd1 provoque des troubles comportementaux. En comparaison des souris Bahd1+/+, les souris Bahd1+/- souffrent d’une anxiété accrue et d’altérations du réflex de sursaut acoustique. Ces résultats suggèrent qu’une dérégulation de BAHD1, par des stimuli de l’environnement ou par des stimuli infectieux, pourrait avoir des effets neuro-pathologiques.Le second axe de ma thèse concernait l’étude des interactions d’InlP avec des protéines nucléaires de l’hôte, identifiées par un crible double-hybride. Nous montrons d’abord qu’InlP est une internaline atypique, avec des répétitions riches en leucine caractérisées par un motif LPX2. Nous identifions, ensuite, deux protéines nucléaires ciblées par InlP : le facteur d’épissage et suppresseur de tumeur RBM5 et le corépresseur RERE. Quand InlP est produite de façon ectopique dans les cellules humaines, elle se localise dans le noyau, où elle altère la formation de corps nucléaires enrichis en RERE. Dans des cellules sur-exprimant RBM5, InlP inhibe l’effet pro-apoptotique de RBM5 et stimule la formation de corps nucléaires denses associés à RBM5. Ces résultats suggèrent qu’InlP est une nucléomoduline agissant sur la l’assemblage et le désassemblage de compartiments de stockage de protéines cibles impliquées dans la synthèse et l’épissage d’ARNs de l’hôte.Ce travail ouvrent des perspectives dans la compréhension des interactions hôte-pathogène et dans une meilleure connaissance des mécanismes patho-épigénétiques, ainsi qu’en biologie cellulaire, dans la compréhension de la dynamique des organites nucléaires sans membrane. / Listeria monocytogenes is an optional intracellular pathogen responsible for a severe foodborne infection called listeriosis. The study of the cellular infection process of this bacterium has shed light on various mechanisms involved in host-pathogen interactions and in the functioning of the eukaryotic cell. In particular, L. monocytogenes has emerged as one of the pioneering models in the discovery of microbial targeting of chromatin and nuclear regulators. The study of a virulence factor of L. monocytogenes, LntA, allowed the identification of one of these regulators : BAHD1. By recruiting proteins involved in the formation of heterochromatin, such as HDAC1/2 and HP1, BAHD1 stimulates the formation of a compact chromatin with a repressive effect. When epithelial cells are infected with L. monocytogenes, BAHD1 suppresses the immune response stimulated by interferons, a function inhibited by LntA. Since BAHD1 is still under-researched, the first objective for my thesis was to further characterize this epigenetic regulator. In addition, preliminary data suggested that a recently discovered virulence factor of Listeria, InlP, had the potential to be, like LntA, a nucleomodulin. My second objective was to explore this hypothesis.The results of my first axis show that BAHD1 interacts with MIER1 and that this interaction is crucial for the association of BAHD1 with HDAC1/2. We also report that BAHD1 modifies chromatin by changing histone methylation and acetylation, as well as DNA methylation, at a target gene, ESR1. These results allow us to propose that BAHD1 form, with MIER1, a scaffold assembling a new chromatin remodeling complex associated with HDAC1/2 : the BAHD1 complex. We then studied the role of BAHD1 in an organ targeted by Listeria, the brain. Our results indicate that a total deficiency in BAHD1 alters the overall transcriptome of this organ in mice. Most of the overexpressed genes are involved in nervous system functions, metabolism and neurological disorders. The predominantly downregulated genes are involved in innate immunity pathways, including interferon response genes. In addition, a haplodeficiency in Bahd1 causes behavioral problems. Compared to Bahd1+/+ mice, Bahd1+/- mice suffer from increased anxiety and changes in acoustic startle reflex. These results suggest that deregulation of BAHD1, through environmental or infectious stimuli, may have neuro-pathological effects.The second axis of my thesis focused on the study of InlP interactions with host nuclear proteins, identified by a double-hybrid screen. First, we show that InlP is an atypical internalin, with leucine-rich repeats characterized by an LPX2 motif. We then identify two nuclear proteins targeted by InlP: the splicing factor and tumor suppressor RBM5 and the corepressor RERE. When InlP is produced ectopically in human cells, it is localized in the nucleus, where it alters the formation of nuclear bodies enriched in RERE. In RBM5-overexpressing cells, InlP inhibits the pro-apoptotic effect of RBM5 and stimulates the formation of dense nuclear bodies associated with RBM5. These results suggest that InlP is a nucleomodulin acting on the assembly and disassembly of target protein storage compartments involved in the synthesis and splicing of host RNAs.This work opens perspectives in the understanding of host-pathogen interactions and in a better knowledge of patho-epigenetic mechanisms, as well as in cell biology and the understanding of membraneless nuclear organelles dynamics.

Listeria monocytogenes

BAHD1

InlP

Nucléomoduline

Interaction hôte-pathogène

Patho-épigénétique

Listeria monocytogenes

BAHD1

InlP

Nucleomodulin

Host-pathogen interaction

Patho-epigenetics

Investigation of the Pseudomonas aeruginosa biofilm exopolysaccharide Psl and its role during infection

Pestrak, Matthew James, Pestrak

January 2018

No description available.

Biomedical Research

Microbiology

Use of comparative genomics and in vitro screening approach to identify vaccine candidates for the food-borne pathogen Campylobacter jejuni

Poudel, Sabin

08 August 2023

Campylobacteriosis is a leading foodborne illness worldwide, primarily caused by Campylobacter jejuni (C. jejuni) which is associated with poultry consumption. The emergence of antibiotic resistance has emphasized the need for alternative strategies to control C. jejuni colonization in poultry. To assess the prevalence of C. jejuni in poultry, 270 cloacal swab samples were collected from broilers raised under No-Antibiotics Ever system. Among these samples, 16.3% were identified as C. jejuni positive. Notably, these isolates exhibited a diverse range of virulence factors and antimicrobial resistance genes, with 61.36% of isolates showing hyper-motile and 20.45% demonstrating multidrug resistance. Following isolation, whole genome sequencing was conducted on four selected strains using a hybrid sequencing approach. Subsequently, the complete genomes of these C. jejuni strains were analyzed to identify vaccine candidates using reverse vaccinology. Three conserved potential vaccine candidates were identified as suitable targets for vaccine development, namely phospholipase A (PldA), TonB dependent transporter (ChuA), and cytolethal distending toxin (CdtB). Furthermore, the gene expression of these candidates was examined in four C. jejuni strains during host-pathogen interactions using avian macrophage cell line HD11. Significant upregulation of all three candidate genes were observed in the four tested C. jejuni strains during interaction with host cells, indicating their crucial role in C. jejuni infection. Additionally, the expression of immune genes was evaluated in avian macrophage cells to understand the immune responses during C. jejuni infection. The infection resulted in the upregulation of toll-like receptor genes (TLR-4), pro-inflammatory genes (IL-1β, IFN-γ, IL-6, IL-8L1), anti-inflammatory gene (IL-10), and iNOS2 gene expression. The observed immune response demonstrates the potential of C. jejuni to induce host immunity for protection. In conclusion, our study identifies three conserved potential vaccine candidates and provides insights into the immune responses induced by C. jejuni infection in avian macrophage cells. These findings are crucial for the development of an effective vaccine against C. jejuni, aiming to reduce C. jejuni transmission through poultry consumption and the risk of human infection.

Campylobacter jejuni

genome sequencing

reverse vaccinology

host-pathogen interaction

NAE-raised broiler

RT-qPCR

Bacteriology

Poultry or Avian Science

Proteomics of mature extracellular Human coronavirus OC43

Joharinia, Negar

08 1900

Human coronavirus OC43 (HCoV-OC43) is a beta-coronavirus from the coronaviridae family. In contrast to SARS-CoV-2, HCoV-OC43 causes upper respiratory tract disease. However, because of their close phylogenic proximity but distinct pathologies, HCoV-OC43 is a very interesting surrogate to study and compare beta coronaviruses. As all viruses, the latter hijack cell machinery proteins to complete their life cycle. Cellular proteins, particularly those incorporated into virions are of particular interest since they often play a vital role in the virus life cycle. Our goal is to employ the proteomic pipeline we developed for HSV-1 to characterize the host proteins associated with highly purified extracellular HCoV-OC43 particles and finally expand it to SARS-CoV-2. To this end, high purity in sufficient yields is crucial as mass spectrometers pick up contaminants. The proteins present in cell culture medium serum, as well as the proteins carried by the exosomes produced by the cells or by the exosomes present in the cell culture media serum, are of particular concern. We utilized a series of methods to eliminate cell culture serum protein contaminations, enrich the viral particles, and separate exosomes from viral particles. For example, we have obtained an efficient separation of concentrated HCoV-OC43 virions from exosomes using density gradient fractionation. Mass spectrometry results on the purified fractions validated the enrichment of viral particles in the virus fraction and the lack of viral proteins in the mock samples. Most interestingly, we detected 69 host proteins unique to the virus fraction (compared to the mock), mostly regulating the RNA metabolism pathway followed by metabolite interconversion, protein modifying enzymes, and protein-binding activity modulator pathways. Since we also purified extracellular exosomes in the process, we probed whether the virus alters their protein content. Mass spectrometry revealed 51 unique proteins exclusively found in exosomes produced by HCoV-OC43 infected cells. These included translational proteins, metabolite interconversion enzymes, and scaffold proteins. Our preliminary RNA interference studies showed that knocking down 14 of these host proteins altered HCoV-OC43 titers. Studying host-virus protein interactions allows us to gain a deeper understanding of how viruses take advantage of host cells, and how we can develop novel viral therapeutics. / Le coronavirus humain OC43 (HCoV-OC43) est un bêta-coronavirus de la famille des coronaviridae. Contrairement au SRAS-CoV2, le HCoV-OC43 provoque une maladie des voies respiratoires supérieures. Cependant, en raison de leur proximité phylogénique étroite mais leur pathologie distincte, HCoV-OC43 est un substitut fort intéressant pour étudier et comparer les bêta-coronavirus. Comme tous les virus, ces derniers détournent les protéines de la machinerie cellulaire pour compléter leur cycle de vie. Les protéines cellulaires, en particulier celles incorporées dans les virions, sont particulièrement intéressantes puisqu'elles jouent souvent un rôle vital dans le cycle de vie du virus. Notre objectif est d'utiliser le pipeline protéomique que nous avons développé pour le HSV-1 afin de caractériser les protéines hôtes associées à des particules virales extracellulaires de HCoV-OC43 hautement purifiées et d'étendre cette approche au SRAS-CoV2. À cette fin, une pureté élevée avec des rendements suffisants est cruciale car les spectromètres de masse détectent les contaminants. Les protéines présentes dans le sérum du milieu de culture cellulaire, ainsi que les protéines portées par les exosomes produits par les cellules ou par les exosomes présentes dans le sérum du milieu de culture cellulaire, sont particulièrement concernées. Nous avons utilisé une série de méthodes pour éliminer les contaminations par les protéines sériques des cultures cellulaires, enrichir les particules virales et séparer les exosomes des virus. Nous avons ainsi obtenu une excellente séparation des virions HCoV-OC43 concentrés des exosomes en utilisant le fractionnement par gradient de densité. Les résultats de spectrométrie de masse sur les fractions purifiées ont validé l'enrichissement en particules virales dans la fraction virale et l'absence de protéines virales dans les échantillons contrôles. Plus intéressant encore, nous avons détecté 69 protéines hôtes uniques à la fraction virale (par rapport aux cellules non-infectées). Ces protéines sont principalement associées à la voie du métabolisme de l'ARN suivie de l'interconversion des métabolites, des enzymes modifiant les protéines et des voies modulatrices de l'activité de liaison aux protéines. Puisque nous avons séparés les exosomes des virus, nous en avons profiter pour évaluer si le virus altère leur contenu protéines. La spectrométrie de masse a de facto identifié 51 protéines uniques aux exosomes produits par les cellules infectées par HCoV-OC43. Celles-ci régulent des voies des protéines traductionnelles, des enzymes d'interconversion des métabolites et des voies des protéines d'échafaudage. Nos études préliminaires sur l’interférence ARN ont montré que l’inactivation de 14 de ces protéines hôtes modifiait le titre de HCoV-OC43. L'étude des interactions hôte-protéine virale nous permet de mieux comprendre comment les virus tirent parti des cellules hôtes et comment nous pouvons développer de nouvelles thérapies virales.

HCoV-OC43

Mass spectrometry

Host-pathogen interaction

Exosomes

Spectrométrie de masse

Interaction hôte-pathogène

Virology / Virologie (UMI : 0720)

Exposure heterogeneity, host immunity and virulence evolution in a wild bird-bacterium system

Leon, Ariel Elizabeth

25 June 2019

Immunological heterogeneity is the norm in most free-living vertebrate populations, creating a diverse and challenging landscape for pathogens to replicate and transmit. This dissertation work sought to determine sources of immunological heterogeneity, as well as the consequences of this heterogeneity on pathogen fitness and evolution. A major source of heterogeneity in free-living host populations is the degree of exposure to a pathogen, as well as a host's history of exposure to a pathogen, which can create variation in standing immunity. We sought to determine the role of exposure heterogeneity on host susceptibility and immunity to secondary infection, and the influence of this heterogeneity on pathogen fitness and virulence evolution in a wild bird-bacterium system. We first determined that exposure level has a significant effect on host susceptibility to infection, severity of disease and infection, as well as immunity produced to secondary infection. Subsequently, we tested whether exposure history, and the immunity formed from this previous exposure, altered the within-host fitness advantage to virulent pathogens. We determined that previous low-level repeat exposure, which wild hosts likely encounter while foraging, produces a within-host environment which greatly favors more virulent pathogens. While within-host processes are vital for understanding and interpreting the evolutionary pressures on a pathogen, the ultimate metric of pathogen fitness is transmission. We therefore tested whether exposure history altered the transmission potential of a host and whether prior host exposure selected for more virulent pathogens. The transmission potential of a host significantly decreased with previous exposure, and high levels of previous exposure selected for more virulent pathogens. While we anticipated selection to be strongest at low-levels of exposure based on our previous results, we found here that high doses of prior exposure resulted in the strongest transmission advantage to virulence. This study also provided insight into the nuanced nature of transmission, which our results indicate is determined both by the degree of within-host pathogen replication as well as host disease severity. Together, our findings underscore the importance of exposure level and exposure history in natural populations in determining susceptibility, immunity and pathogen virulence evolution. / Doctor of Philosophy / Infectious diseases disrupt and threaten all life on this planet. To better anticipate and understand why some diseases are more harmful than others, it is vital that we consider the natural variability that exists in animal populations. A major source of variation in populations that experience disease is exposure level to a pathogen, as well as the history of exposure to a pathogen, which can alter an individual’s protection against future exposures. We sought to determine the role of exposure level on the likelihood of an individual contracting an infection, their protection from future infections, and the influence this has on pathogen evolution in a wild bird-bacterium system. We determined that exposure level has a significant effect on the likelihood an individual has of becoming infected, how severe the infection became, as well as how protected they were from future infections. Subsequently, we tested whether exposure history, and the immunity formed from previous exposure, altered the ability of pathogen strains that cause different levels of harm to replicate. We determined that previous low-level exposure, which hosts likely encounter in the wild, creates a level of immunity that favors more harmful strains of the pathogen. While understanding what happens within a host is important, the ultimate metric for predicting whether more or less harmful types of pathogens will persist is the ability of each pathogen type to spread from one host to another. We therefore tested whether exposure history altered the spread potential of a host and whether previous exposure preferentially favored the spread of more harmful pathogens. The spread potential of a host was much lower if that host had previously been exposed to the pathogen, and high levels of previous exposure in hosts only allowed the more harmful pathogen types to spread. We also found that a host’s spread potential was the result of both how much pathogen they had in their body, as well as how inflamed their affected tissues were. Together, our results indicate that natural variation in prior exposure to pathogens, which is common in all animal populations, including humans, can favor more harmful pathogen types.

House finch

Haemorhous mexicanus

Mycoplasma gallisepticum

exposure level

immune heterogeneity

virulence evolution

transmission

host-pathogen interactions

prior exposure