Genetic variation in the IFITM locus and its phenotypic consequences

Diaz Soria, Carmen Lidia

January 2017

In the past few years, interferon-induced transmembrane (IFITM) proteins have been identified as important antiviral factors. The current understanding of IFITMs suggests that they localise within distinct cellular compartments from where they exert their broad antiviral role. For example, IFITM1 localises to the plasma membrane and restricts viruses that do not require endocytosis to infect host cells. In contrast, IFITM2 and IFITM3 are found in the early and late endosomes, respectively, and are potent inhibitors of viruses that depend on endosomal pathways for infection. I begin this dissertation by providing some background on the biology and function of IFITM proteins, including details of in vitro assays that have helped elucidate IFITMs role as antiviral factors. I also describe some early candidate-gene association studies that have attempted to correlate genetic variation within these genes with variation in viral restriction. I also describe how genetic association studies have been used more broadly to understand the biology underlying both infectious and non-communicable diseases. Evidence from in vitro, and in vivo work has demonstrated the IFITMs role as potent antiviral factors, however, no genome-wide association study has reported any significant associations to genetic variant in or around these genes. In Chapter 2, I explore reasons why this may be the case and calculate the coverage of IFITM genes by commercially available genotyping arrays. I show that IFITM2 and IFITM3 are amongst the 7% of all protein coding genes with less than 25% common variant (minor allele frequency > 5%) coverage across all arrays. Poor coverage of genetic variation is therefore one explanation for the lack of IFITM associations in GWAS. The lack of coverage in the genotyping arrays led me to explore other tools to capture variation in the IFITM region. I employ a targeted sequencing method using two different sequencing technologies: short-read sequencing (Illumina MiSeq) and single molecule, real-time sequencing (PacBio RS). Conventional pulldown protocols for targeted sequencing have not been designed for single molecule, real-time sequencing at the time, thus in Chapter 3, I provide some details of the optimisation work required to adapt the targeted method for PacBio sequencing. I then assess the performance of the method for both Illumina and PacBio sequencing. In Chapter 4, I apply the targeted sequencing method described in Chapter 3 to test genetic variants in and around IFITM1, IFITM2 and IFITM3 for association with rapid disease progression in HIV. I also explore the contribution of rare genetic variants (MAF < 1%) to this phenotype by testing for a differential enrichment between cases and controls across each of the three genes. Studies in vitro have also reported that IFITM proteins are potent restrictors of dengue virus infection. In Chapter 5, I use genotype data across a cohort of 2,008 Vietnamese children diagnosed with dengue haemorrhagic fever (DHF) and 2,018 cord blood controls to test if common variants are associated with the disease.

Caractérisation biochimique et structurale de la protéine IFITM3, un facteur de restriction antiviral du système immunitaire inné / Biochemical and structural characterization of the innate immune antiviral restriction factor IFITM3

Mayeux, Géraldine

27 February 2018

Les protéines IFITM (« InterFeron Inducible TransMembrane proteins »), et en particulier les membres 1, 2 et 3, sont des facteurs de restriction antiviraux dont l’expression est induite par le système immunitaire inné en réponse à une infection virale. Elles inhibent la réplication de nombreux virus pathogènes pour l’homme parmi lesquels figurent le virus de la grippe A, le VIH (Virus de l’Immunodéficience Humaine) de type 1 ou encore le virus de l’hépatite C. Ces virus entrent dans la cellule hôte, soit par fusion directe avec la membrane plasmique, soit par la voie de l’endocytose. Il est à présent communément admis que les protéines IFITM, localisées au sein des membranes plasmiques et endolysosomales, agissent en inhibant la fusion des membranes virales et cellulaires, empêchant par conséquent l’entrée du virus dans la cellule et donc sa réplication. D’autre part, dans le cas du VIH, leur incorporation dans les particules virales produites par la cellule hôte diminuerait la capacité de ces particules à infecter de nouvelles cellules cibles. Cependant, les mécanismes moléculaires par lesquels les protéines IFITM interfèrent avec le cycle viral ne sont pas encore clairement définis.Parmi les membres de la famille IFITM, IFITM3 est celui qui présente l’effet antiviral le plus systématique selon les différentes études. Il constitue donc un modèle de référence pour étudier la famille IFITM.Déterminer la structure ainsi que la topologie membranaire d’IFITM3 sous sa forme active rendrait alors possible la réalisation d’études fonctionnelles, dont les résultats contribueraient sans nul doute à élucider le(s) mécanisme(s) par le(s)quel(s) IFITM3 exerce son activité antivirale.C’est pourquoi, nous nous sommes tout d’abord attelés à reconstituer IFITM3 au sein de membranes artificielles (liposomes, nanodisques), car contrairement aux micelles de détergent, ces membranes artificielles peuvent mimer l’environnement natif des protéines membranaires et par conséquent, offrir de plus grandes chances de les y étudier sous leur forme active. Nous avons ensuite procédé à la caractérisation biochimique et biophysique d’IFITM3 et avons mis en évidence la formation de dimère de la protéine ainsi que de plus grandes espèces oligomériques. L’analyse structurale d’IFITM3 reconstituée en nanodisques par RMN nous a quant à elle permis d’identifier une courte région hélicoïdale dans la région N-terminale extramembranaire d’IFITM3 encore jamais décrite auparavant et pouvant correspondre à un motif d’internalisation. Nous avons en outre observé, par microscopie électronique à coloration négative, de potentiels effets d’IFITM3 sur la courbure de la membrane de liposomes qui pourraient être à l’origine de son action inhibitrice sur la fusion virale. Et enfin, nous avons montré au travers d’expériences TEVC que lorsqu’IFITM3 est présente dans l’environnement extracellulaire d’ovocytes de xénope, celle-ci est capable d’engendrer des fuites ioniques au travers de la membrane des ovocytes qui pourraient résulter soit, d’une déstabilisation de la membrane par IFITM3 soit, d’une formation de pores membranaires par la protéine. / The host cell first line of defence against viral infections induces the production of interferons. These interferons are then released in the surrounding medium where they bind to target cells and induce the expression of hundreds of genes so called interferon-stimulated genes (ISGs). The interferon inducible transmembrane proteins IFITM are part of the products of these ISGs. IFITM1, 2 and 3 are antiviral factors able to restrict the replication of a broad variety of enveloped viruses, such as influenza virus, HIV-1 (Human Immunodeficiency Virus) and Hepatitis C virus. These viruses enter in the host cell either by direct fusion with the cell membrane or by endocytosis. IFITM proteins contain two membrane regions for insertion or interaction with plasma and endolysosomal membranes where they block the fusion of virus particles with cellular membranes by a mechanism which is still undefined. In addition, their incorporation into new HIV virions, in virus producing cells, has been correlated with decreased infectivity.Among the IFITM protein family members, IFITM3 is the one showing the most recurrent antiviral effect in the different studies. Therefore it represents a good model to study the whole IFITM family.The determination of its structure and membrane topology is crucial to be able to clarify, through structure-based functional studies, the mechanism(s) by which IFITM3 interfere with the viral cycle.Here we characterized and we studied IFITM3 structure and membrane topology in a lipidic environment close to its native environment such as liposomes and nanodiscs. We demonstrated that IFITM3 can self-associate to form at least a dimer. Some higher order associations of IFITM3 have been observed after its reconstitution into liposomes and big size nanodiscs. We discovered by NMR in solution that the N-terminal region of IFITM3 contains a small helical region, never described until now, which could correspond to an internalization motif. We also observed by negative staining electron microscopy some liposomal membrane curvature changes that could be assigned to the presence of IFITM3 in these liposomes. And we discovered through TEVC experiments that IFITM3 addition in the extracellular environment of xenopus oocytes produces ion leaks through the oocyte membrane which could result either from membrane destabilization or from a pore formation.

Ifitm3

Facteur de restriction antiviral

Système immunitaire inné

Ifitm3

Antiviral restriction factor

Innate immune system

570

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07 December 2022

No description available.

Biomedical Research

Virology

Immunology

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Kenney, Adam D.

January 2021

No description available.

Biomedical Research

Immunology

Virology

IFITM3

influenza virus

cardiac pathology

heart

infection

innate immunity

virus

mouse model

interferon

inflammation

MG53

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Karthigeyan, Krithika Priyadarshini

January 2021

No description available.

Microbiology

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Fatty acid synthase

HIV-1

SARS-CoV-2

Influenza

N-myristoylation

fatty acylation

IFITM3

HIV-1 Gag

Fasnall

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McMichael, Temet M.

09 October 2018

No description available.

Biomedical Research

Molecular Biology

Microbiology

Immunology

Virology

Biochemistry

Biology

Cellular Biology

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Chesarino, Nicholas M.

January 2016

No description available.

Biomedical Research

Immunology

Virology

Cellular Biology