key: cord-0956702-e9jfrvkq
authors: Wellington, Dannielle; Laurenson-Schafer, Henry; Abdel-Haq, Adi; Dong, Tao
title: IFITM3: How genetics influence influenza infection demographically
date: 2019-03-20
journal: Biomed J
DOI: 10.1016/j.bj.2019.01.004
sha: 4f16c5332bacc7ebdc6286893771ce195dd270de
doc_id: 956702
cord_uid: e9jfrvkq

The role of host genetics in influenza infection is unclear despite decades of interest. Confounding factors such as age, sex, ethnicity and environmental factors have made it difficult to assess the role of genetics without influence. In recent years a single nucleotide polymorphism, interferon-induced transmembrane protein 3 (IFITM3) rs12252, has been shown to alter the severity of influenza infection in Asian populations. In this review we investigate this polymorphism as well as several others suggested to alter the host's defence against influenza infection. In addition, we highlight the open questions surrounding the viral restriction protein IFITM3 with the hope that by answering some of these questions we can elucidate the mechanism of IFITM3 viral restriction and therefore how this restriction is altered due to the rs12252 polymorphism.

Confounding factors such as age, sex, ethnicity and environmental factors have made it difficult to assess the role of genetics without influence. In recent years a single nucleotide polymorphism, interferon-induced transmembrane protein 3 (IFITM3) rs12252, has been shown to alter the severity of influenza infection in Asian populations. In this review we investigate this polymorphism as well as several others suggested to alter the host's defence against influenza infection. In addition, we highlight the open questions surrounding the viral restriction protein IFITM3 with the hope that by answering some of these questions we can elucidate the mechanism of IFITM3 viral restriction and therefore how this restriction is altered due to the rs12252 polymorphism.

On the hundredth anniversary of the worst influenza pandemic ever recorded, influenza infection remains one of the most common viral infections worldwide despite extensive research and vaccination strategies. Annually the worldwide burden of infection is predicted to be~1 billion individuals infected, with~3e5 million of these having severe disease leading to 290,000 to 650,000 deaths [1] . External factors such as age, gender and ethnicity have all been predicted to play a role in determining the severity of infection. In this review, we will focus on an example of significant genetic variation on the severity of influenza infection in an ethnicityspecific manner.

Age Age has been described as an important risk factor for influenza infection severity and morbidity [2] . People over 65 years of age are at particular risk [3, 4] , most likely due to immunosenescence and the associated poor response to vaccination [5e9] . Infants less than 5 years old are also considered to be at a high-risk of infection but the reasons behind this are still unknown [10] . However, a meta-analysis from 2013 showed that this group were actually at lower risk of death and hospitalisation, but higher risk of developing pneumonia [2] .

Interestingly, there seems to be a difference in mortality rate depending on whether the infection is an epidemic (one or more communities) or pandemic (worldwide) with a shift towards younger age groups during pandemics while the elderly are at risk during epidemics [4, 11] . In both age groups, the risk of complications or mortality associated with influenza infection are confounded by existing medical conditions in the individuals, making it more difficult to clearly ascertain the contribution of age.

Susceptibility to influenza infection generally shows no association with ethnicity, as this data is confounded by socioeconomic factors, but some research has been done to identify at risk groups [2] . In particular, indigenous ethnicity has been described as a risk factor with an elevated mortality rate or hospitalisation rate compared to European descendants in a study conducted in Canada [12e16]. Additionally, an interesting feature of the 1918 pandemic was that the mortality rate was relatively low in Chinese populations [17] . While this may be a result of poor record keeping, it is an interesting idea to bear in mind that some populations may respond better or worse to different influenza strains.

The sex of the individual has also been hypothesised to play a role in severity of influenza infection [18e20]. Higher morbidity associated with influenza infection in males compared to females has previously been demonstrated in one study [21] , but generally there is little evidence for a contribution of sex in influenza infection. However, it is likely that this is due to the data not being separated into age groups as there is some evidence in certain age categories that sex may an important determinant of disease severity [18] .

In the 2009 H1N1 pandemic, overall, more women than men were hospitalised. This may be indicative of the fact that women generally mount higher immune responses to viruses compared to men [18] . However, it is more likely a result of immunocompromise during pregnancy, as many of the hospitalised female patients were pregnant [22] .

In recent years there has been an increase in evidence of a genetic association between the host and the severity of influenza infection, with a significant heritable contribution to fatal outcome clear [23, 24] . It has been known for several decades that different mouse strains respond to the same influenza infection in varying levels of severity, supporting the idea that genetic variance can affect influenza infection [25e29].

In humans, there is evidence that homozygosity for the CCR5-D32 allele, a naturally occurring variant of the chemokine receptor CCR5, is associated with increased susceptibility to West Nile Virus and Influenza virus infection [30] . A patient with homozygous null mutations in the Interferon Regulatory Factor 7 (IRF7) gene displayed a severely impaired antiviral response with reduced expression of type I and III interferons [31] .

The anti-viral factor MXA (Mx1 in mice) also shows some natural genetic variance and investigations into the role of this variance in influenza susceptibility are on-going [32] . However, it has been shown that MXA restricts influenza A virus (IAV) infection in a strain-specific manner suggesting that this interaction may be more dependent on viral variance rather than host genetics [33e35]. Many common inbred laboratory mouse stains which are susceptible to influenza infection have an inactive Mx1 gene due to exon deletion or nonsense mutation which causes termination of translation to protein [26e28].

Single nucleotide polymorphisms (SNP) in several genes have been found to be associated with influenza infection severity including TLR2 rs5743708, TLR3 rs5743313 & rs5743315, TLR4 rs4986790 & rs4986791 and CD55 rs22564978 [36e40]. These SNPs have been demonstrated to induce weakened host responses to influenza infection and impaired signalling function.

The most prevalent genetic association with influenza infection is the association between the C variant of the SNP rs12252 within interferon-induced transmembrane protein 3 (IFITM3) and severe influenza [41, 42] , which is discussed in more detail below. Interestingly, presence of the CC genotype of both IFITM3 rs12252 and TLR3 rs5743313 cumulatively led to an increased death risk with influenza infection [43] .

The previous examples highlight how disruption of antiviral immunological responses can increase disease pathogenesis. SNPs affecting genes with direct influenza interactions have also been identified as risk variants for influenza virus infection. For example, SNPs in the antimicrobial genes Surfactant Protein A2 (SFTPA2) and Galectin-1 have been implicated as risk factors for severe influenza [44, 45] . These proteins are found in the airways, and can directly interact with influenza virus, limiting its replication. A SNP affecting the expression of Transmembrane Protease Serine 2 (TMPRSS2), a host protease involved in haemagglutinin cleavage, has also been associated with severe influenza infection [46] .

A genome wide association study (GWAS) performed on a small cohort of 156 Spanish patients stratified into mild and severely infected individuals found only one risk variant [47] . This SNP, rs28454025, is located inside an intron of the PEAK1-Related Kinase-Activating Pseudokinase 1 (PRAG1) gene. Given this gene's role in neural development, the authors concluded that this was a false positive.

For all of the SNPs previously mentioned the confounding factor seems to be ethnicity, with most SNPs showing variable distribution across ethnic groups [48] . This and the lack of clinical samples for influenza infection have made it difficult to draw any firm conclusions about the association between genetic variants and influenza infection. Additional large-b i o m e d i c a l j o u r n a l 4 2 ( 2 0 1 9 ) 1 9 e2 6 scale cohort studies will be required to investigate the role of genetics in influenza infection in the future.

As mentioned above, genetic variation within IFITM3 has been associated with influenza infection severity. The interferon (IFN) induced trans-membrane protein IFITM3 is an important anti-viral factor shown to restrict replication of around seventeen, mostly enveloped RNA viruses including influenza A virus (IAV), human immunodeficiency virus 1 (HIV-1), Ebola and Dengue virus [42,49e52] . Presence of IFITM3 impairs viral propagation, effects severity of infection and improves the cellular defence against viruses [42, 49, 52] . In addition to this role in virus restriction, IFITM3 has been shown to restrict cytomegalovirus [53] and Sendai virus [54] through restriction of cytokine production, mechanisms independent of direct viral restriction. This is interesting due to the finding that hypercytokinemia in influenza infection can lead to more rapid progression of disease in both humans [55] and mice [42] .

The minor allele (A) of the rs34481144 SNP, found within the promoter of IFITM3, has recently been found to be associated with increased severity of IAV infection [56] . This SNP was shown to associate strongly with expression levels of IFITM3 mRNA, making it an Expression Quantitative Trait Locus (eQTL).

Further work implicated the A allele of this SNP in enhanced binding of CTCF to the IFITM3 promoter, which has a repressive effect on IFITM3 expression. Finally, this study associated the A allele with enhanced methylation on the IFITM3 promoter of CD8 þ T cells in nasal washes, and general transcriptional repression of the IFITM3 genomic neighbourhood. The latter phenomenon was attributed to the fact that CTCF has been found to associate with broad changes in regional expression via alteration of chromosome topology. rs34481144 shows relatively even allele frequencies in European populations [Minor Allele Frequency (MAF) ¼ 0.462] compared to the low frequency seen in East Asian populations (MAF ¼ 0.006) [ Fig. 1 ] [57] .

The rs12252 SNP is a synonymous SNP within the first exon of IFITM3 and has been associated with increased severity in influenza infection, as well as faster progression to AIDS with HIV-1 infection [41, 42, 58] . In opposition with rs34481144, this SNP is common in Asian populations (MAF ¼ 0.528) but rare in European populations (MAF ¼ 0.041) [ Fig. 2 ] [59] . This makes combinatorial analyses between these two SNPs difficult, although it is potentially feasible in populations with intermediate allele frequencies for both alleles. Interestingly, Randolph et al reported that every instance of the CC rs12252 genotype (minor) was associated with the GG genotype (major) of rs34481144, indicating that, in European populations, the risk variants for each allele are on opposite haplotypes [60] .

There are some studies where this association between IFITM3 rs12252 and influenza severity has not been found [60e62]. However, this lack of association is likely due to the very low number of rs12252-CC patients included and the fact those most patients were from Caucasian, European populations. Especially as a recent meta-analysis confirmed the association between rs12252-CC and influenza severity [63] .

When this SNP was first reported it was suggested that the C allele might create an alternative splicing site, generating a protein with a 21 amino acid deletion at the N-terminus [42] . Model experiments using D21-IFITM3 showed that this truncated version of the protein was mostly translocated to the plasma membrane and therefore it did not restrict viral infection by influenza or HIV-1 as well as it's full length counterpart [64e67]. Recently, however, it has been shown that the C-variant of rs12252 is capable of generating fulllength IFITM3 protein, with the truncated version only present in negligible levels, if at all [60, 68] . This suggests that a truncated version of IFITM3 is unlikely to lead to the differences in viral restriction previously seen.

The mechanism behind why this SNP is so important in viral restriction is still unclear and a question that we feel will remain open until the mechanism of action of IFITM3 and indeed more information in general about this important protein is available. As such, for the remainder of this article we will focus on what is known about IFITM3 and present the remaining open questions that may be integral for determining the role of rs12252.

The mechanism of how IFITM3 restricts viruses has yet to be fully elucidated, however, it is likely that IFITM3 forms part of the membrane composition of endosomal compartments where it prevents viral entry into the cytosol [50, 64, 69] . Evidence for this comes from the fact that the early stages of influenza infection such as binding to the sialic acid receptor, endocytosis and trafficking to the late endosome are conserved in the presence of IFITM3 [50, 64, 70] . It was thought that IFITM proteins might reduce membrane fluidity through an increase of endosomal cholesterol altering the curvature of the membrane to impede hemifusion [69, 71] . However, a more recent study suggests that IFITM3 only functions to block release of viral particles post-hemifusion but prior to pore formation [72] .

While it is clear that IFITM3 restricts viral infection by preventing release of viral particles into the cytoplasm, the mechanism by which it achieves this is still unclear. SNPs within IFITM3, rs12252 and rs34481144, have been demonstrated to alter severity of influenza infection [41, 42, 56] . Elucidation of the mechanism of action of IFITM3 is of high priority in order to help establish how these SNPs contribute to variability of influenza infection.

IFITM3 structure IFITM3 is one of five IFITM genes found in humans. While IFITM5 and IFITM10 have diverse functions and structures that are beyond the scope of this review, IFITM1, IFITM2 and IFITM3 are highly homologous and share similar functions suggesting that they have diverged from a single gene. IFITM2 and IFITM3 have very high homology, only differing by 16 amino acids, presumably, creating a very similar structure for each. IFITM1 however, has a shorter N-terminus and a longer C-terminus [73, 74] .

The IFITM3 protein is only 133 amino acids in length with two transmembrane domains, meaning that the majority of the protein structure is found within the membrane [75] . Due to this highly hydrophobic nature of the protein no crystal structures are available. Instead three membrane topology models for IFITM3 have been generated based on the data available [ Fig. 3 ], suggesting that IFITM3 is either:

(i) An intramembrane helix with a C-terminal transmembrane helix [79, 80] ; (ii) An intramembrane protein with both termini cytoplasmic [64, 78] ; (iii) A dual-pass protein with the C-and N-termini on the extracellular side of the membrane [40, 76, 77] .

Recent evidence from NMR studies suggests that the most likely conformation is most similar to model (i), with the hydrophobic region of IFITM3 adopting a topology containing two short intramembrane a-helices followed by a long transmembrane a-helix [81] . These short helices are predicted to induce membrane curvature, potentially maintaining endosomal compartments and preventing viral release.

Several post-translational modifications of the IFITM3 protein have been described including S-Palmitoylation (S-PALM), phosphorylation and ubiquitination [64, 78, 82, 83] . S-PALM on membrane neighbouring cysteines was indicated to play an important role in the membrane association of IFITM3, with S-PALM-deficient mutants showing lower antiviral activity and less membrane association [78, 84] . Furthermore, S-PALM seems to be necessary for correct trafficking of the IFITM proteins, with John et al hypothesising that IFITM gets its S-PALM modification in the Golgi compartment, then traffics to the cell surface prior to endocytosis and incorporation into late endosomes and lysosomes [85] .

Poly-ubiquitination on lysine amino acids (K24, K48 and K63) led to a reduction in antiviral activity of IFITM3, most likely due to an increase in protein degradation [64, 78] . Chesarino et al proposed NEDD4 as the main ligase for IFITM3 poly-ubiquitination and therefore as a potential target for drugs aiming to increase IAV resistance [82] .

The phosphorylation of the tyrosine at position 20 of IFITM3 (Y20) was described as necessary for the colocalisation of IFITM3 with late endosomes and lysosomes and its antiviral function [64, 67, 85] . Interestingly, IFITM1, which lacks Y20, is located at the cell membrane rather than the acidic compartments [85] . Phosphorylation of Y20 decreases the ubiquitination of IFITM3 [83] . Taken together this suggests that post-translational modifications may help to control the level of IFITM3 expression within a cell as well as its locality.

It is widely agreed that IFITM3 must be located within the endosomal pathway of cells in order to restrict the range of viruses it does, however the exact compartment of this pathway or whether IFITM3 is present in all compartments is still under debate, despite several previous studies. Generally, this lack of a conclusive answer is due to a lack of suitable reagents for studying IFITM3 expression, with most commercial antibodies being cross-reactive for IFITM2. Researchers have thus used these cross-reactive antibodies, murine systems or overexpression tagged protein systems for any localisation experiments, all of which have their downfalls.

Using cross-reactive antibodies, it was shown that IFITM2/ 3 co-localised with the late endosomal marker Rab7 and the lysosomal markers LAMP1, LAMP2 and CD63 [50, 67, 85] . Mouse embryonic fibroblasts also exhibited co-localisation between IFITM3 and LAMP1 [82] . Using a haemagglutinin tag (HA) to IFITM3, Yount et al showed co-localisation with the endoplasmic reticulum (Calreticulin) and early endosomes (Rab5) [78] . Another study using FLAG-IFITM3 showed colocalisation between IFITM3 and the early endosome (EEA1) and lysosome (CD63) compartments [64] .

Although some of this data is in agreement, the breadth of IFITM3 co-localisation in the various compartments serves to highlight the limitations of these investigations. Potentially, IFITM3 is expressed in all compartments, however, it is also possible that IFITM3 is expressed in one compartment and IFITM2 another and tagged systems may alter localisation. The latter was beautifully shown by Williams et al, who showed IFITM3 to co-localise with LAMP2 in the presence of a cross-reactive antibody and in a C-myc-tagged system but not in a FLAG-tagged system [67] . Determining the localisation of IFITM3 confidently will help to establish its mechanism in viral control.

It has recently been shown that stem cells highly express certain interferon stimulated genes (ISGs), including IFITM3, as an innate anti-viral mechanism [86] . Stem cells are refractive to IFN stimulation and so these ISGs are expressed constitutively as a protection mechanism that is lost with differentiation. This suggests that in differentiated cells expression of ISGs such as IFITM3 is low or non-existent constitutively but strongly induced by IFN stimulation.

However, it seems that in the case of IFITM3 it is not as simple as this, with data from multiple sources, including our own laboratory, showing that the constitutive expression of IFITM3 can vary by cell type. In mice, constitutive expression of IFITM3 has been demonstrated in the lung upper and lower airways, visceral pleura and tissue-resident leukocytes [87] . Additionally, following IAV infection in mice, IAV-specific tissue-resident memory T cells in the lung mucosa can withstand viral infection during a second challenge by maintaining expression of IFITM3 [88] . For humans, the protein atlas database shows data suggesting that both protein and RNA levels of IFITM3 are variable across cell types [89, 90] .

Determining how the constitutive expression of IFITM3 varies on different cell types may potentially have implications for the mechanism of IFITM3 anti-viral protection with regards to viral tropism. It may be that viruses favour cells or organs with low intrinsic IFITM3 expression in order to give themselves an advantage at the early stages of infection. Fig. 3 Topology models of IFITM3. The exact topology of IFITM3 is unknown due to its highly hydrophobic nature. However, there are three models that are currently considered: (i) An intramembrane helix with a C-terminal transmembrane helix; (ii) An intramembrane protein with both termini cytoplasmic; (iii) A dual-pass protein with the C-and N-termini on the extracellular side of the membrane. Adapted from Ref. [81] .

Studies focussing on the expression pattern of IFITM3 without the confounding effect of IFITM2 expression are an important area of IFITM3 research in the future.

In humans, there are three types of IFN: Type I (IFN-a, IFN-b, IFN-ε, IFN-k and IFN-u), Type II (IFN-g) and Type III (IFN-l) [91e94] with each type signaling through a different receptor [95e99]. IFITM3 is induced by cytokines such as IL-6 [87] but predominantly by interferons through the two IFN stimulated response elements (ISRE) and one gamma-interferon activation site (GAS) directly upstream of the promoter and enhancer regions. Previously, it has been shown that Type I and II IFNs highly induce IFITM3 expression [100] . The effect of Type III IFN stimulation has not been widely studied, although one mouse study stated that type III IFN did not induce IFITM3 expression while types I and II did [87] .

The differential response of the IFITM3 gene to IFN stimulation may be a reflection of differences in IFN receptor expression on these cells. The IFNAR and IFNGR receptors are known to be ubiquitously expressed on all cell types compared to the limited expression of the type III IFN receptors.

With the apparent role of host genetics in susceptibility to influenza infection becoming clearer over recent years, the role of proteins like IFITM3 in viral restriction will become even more important. Despite knowledge of a genetic link between influenza infection severity and IFITM3 genotype, the mechanism for this link is still unknown. A better understanding of how rs12252 leads to such a differential outcome in infection is needed.

The authors of this review are funded by Medical Research Council, UK.

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The authors have no conflicts of interest to report. r e f e r e n c e s