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      Mutations in human genes that increase the risk for severe influenza infection Translated title: Мутации в генах человека, повышающие риск тяжелого течения гриппозной инфекции

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            ABSTRACT

            The system of genetic control of innate immune responses to influenza infection and gene function allows for the development of systemic treatment of influenza with a focus on the phenotype of mutations based on individual genetic susceptibility to severe disease and/or the development of complications.

            Translated abstract

            Система генетического контроля реакции врожденного иммунитета на гриппозную инфекцию и функции генов позволяет вести разработку системного лечения гриппа с ориентацией на фенотипические проявления мутаций с учетом наследственной предрасположенности индивида к тяжелому течению заболевания и/или развитию осложнений.

            Main article text

            INTRODUCTION

            Analysis of the morbidity and mortality patterns of influenza in worldwide practice is based on studies of the age distribution and detection of risk groups [1-6]. At the same time, morbidity and mortality significantly depend on the distinctive genetic characteristics of individual populations and ethnic groups. On the one hand, the direct connection is established between a complicated course of influenza and haplotype HLA (Human Leukocyte Antigenes). On the other hand, the analysis of a number of gene polymorphisms, which determine the level of anti-viral defense, confirms that the contribution of single mutations and single-nucleotide polymorphisms (SNP) to the morbidity and mortality from influenza is significantly higher than was previously considered [7-12]. Large scale studies on population genetics and sensitivity to influenza prove that the anti-epidemic actions in different regions of the country should be planned in accordance to the specific genetic characteristics of population.

            It is also evident that in the process of anti-influenza vaccine development it is necessary to consider the possibility of the vaccine’s “genetic” orientation toward large population groups, as well as little to no reaction in response to vaccination in individuals with certain haplotypes of HLA [11,12]. Based on the results of genetic polymorphism analysis it is possible to conclude that in influenza therapy - in the case of mass morbidity, which is distinctive to pandemics - it is necessary to consider the possibility of a complicated course of disease caused by a defect in a certain part of the immune system and/or anti-viral defense. The understanding of genetic basics of pathology of infectious diseases, including influenza, could considerably change the vaccination practice as well as the basics of therapy itself. To that end, it is necessary to systematize the available information on genomes and the corresponding markers, distinctive for the cases with inadequate or pathological reaction to influenza and other accompanying infections. The SNP of the genes, listed and characterized below, is connected with the enhancement of human sensitivity to influenza or complicated course of this disease [9,13,14].

            The role of interferon-induced transmembrane protein 3 (IFITM3) gene polymorphism in infectious pathology

            Gene (IFITM3). One of the significant discoveries made during the years, passed after the last pandemic, was the detection of polymorphism in gene IFITM3 in groups of patients who developed a severe course of disease, caused by influenza virus A(H1N1)pdm09, with fatal complications in a number of cases (Fig.1) [9, 13-21].

            Fig. 1.
            The structure of the IFITM3 gene, the main coding transcripts and the corresponding proteins. The mutation leading to the formation of the alternative splicing site in exone 1 is shown as a vertical red line (single-nucleotide polymorphism rs12252 T/C). Start-codons are marked as black triangles, protein coding exones of IFITM3 gene are shown in blue, the 1-21 fragment of protein IFITM3 [26] is shown in green.

            Gene IFITM3 belongs to the family of genes that are induced by type I interferons (IFN). The IFITM3 protein is a transmembrane protein containing two transmembrane domains. Its functional activity is connected with human resistance to the strains of A(H1N1)pdm09 virus and many other infections, including Dengue and West Nile hemorrhagic fevers [13]. The protein IFITM3 exists in different isoforms; one of the most prevalent isoforms lacks the N-terminus domain (Fig.2) [18-21]. Analysis of this phenomenon led to the identification of a splicing site mutation that determines the enhanced human sensitivity to pandemic influenza [19, 20].

            Fig. 2.
            The scheme of IFTM3 protein.

            N-end sequence 1-MNHTVQTFFSPVNSGQPPNYE-21, which is absent in the shortened mutant protein, is shown in green.

            The analysis of the protein IFITM3 mechanism of action showed that it blocks the cells infection by preventing the entry of viral particles via endocytosis. [22]. This protein was shown to suppress the infection of Ebola, HIV-1 (human immunodeficiency virus type I), hepatitis C, and Dengue viruses [13]. It was also shown that IFITM3 protein suppresses the S-protein dependent endocytosis of Middle East Respiratory Syndrome coronavirus (MERS-CoV) [23], preventing the virus genetic material from entering the cell.

            The wide spectrum of IFITM3 protein antiviral activity is caused by the protein’s profound effect on the stability of complex ATPhase of vacuoles (v-ATPhase) and endosomes. The interaction of v-ATPhase with endosomes, which leads to the relocation of Clatrin and pH reduction, plays an important role in the endocytosis of viruses [24]. This process is extremely attractive as a drug discovery target because it plays a key role in the cell infection process. It was established that classical Clatrin and v-ATPhase inhibitors are effective viral reproduction inhibitors and belong to broad-spectrum class of medicines. It turned out that Arbidol also belongs to this group of inhibitors [25]. Thus, one more mechanism of Arbidol action was revealed, which could explain its wide spectrum antiviral activity. However, the interaction of protein IFITM3 with viruses on the Clatrin pathway of virus particles internalization on the early infection phases could not be restricted to the mechanism of antiviral defense.

            Two different transcripts could be formed during the expression of the IFITM3 gene – the full transcript and the shortened transcript version, which encodes the protein sequence, lacking the N-end 21 amino acid fragment [21].

            In general, the IFITM3 protein is a restriction factor for virus reproduction, acting by the formation of the cells resistance to the different types of viruses. However, the detailed mechanisms of anti-viral defense formation in cells remain unknown in spite of the protein IFITM3 discovery. As it was shown in a number of publications [18-20], mice with silenced IFITM3 gene had a more complicated course of influenza than mice with wild IFTIM3 gene. There is a known mutation of this gene in humans: substitution of Thymidine by Cytosine in the 1st intron splicing site [18].

            The connection of this mutation to the severity of influenza A(H1N1)pdm09 was studied in a European population group [19]. In this study, the frequency of hospitalizations was the criteria of complications during the development of infection. Patients who were hospitalized with severe influenza and/or the complications caused by influenza were found to have an enhanced frequency of homozygosity for a rare C allele of gene IFITM3. The frequency of SNP rs12252-C in patients with severe influenza totals 5.3% versus 0.3% (which is common) for the European population. Interestingly, the frequency of occurrence of SNP rs12252-C in Chinese populations was significantly higher. The genotype frequency CC reached approx. 25% in the Chinese populations. Among the patients in China who had severe forms of influenza the occurrence of genotype CC reached up to 69% (Fig.3).

            Fig. 3.
            The frequency of SNP rs12252 occurrence in the alleles of IFITM3 gene in different populations living in Asia and Europe. A - the comparison of the genotypes in populations of China, Japan, Northern Europe and England;

            B - groups of patients: 1 - hospitalized patients, 2 - moderate severity influenza, 3 - severe course of influenza with complications;

            C - the frequency of alleles occurrence in patients with A(H1N1)pdm09 virus.

            The results on allelic frequencies of the IFITM3 gene described here were obtained by the authors by the statistical data processing of 1,000 genomes [19]. The IFITM3 allelic frequency varied significantly in different populations. However, among members of the Han population, originating in the Southern province and inhabiting Eastern, Southern, and central China, the frequency of CC genotype rs12252 has been found to be as high as 69%. As a result of the detailed analysis of IFITM3 allelic frequency in the population and influenza morbidity (mortality), the authors come to the conclusion that the high frequency of occurrence of CC genotype contributes to the epidemiology of influenza in China. As a matter of fact, it is precisely in China that high frequencies of massive influenza breakouts are recorded that often lead to pandemics.

            The discovery of correlation between genotype IFITM3 rs12252 and the clinical pattern of influenza infection prompted interest to study the separate components of “cytokine storm” in patients with the variant IFITM3 gene [21]. These studies were conducted with patients infected with the pathogenic strain of A(H7N9) influenza virus that is currently in circulation. The patterns of expression of the following markers of “cytokine storm” were analyzed: MPC-1 (Monocyte Chemoattractant Protein-1), IL-1β (Interleukin-1β), IL-6, IL-8, IL-10, TNF-α (Tumor Necrosis Factor), IFN-γ and C-reactive protein [27]. The authors studied the level of content of these proteins in peripheral blood. As a result of this study, it was established that the patients with genotype CC have more active synthesis and higher level of the secretion of protein MPC-1 in comparison with patients with CT or TT genotypes (Fig.3). The severity of disease also had direct correlation with these parameters – genotype CC and excessive nonspecific immune response. Furthermore, the authors have conducted the study of cytokines (MIP-1α, MIP-1β, IL-1β, IL-6 and IL-8) in the lungs of dead patients. It turned out that the level of content of some pro-inflammatory cytokines in lungs was 100–1,000 times higher than in the peripheral blood. Thus, the development of “cytokine storm” is aided by IFITM3 rs12252 gene mutation.

            To conclude the discussion of the role of gene IFITM3 polymorphism in infectious pathology it should be mentioned that the SNP rs12252 contributes to the development of Kawasaki syndrome – the early children’s vasculitis [15].This abnormality is also common for certain population groups of South-East Asia and it could lead to a severe complication, such as aortic aneurysm [28]. It should be mentioned that influenza infection provokes vasculitis, including cerebral vasculitis, which suggests that the influenza infection affects the development of the pathology of the cardiovascular system.

            Polymorphism of genes, which make an additional contribution to the severity of influenza infection

            Gene polymorphisms have been studied in order to understand the susceptibility of populations to infectious diseases and their severe progression. These studies have fundamental significance for pediatric practice and global epidemic processes [9,14, 17]. The group of genes that have an impact on the development of complications over the course of influenza, is significantly widening over the years [9,17]. Table 1 presents a list of these genes and their probable role in the disruption of certain functions contributing to the eradication of influenza and other viral infections.

            Table 1.
            Genes, whose mutations and polymorphism lead to complications during the course of influenza infection.
            GeneFunctions of the encoded proteinDefectReference
            IFITM3 Factor of antiviral defense on the endosomes levelDefect of inner cell’s antiviral defense on the initial infection step (endosomes)[18,19,21, 25]
            SP-B Surfactant protein B – lungs surfactantPneumocytes defense, stability of teeth ridge, oxygen transport and clearance of viruses and bacteria[29,30]
            FCGR2A Fc-receptor – factor of infectious virus clearanceDefect of virus clearance[31,32]
            C1QBP Factor of the complement systemDefect of the complement system and complement dependent cytolysis of infected cells[8,9,33]
            DAF/CD55 Factor of the complement decom-position acceleration, antigen of the Kromer blood group systemDefect of the natural mechanisms of the lungs’ defense from the damage caused by complement in the course of influenza infection[34]
            MBL2 Mannose-binding cell lectinNatural immunity regulation defect[35]
            SOCS4 Suppressor of the cytokine dependent signal systemsDefect of control of cytokine synthesis and activity (possible development of the “cytokine storm”)[27,36]
            SECISBP2 Complex of Se – dependent enzymesDefect of the antioxidant system[37]

            The lung surfactant proteins play an important role not only in providing the stability of oxygen transport but also in antibacterial and antiviral defense. Long-term clinical observations showed that polymorphisms in genes that encode the surfactant proteins, and in particular the protein B (SP-B), play the key role in susceptibility to infections like influenza [29]. It was also established that the polymorphism of the SP-B gene is connected with a severe course of infection caused by the respiratory syncytial virus [30].

            The role of complement system factors in bacterial and viral infections is very well known. In this respect, the role of the C1QBP gene polymorphism (Complement Component 1, Q subcomponent Binding Protein) in the complications of the course of influenza [8,33] is worth close attention. The gene C1QBP is encoding the protein C1QBP, which is a homotrimer in mature form. The structural particularity of homotrimer C1QBP lies in asymmetric charge distribution on the surface of the molecule. This protein is interacting with a wide range of molecules involved in regulation of immune system: CDK13 [38], HRK [39], VTN [40], NFYB [41], FOXC1 [42], DDX21, DDX50, NCL [43], SRSF1, SRSF9 [44], CDKN2A [45] and other proteins including CD93 [46]. The function of C1QBP consists in antibody dependent cytolysis of infected cells with the involvement of complement and activation of phagocytosis. This protein is accumulated in mitochondrions during viral infection and inhibits signal transmission, which depends on RLR (RIG-I-like receptors), by interaction with the antiviral protein MAVS (Mitochondrial Anti-Viral signaling protein). The protein C1QBP is involved in the activation of blood coagulation cascade [47]. The action of C1QDP has pleiotropic character and depends on infection stage.

            CD55 (Complement Decay-Accelerating Factor; DAF) – acceleration factor for the complement decomposition – antigen of the Kromer system of blood types. DAF/CD55 carries out anti-inflammatory functions by protecting cells from damage by a complement system as well as by the control of leucocytes migration to the inflammation center [47]. DAF/CD55 is expressed in vascular endothelium, mononuclears of peripheral blood and also in epithelial cells (including lung and endometrial epithelia) [48]. CD55 inhibits activation of C3 and C5 components of complement system [49]. Significant level of expression of CD55 in respiratory epithelium stresses the importance of lungs protection from the damage caused as a result of excessive activation of the complement system. It is notable that the expression level of CD55 is regulated by progesterone and estrogen [50].

            SNP in the gene’s CD55 (rs2564978 genotype T/T) promoter is associated with more severe course of influenza caused by A(H1N1)pdm09 virus [34]. As was established by experiments in vitro, the infection of cells by the influenza virus A(H1N1)pdm09 causes the intensification of the protein CD55 expression. Patients with T/T rs2564978 genotype contain much less of CD55 on the surface of mononuclears of peripheral blood as compared with the patients with C/C and C/T genotypes [51].

            The activation of the complement system makes a significant contribution to the lung tissue damage over the course of influenza infection. High levels of C3, C5b-9 and MLB were detected in the lungs of mice infected with influenza A(H5N1) viruses, while the administration of C3aR antagonist significantly reduced the degree of inflammation in the lung tissue [52].

            The mutation in the gene’s CD55 promoter, which apparently leads to the reduction of its expression, disrupts innate lungs defense mechanisms against the damage induced by complement during influenza infection leading to a higher chance of severe disease course and lethal outcome.

            Discussion of the correlation of human genes polymorphism with severity of influenza course brings up the problem of inadequate reaction of the innate immunity to infection. It is known that the activation of transcription of genes, encoding the proinflammatory cytokines, plays an important role in pathogenesis of severe influenza [21].

            The system of genetic control of the innate immune response towards influenza infection as well as the functions of genes that are involved in downward regulation of the expression of genes, encoding the proinflammatory cytokines is of particular interest.

            Gene SOCS4 (Suppressor of Cytokine Signaling 4) holds one of the key positions in the hierarchy of genetic control of the activation of proinflammatory cytokines synthesis [36].

            The interest in the genetic control of these processes is natural. Recently, it was established that the genes of SOCS family play an important role in restraint of nonspecific natural immune response to different pathogens. Particularly, it primarily relates to the protein SOCS4 – the suppressor of cytokine signal systems 4. As a downward regulator of cytokine synthesis control, this protein belongs to the key factors of defense from excessive proinflammatory reaction to influenza virus. The proteins of this family control the innate and adaptive immune response by inhibiting the signaling pathway JAK/STAT [36].

            SECISBP2 – gene, encoding the enzymatic complex (Sec Insertion Sequence Binding Protein 2), which in turn ensures the inclusion of selenocysteine in the protein structure [37]. Enzymes containing selenocysteine are the members of the cell’s Red-Ox defense system from oxygen radicals. Generation of oxygen radicals is the cells reaction to the majority of pathogenic microorganisms including viruses [37]. In the case of hereditary mutations in SECISBP2 gene, the acceleration of oxygen active forms synthesis leads to the systematic enhancement of cellular sensitivity to insulin. This is observed in mice with knocked out gene that encodes the antioxidant enzyme glutathione peroxidase 1, which contains selenium. The presence of gene SECISBP2 mutations in humans is clinically manifested by azoospermia, axial muscular dystrophy, disorder of T-lymphocytes proliferation and suppression of immune system in general. A high degree of lipid oxidation by peroxide and DNA oxidative damage, reduction of DNA damage reparation potential and shortening of telomeres are observed in individuals with these mutations. The pleiotropic effect of mutations in SECISBP2 gene is caused by the disruption of functions of the whole selenoproteome [37]. This hereditary defect should be especially prominent in the case of influenza infection and influenza-caused pneumonia. It is known that the influenza antioxidant therapy can provide significant clinical results in the area of intoxication syndrome relief and prevention of cardiovascular complications [52].

            CONCLUSION

            The understanding of genetic polymorphism in certain genes enables to direct the development of the systematic influenza therapy with the focus on phenotypic changes, caused by mutations, with consideration of the distribution degree of the hereditary susceptibility to severe course of influenza among groups of genetic risk and population, in general.

            In spite of the possibility of the wide distribution of mutations in the identified group of genes, related to the enhanced sensitivity to influenza, it should be recognized that the presentation level of the viral antigens within the certain population groups with the different types of HLA [10, 12] remains most important.

            Mortality from influenza is registered in the acute period of the illness and usually on the peak of the epidemic, and then, as a “postponed mortality”, in the period from 1 to 3 months after the course of the disease. Most commonly, the lethal outcome is connected with the accompanying diseases, usually with cardiovascular pathology - namely heart attack and stroke.

            Thus, these factors should be taken in account while analyzing the genetic background of the population.

            REFERENCES

            1. Karpova LS, Sominina AA, Dmitrieva MN, Popovtseva NM, Stolyarova TP, Kiselev OI, Comparison of influenza pandemic in Russia in 2009-2010 with the following epidemics involving influenza A(H1N1) pdm09 (2011-2014). Epidemiology and preventive treatment by vaccination 2014; 79, 6, pp. 8 – 9 (in Russian).

            2. Monto AS. The risk of seasonal and pandemic influenza: prospects for control. Clin Infect Dis 2009; 48, Suppl 1, S20-5.

            3. Taubenberger JK, Morens DM. 1918 Influenza: the mother of all pandemics. Emerg Infect Dis 2006; 12,15-22.

            4. Wagner AP, McKenzie E, Robertson C, McMenamin J, Reynolds A, Murdoch H. Automated mortality monitoring in Scotland from 2009. Euro Surveill 2013; 18, 20451.

            5. Dawood FS, Iuliano AD, Reed C, Meltzer MI, Shay DK, Cheng PY, Bandaranayake D, Breiman RF, Brooks WA, Buchy P, Feikin DR, Fowler KB, Gordon A, Hien NT, Horby P, Huang QS, Katz MA, Krishnan A, Lal R, Montgomery JM, Molbak K, Pebody R, Presanis AM, Razuri H, Steens A, Tinoco YO, Wallinga J, Yu H, Vong S, Bresee J, Widdowson MA. Estimated global mortality associated with the first 12 months of 2009 pandemic influenza A H1N1 virus circulation: a modelling study. Lancet Infect Dis 2012; 12, 687-95.

            6. Davila J, Chowell G, Borja-Aburto VH, Viboud C, Grajales Muniz C, Miller M. Substantial Morbidity and Mortality Associated with Pandemic A/H1N1 Influenza in Mexico, Winter 2013-2014: Gradual Age Shift and Severity. PLoS Curr 2014; 6.

            7. Arankalle VA, Lole KS, Arya RP, Tripathy AS, Ramdasi AY, Chadha MS, Sangle SA, Kadam DB. Role of host immune response and viral load in the differential outcome of pandemic H1N1 (2009) influenza virus infection in Indian patients. PLoS ONE 2010; 5.

            8. Webb SA, Pettila V, Seppelt I, Bellomo R, Bailey M, Cooper DJ, Cretikos M, Davies AR, Finfer S, Harrigan PW, Hart GK, Howe B, Iredell JR, McArthur C, Mitchell I, Morrison S, Nichol AD, Paterson DL, Peake S, Richards B, Stephens D, Turner A, Yung M. Critical care services and 2009 H1N1 influenza in Australia and New Zealand. N Engl J Med 2009; 361,1925-34.

            9. Oshansky CM, Thomas PG. The human side of influenza. J Leukoc Biol 2012; 92, 83-96.

            10. Alexander J, Bilsel P, del Guercio MF, Marinkovic-Petrovic A, Southwood S, Stewart S, Ishioka G, Kotturi MF, Botten J, Sidney J, Newman M, Sette A. Identification of broad binding class I HLA supertype epitopes to provide universal coverage of influenza A virus. Hum Immunol 2010; 71, 468-74.

            11. Hertz T, Oshansky CM, Roddam PL, DeVincenzo JP, Caniza MA, Jojic N, Mallal S, Phillips E, James I, Halloran ME, Thomas PG, Corey L. HLA targeting efficiency correlates with human T-cell response magnitude and with mortality from influenza A infection. Proc Natl Acad Sci U S A 2013; 110,13492-7.

            12. Hertz T, Nolan D, James I, John M, Gaudieri S, Phillips E, Huang JC, Riadi G, Mallal S, Jojic N. Mapping the landscape of host-pathogen coevolution: HLA class I binding and its relationship with evolutionary conservation in human and viral proteins. J Virol 2011; 85, 1310-21.

            13. Brass AL, Huang IC, Benita Y, John SP, Krishnan MN, Feeley EM, Ryan BJ, Weyer JL, van der Weyden L, Fikrig E, Adams DJ, Xavier RJ, Farzan M, Elledge SJ. The IFITM proteins mediate cellular resistance to influenza A H1N1 virus, West Nile virus, and dengue virus. Cell 2009; 139, 1243-54.

            14. Hui DS, Hayden FG. Editorial commentary: Host and viral factors in emergent influenza virus infections. Clin Infect Dis 2014; 58, 1104-6.

            15. Bowles NE, Arrington CB, Hirono K, Nakamura T, Ngo L, Wee YS, Ichida F, Weis JH. Kawasaki disease patients homozygous for the rs12252-C variant of interferon-induced transmembrane protein-3 are significantly more likely to develop coronary artery lesions. Mol Genet Genomic Med 2014; 2, 356-61.

            16. Rowley AH, Baker SC, Shulman ST, Rand KH, Tretiakova MS, Perlman EJ, Garcia FL, Tajuddin NF, Fox LM, Huang JH, Ralphe JC, Takahashi K, Flatow J, Lin S, Kalelkar MB, Soriano B, Orenstein JM. Ultrastructural, immunofluorescence, and RNA evidence support the hypothesis of a “new” virus associated with Kawasaki disease. J Infect Dis 2011; 203, 1021-30.

            17. Horby P, Nguyen NY, Dunstan SJ, Baillie JK. The role of host genetics in susceptibility to influenza: a systematic review. PLoS ONE 2012; 7, e33180.

            18. Everitt AR, Clare S, Pertel T, John SP, Wash RS, Smith SE, Chin CR, Feeley EM, Sims JS, Adams DJ, Wise HM, Kane L, Goulding D, Digard P, Anttila V, Baillie JK, Walsh TS, Hume DA, Palotie A, Xue Y, Colonna V, Tyler-Smith C, Dunning J, Gordon SB, Smyth RL, Openshaw PJ, Dougan G, Brass AL, Kellam P. IFITM3 restricts the morbidity and mortality associated with influenza. Nature 2012; 484, 519-23.

            19. Zhang YH, Zhao Y, Li N, Peng YC, Giannoulatou E, Jin RH, Yan HP, Wu H, Liu JH, Liu N, Wang DY, Shu YL, Ho LP, Kellam P, McMichael A, Dong T. Interferon-induced transmembrane protein-3 genetic variant rs12252-C is associated with severe influenza in Chinese individuals. Nat Commun 2013; 4, 1418.

            20. Everitt AR, Clare S, McDonald JU, Kane L, Harcourt K, Ahras M, Lall A, Hale C, Rodgers A, Young DB, Haque A, Billker O, Tregoning JS, Dougan G, Kellam P. Defining the range of pathogens susceptible to Ifitm3 restriction using a knockout mouse model. PLoS ONE 2013; 8, e80723.

            21. Wang Z, Zhang A, Wan Y, Liu X, Qiu C, Xi X, Ren Y, Wang J, Dong Y, Bao M, Li L, Zhou M, Yuan S, Sun J, Zhu Z, Chen L, Li Q, Zhang Z, Zhang X, Lu S, Doherty PC, Kedzierska K, Xu J. Early hypercytokinemia is associated with interferon-induced transmembrane protein-3 dysfunction and predictive of fatal H7N9 infection. Proc Natl Acad Sci U S A 2013; 111, 769-74.

            22. Feeley EM, Sims JS, John SP, Chin CR, Pertel T, Chen LM, Gaiha GD, Ryan BJ, Donis RO, Elledge SJ, Brass AL. IFITM3 inhibits influenza A virus infection by preventing cytosolic entry. PLoS Pathog 2011; 7, e1002337.

            23. Wrensch F, Winkler M, Pohlmann S. IFITM proteins inhibit entry driven by the MERS-coronavirus spike protein: evidence for cholesterol-independent mechanisms. Viruses 2014; 6, 3683-98.

            24. Wee YS, Roundy KM, Weis JJ, Weis JH. Interferon-inducible transmembrane proteins of the innate immune response act as membrane organizers by influencing clathrin and v-ATPase localization and function. Innate Immun; 18, 834-45.

            25. Blaising J, Levy PL, Polyak SJ, Stanifer M, Boulant S, Pecheur EI. Arbidol inhibits viral entry by interfering with clathrin-dependent trafficking. Antiviral Res 2013; 100, 215-9.

            26. Cunningham F, Amode MR, Barrell D, Beal K, Billis K, Brent S, Carvalho-Silva D, Clapham P, Coates G, Fitzgerald S, Gil L, Giron CG, Gordon L, Hourlier T, Hunt SE, Janacek SH, Johnson N, Juettemann T, Kahari AK, Keenan S, Martin FJ, Maurel T, McLaren W, Murphy DN, Nag R, Overduin B, Parker A, Patricio M, Perry E, Pignatelli M, Riat HS, Sheppard D, Taylor K, Thormann A, Vullo A, Wilder SP, Zadissa A, Aken BL, Birney E, Harrow J, Kinsella R, Muffato M, Ruffier M, Searle SM, Spudich G, Trevanion SJ, Yates A, Zerbino DR, Flicek P. Ensembl 2015. Nucleic Acids Res; 43, D662-9.

            27. Ramirez-Martinez G, Cruz-Lagunas A, Jimenez-Alvarez L, Espinosa E, Ortiz-Quintero B, Santos-Mendoza T, Herrera MT, Canche-Pool E, Mendoza C, Banales JL, Garcia-Moreno SA, Moran J, Cabello C, Orozco L, Aguilar-Delfin I, Hidalgo-Miranda A, Romero S, Suratt BT, Selman M, Zuniga J. Seasonal and pandemic influenza H1N1 viruses induce differential expression of SOCS-1 and RIG-I genes and cytokine/ chemokine production in macrophages. Cytokine 2013; 62, 151-9.

            28. Mizuguchi M, Yamanouchi H, Ichiyama T, Shiomi M. Acute encephalopathy associated with influenza and other viral infections. Acta Neurol Scand Suppl 2007; 186, 45-56.

            29. To KK, Zhou J, Song YQ, Hung IF, Ip WC, Cheng ZS, Chan AS, Kao RY, Wu AK, Chau S, Luk WK, Ip MS, Chan KH, Yuen KY. Surfactant protein B gene polymorphism is associated with severe influenza. Chest 2014; 145:1237-43.

            30. Puthothu B, Forster J, Heinze J, Heinzmann A, Krueger M. Surfactant protein B polymorphisms are associated with severe respiratory syncytial virus infection, but not with asthma. BMC Pulm Med 2007; 7, 6.

            31. Zarychanski R, Stuart TL, Kumar A, Doucette S, Elliott L, Kettner J, Plummer F. Correlates of severe disease in patients with 2009 pandemic influenza (H1N1) virus infection. CMAJ 2010; 182, 257-64.

            32. Worgall S, Bezdicek P, Kim MK, Park JG, Singh R, Christofidou-Solomidou M, Prince A, Kovesdi I, Schreiber AD,Crystal RG.Augmentation of pulmonary host defense against Pseudomonas by FcgammaRIIA cDNA transfer to the respiratory epithelium. J Clin Invest 1999; 104, 409-18.

            33. La Ruche G,TarantolaA,Barboza P,Vaillant L,Gueguen J, Gastellu-Etchegorry M. The 2009 pandemic H1N1 influenza and indigenous populations of the Americas and the Pacific. Euro Surveill 2009; 14.

            34. Zhou J, To KK, Dong H, Cheng ZS, Lau CC, Poon VK, Fan YH, Song YQ, Tse H, Chan KH, Zheng BJ, Zhao GP, Yuen KY. A functional variation in CD55 increases the severity of 2009 pandemic H1N1 influenza A virus infection. J Infect Dis 2012; 206, 495-503.

            35. Zuniga J, Buendia-Roldan I, Zhao Y, Jimenez L, Torres D, Romo J, Ramirez G, Cruz A, Vargas-Alarcon G, Sheu CC, Chen F, Su L, Tager AM, Pardo A, Selman M, Christiani DC. Genetic variants associated with severe pneumonia in A/H1N1 influenza infection. Eur Respir J 2011; 39, 604-10.

            36. Kedzierski L, Linossi EM, Kolesnik TB, Day EB, Bird NL, Kile BT, Belz GT, Metcalf D, Nicola NA, Kedzierska K, Nicholson SE. Suppressor of cytokine signaling 4 (SOCS4) protects against severe cytokine storm and enhances viral clearance during influenza infection. PLoS Pathog 2014; 10, e1004134.

            37. Schoenmakers E, Agostini M, Mitchell C, Schoenmakers N, Papp L, Rajanayagam O, Padidela R, Ceron-Gutierrez L, Doffinger R, Prevosto C, Luan J, Montano S, Lu J, Castanet M, Clemons N, Groeneveld M, Castets P, Karbaschi M, Aitken S, Dixon A, Williams J, Campi I, Blount M, Burton H, Muntoni F, O’Donovan D, Dean A, Warren A, Brierley C, Baguley D, Guicheney P, Fitzgerald R, Coles A, Gaston H, Todd P, Holmgren A, Khanna KK, Cooke M, Semple R, Halsall D, Wareham N, Schwabe J, Grasso L, Beck-Peccoz P, Ogunko A, Dattani M, Gurnell M, Chatterjee K. Mutations in the selenocysteine insertion sequence-binding protein 2 gene lead to a multisystem selenoprotein deficiency disorder in humans. J Clin Invest 2010; 120, 4220-35.

            38. Even Y, Durieux S, Escande ML, Lozano JC, Peaucellier G, Weil D, Geneviere AM. CDC2L5, a Cdk-like kinase with RS domain, interacts with the ASF/SF2-associated protein p32 and affects splicing in vivo. J Cell Biochem 2006; 99, 890-904.

            39. Sunayama J, Ando Y, Itoh N, Tomiyama A, Sakurada K, Sugiyama A, Kang D, Tashiro F, Gotoh Y, Kuchino Y, Kitanaka C. Physical and functional interaction between BH3-only protein Hrk and mitochondrial pore-forming protein p32. Cell Death Differ 2004; 11, 771-81.

            40. Lim BL, Reid KB, Ghebrehiwet B, Peerschke EI, Leigh LA, Preissner KT. The binding protein for globular heads of complement C1q, gC1qR. Functional expression and characterization as a novel vitronectin binding factor. J Biol Chem 1996; 271, 26739-44.

            41. Chattopadhyay C, Hawke D, Kobayashi R, Maity SN. Human p32, interacts with B subunit of the CCAAT-binding factor, CBF/NF-Y, and inhibits CBF-mediated transcription activation in vitro. Nucleic Acids Res 2004; 32, 3632-41.

            42. Huang L, Chi J, Berry FB, Footz TK, Sharp MW, Walter MA. Human p32 is a novel FOXC1-interacting protein that regulates FOXC1 transcriptional activity in ocular cells. Invest Ophthalmol Vis Sci 2008; 49, 5243-9.

            43. Yoshikawa H, Komatsu W, Hayano T, Miura Y, Homma K, Izumikawa K, Ishikawa H, Miyazawa N, Tachikawa H, Yamauchi Y, Isobe T, Takahashi N. Splicing factor 2-associated protein p32 participates in ribosome biogenesis by regulating the binding of Nop52 and fibrillarin to preribosome particles. Mol Cell Proteomics 2011; 10, M110 006148.

            44. Petersen-Mahrt SK, Estmer C, Ohrmalm C, Matthews DA, Russell WC, Akusjarvi G. The splicing factor-associated protein, p32, regulates RNA splicing by inhibiting ASF/SF2 RNA binding and phosphorylation. EMBO J 1999; 18, 1014-24.

            45. Reef S, Shifman O, Oren M, Kimchi A. The autophagic inducer smARF interacts with and is stabilized by the mitochondrial p32 protein. Oncogene 2007; 26, 6677-83.

            46. Ghebrehiwet B, Lu PD, Zhang W, Keilbaugh SA, Leigh LE, Eggleton P, Reid KB, Peerschke EI. Evidence that the two C1q binding membrane proteins, gC1q-R and cC1q-R, associate to form a complex. J Immunol 1997; 159, 1429-36.

            47. Sakuma M, Morooka T, Wang Y, Shi C, Croce K, Gao H, Strainic M, Medof ME, Simon DI. The intrinsic complement regulator decay-accelerating factor modulates the biological response to vascular injury. Arterioscler Thromb Vasc Biol 2010; 30, 1196-202.

            48. Uhlen M, Fagerberg L, Hallstrom BM, Lindskog C, Oksvold P, Mardinoglu A, Sivertsson A, Kampf C, Sjostedt E, Asplund A, Olsson I, Edlund K, Lundberg E, Navani S, Szigyarto CA, Odeberg J, Djureinovic D, Takanen JO, Hober S, Alm T, Edqvist PH, Berling H, Tegel H, Mulder J, Rockberg J, Nilsson P, Schwenk JM, Hamsten M, von Feilitzen K, Forsberg M, Persson L, Johansson F, Zwahlen M, von Heijne G, Nielsen J, Ponten F. Proteomics. Tissue-based map of the human proteome. Science 2015; 347, 1260419.

            49. Kuttner-Kondo LA, Mitchell L, Hourcade DE, Medof ME. Characterization of the active sites in decay-accelerating factor. J Immunol 2001; 167, 2164-71.

            50. Nowicki B, Nowicki S. DAF as a therapeutic target for steroid hormones: implications for host-pathogen interactions. Adv Exp Med Biol 2013; 735, 83-96.

            51. Shang Y, Chai N, Gu Y, Ding L, Yang Y, Zhou J, Ren G, Hao X, Fan D, Wu K, Nie Y. Systematic immunohistochemical analysis of the expression of CD46, CD55, and CD59 in colon cancer. Arch Pathol Lab Med 2014; 138, 910-9.

            52. Sun S, Zhao G, Liu C, Wu X, Guo Y, Yu H, Song H, Du L, Jiang S, Guo R, Tomlinson S, Zhou Y. Inhibition of complement activation alleviates acute lung injury induced by highly pathogenic avian influenza H5N1 virus infection. Am J Respir Cell Mol Biol 2013; 49, 221-30.

            Author and article information

            Journal
            mirjournal
            Microbiology Independent Research Journal (MIR Journal)
            Доктрина
            2500-2236
            2015
            10 September 2015
            : 2
            : 1
            : 10-18
            Affiliations
            [-1]Research Institute of Influenza, Saint Petersburg, Russian Federation
            [-2]Central Research Institute of Epidemiology, Moscow, Russian Federation
            Author notes
            [# ]Corresponding author: Olga Konshina, 197376, St. Petersburg, Prof. Popova str., 15/17, E-mail: olga_konshina@ 123456influenza.spb.ru
            Article
            10.18527/2500-2236-2015-2-1-10-18
            f8378588-0fea-4218-8659-3cca1ac72929
            © 2015 Konshina et al.

            This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International Public License (CC BYNC-SA), which permits unrestricted use, distribution, and reproduction in any medium, as long as the material is not used for commercial purposes, provided that the original author and source are cited.

            History
            : 14 March 2015
            : 22 July 2015
            Categories
            RESEARCH PAPER

            Immunology,Pharmaceutical chemistry,Biotechnology,Pharmacology & Pharmaceutical medicine,Infectious disease & Microbiology,Microbiology & Virology
            genetic control,influenza,gene polymorphism

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