key: cord-0991170-cf336j6k
authors: König, Renate; Stertz, Silke
title: Recent strategies and progress in identifying host factors involved in virus replication
date: 2015-08-31
journal: Current Opinion in Microbiology
DOI: 10.1016/j.mib.2015.06.001
sha: 330a49685a269070206fdd0f4bba345e96bf492f
doc_id: 991170
cord_uid: cf336j6k

Viruses are completely dependent on their host cells for the successful production of progeny viruses. At each stage of the viral life cycle an intricate interplay between virus and host takes place with the virus aiming to usurp the host cell for its purposes and the host cell trying to block the intruder from propagation. In recent years these interactions have been studied on a global level by systems biology approaches, such as RNA interference screens, transcriptomic or proteomic methodologies, and exciting new insights into the pathogen–host relationship have been revealed. In this review, we summarize the available data, give examples for important findings from such studies and point out current limitations and potential future directions.

Human viruses intrinsically depend on cellular factors to successfully infect and replicate inside their host. Viruses hijack the cellular machinery, exploit it and often reprogram it for their own needs, both to utilize it for replication and to evade antiviral innate immune defenses. Here, in this review, we summarize systematic approaches that have been developed to identify these key cellular determinants for viral infections. First of all, the knowledge of these critical host-pathogen interactions is crucial to understand the viral life cycle and moreover, will provide the basis for the development of therapeutic interventions. We will highlight novel concepts that arose from the comprehensive understanding of the host-viral circuitry.

A biological system, such as the evolutionary interplay between a virus and its host, functions through the combined regulatory mechanisms and entangled engagement of various classes of molecules and states (DNA, RNA, regulatory RNA, protein interactions, protein abundance, post-translational modifications, epigenetic modifications, metabolites, etc.) in a spatial and temporal order [1] . Systems-based 'omics' approaches such as genomics, proteomics, transcriptomics, metabolomics and other approaches are instrumental to capture pieces of this host-pathogen map in a comprehensive and unbiased survey (summarized in Table 1 ). Perturbation studies, RNA interference (RNAi) or cDNA overexpression, have facilitated the establishment of systematic cellbased loss-of-function or gain-of-function screening platforms, respectively. These functional genomics approaches are a powerful tool informing us about the immediate relevance of the identified factors for viral replication. In this review we focus on the genome-wide siRNA screening approaches deciphering the host cellular repertoire affecting HIV and influenza A virus (IAV) replication providing a global cellular map of the viralhost relationship (six global RNAi screens in human cells for IAV and five for HIV) [2,3 ,4,5,6 ,7,8 ,9-12] . Proteomics data can provide global insight into host proteins hijacked by the virus. Recent studies have comprehensively documented the protein complexes directly interacting with viral proteins encoded by the retrovirus HIV-1 and the herpesvirus KSHV by systematically affinity tagging and purifying all viral proteins followed by mass spectrometry [13 ,14] . Combining the genome-wide siRNA approaches above with this kind of proteomewide strategies would add another level of confidence in selecting the relevant host factors responsible for replication that serve as immediate interconnections of viral components with the host proteome. Studies integrating proteomics and hit validation by RNAi are a starting point in achieving this goal (exemplified by [15] [16] [17] ).

Recent approaches surveyed key molecules playing roles in common antiviral strategies (summarized in Table 1 ). For instance, Pichlmair et al. investigated the proteome of 70 viral proteins from 30 different viruses targeting virusspecific and pan-viral cellular processes as an immune escape strategy suggesting certain conserved cellular alert mechanisms [18] . Intriguingly, a pan-viral cellular immune response strategy implying an unexpected role for the DNA sensor cGAS in controlling RNA viruses was uncovered by Schoggins et al. [19] . They demonstrated a gain-of-function approach by screening a library of interferon-stimulated genes (ISGs) on antiviral activity against 14 different viruses. To complete the picture of the innate response sensing viral pathogens, several studies interrogated regulators of pathways affecting viral replication (see Table 1 ). Lee et al. integrated various complementary 'omics' approaches to identify new components of the innate response to cytosolic DNA affecting retroviral infections in mouse embryonic fibroblasts (MEFs) [20] , whereas two other studies covered the TLR interactome [21, 22] . To understand the cellular complexes formed after pathogen recognition, Li et al. systematically explored the human IFN interactome responsible for regulating cellular antiviral defense and IFN production [23] .

These recent novel systems-biology strategies have started to uncover the important framework that orchestrates the cellular defense against viral pathogens, however, important questions and answers are still outstanding. Non-structural viral proteins indeed protect viruses against unknown cellular proteins [24] , however none of the above mentioned studies systematically investigated how nonstructural proteins influence the results of genomics screens, for example, by comparing global screens that were performed with viruses mutated in one gene at a time. Viral proteins are known to influence innate factors by either directly leading them to proteasomal degradation [24] or changing the activation status of the restricting factors through post-translational modifications [25] . A future systematic survey on the alteration of the global cellular protein abundance/phospho-proteome/ubiquitinome through viral modulators would significantly add to the cooperative picture of viral replication. A first global study on cellular rewiring successfully uncovered novel cellular factors that are differentially phosphorylated upon HIV-1 infection [26 ] .

Given the gigantic wealth of information collected by various 'omics' studies, it becomes extremely important to gather the data in a user-friendly format, and provide 80 Host-microbe interactions: viruses Table 1 Screening approaches to identify novel cellular factors affecting viral replication (selected publications)

Genomics [2,3 ,4,5,6 ,7,81,82] Proteomics and genomics [15, 16] HIV Genomics [9,8 ,83,10- In vivo screening approach Genomics [75] novel analysis tools to comb the plethora of data to be able to compare them to own lab-generated datasets. Many global initiatives (as summarized in Table 2 ) have started to develop such tools and compendia. An all-encompassing tool integrating various datasets in a comprehensive and unbiased model of viral-host interaction, a so-called meta-analysis, will be a big challenge but promising direction for the future.

Many of the studies mentioned above revealed important novel insights into virus-host interactions and opened up new research avenues. In this review we can only highlight a few selected examples for which we illustrate how screening approaches have led to an advanced understanding of the complex virus-host interplay ( Figure 1 ).

In the field of IAV entry several novel host factors have been identified and characterized for their role in the early steps of virus infection as a result of RNAi screens for host factors of influenza viruses. For example, the cytoplasmic dipeptidase prolidase has been found to be involved in early endosomal trafficking of the virus [27] . Interestingly, also the tetraspanin CD81 which had previously been detected in influenza virions was revealed to be required for early events in virus infection, most likely at the level of fusion of viral and endosomal membranes [28, 29] . Exciting progress has also been made at the stage of viral uncoating: Su and colleagues performed an shRNA screen for host factors of IAV and focused on one particular hit found to be required for early steps of Identifying host factors involved in virus replication Kö nig and Stertz 81 Overview of screening approaches. Graphical representation of the most common screening approaches used to study virus interactions. *The enrichment step is only used for certain types of screens, such as phospho-proteomic analysis or screens for viral interactors. **The enrichment of specific posttranslational modifications includes phosphorylation, ubiquitination, etc. viral infection, the E3 ubiquitin ligase ITCH [6 ] . They could show that the virus gets trapped in the endosome upon knockdown of ITCH. Moreover, ITCH was found to be phosphorylated upon infection, thereby recruited to the endosome where it interacts with the viral matrix protein M1 and ubiquitinates M1. These results gave the first insight into cellular factors involved in the uncoating process of IAV and this was further elucidated by a recent study by Banerjee et al. [30 ] . On the basis of the results of an siRNA screen for IAV host factors the class I HDACs (histone deacetylases) had emerged as regulators of IAV entry and therefore the authors followed up on HDAC6 [30 ,31] . They found that the incoming virus carries unanchored ubiquitin chains that become recognized by an HDAC6-dependent pathway of the aggresome machinery. This leads to the recruitment of microtubules and associated motor proteins. Their model suggests that the motor proteins can generate physical force to disrupt the virions and thereby enable complete uncoating. Currently, it is unclear how the function of ITCH and the aggresome pathway are linked but certainly these studies have uncovered exciting new insights into the uncoating process of IAV.

Besides the progress on cellular factors with a proviral function in IAV entry the screening approaches have also advanced the area of antiviral factors: One of the genomewide RNAi screens for IAV identified the IFITM (IFNinducible transmembrane) proteins with the family members IFITM1, IFITM2, IFITM3 and IFITM5 in humans as novel antiviral restriction factors and two other screens confirmed this result [3 ,5,15] . Brass and colleagues observed that knockdown of IFITM3 led to increased viral replication, whereas overexpression of the IFITMs efficiently blocked the virus. It soon became clear that the antiviral potential of IFITM3 was not limited to influenza viruses, but also included members of flaviviruses, filoviruses, bunyaviruses, coronaviruses, reoviruses and HIV-1 [3 ,32-35] . Moreover, it was found that the IFITM proteins localize to endosomes and/or the plasma membrane and block at the stage of viral entry [32, 36] . Since then, a whole field of research on the antiviral potential, the mechanism of viral inhibition and the in vivo role of the IFITM proteins has opened up and flourished. We have learnt that besides humans, other species, including pigs, chicken and mice, encode for IFITM proteins with powerful antiviral activity [37] [38] [39] [40] . The mechanism of antiviral action is not completely understood yet but it is assumed that fusion between viral and endosomal membranes is targeted by the IFITM proteins [36, 41] . Current models suggest that the IFITMs either impact the composition or activity of components of endosomal vesicles to which they localize and thereby hinder fusion [42] . Alternatively, the IFITMs could affect the membrane properties of endosomes resulting in unfavorable conditions for fusion between cellular and viral membranes [43] . In line with both models most of the viruses that are sensitive to IFITM restriction are enveloped viruses that fuse in late endosomal compartments. However, also the non-enveloped reoviruses are blocked efficiently by IFITMs, whereas arenaviruses which fuse at membranes of acidic endosomal compartments are resistant to IFITM restriction [3 ,32,35] . This highlights that we do not yet fully understand the antiviral mechanism of IFITM proteins. Interestingly, two new studies reported the incorporation of IFITM proteins into HIV-1 virions and inhibition of viral fusion as a result of IFITM packaging [44 ,45 ] . It will be important to see if other viruses incorporate IFITMs as well and if this can explain some of the open questions on the mechanism of action.

Regarding the in vivo role of IFITMs it could be shown that ifitm3 À/À mice are more susceptible to IAV infection than wildtype mice as evidenced by increased weight loss and mortality [37] . Furthermore, recent findings in human patients highlighted the importance of IFITM3 in the host defense of humans against IAV [37] . It was observed that patients homozygous for a polymorphism in the IFITM3 gene that results in an inactive variant of IFITM3 had an approximately 20-fold higher incidence of severe influenza than those with intact IFITM3. Another study came to a similar conclusion but a third one could not confirm this result [46, 47] . Moreover, a recent study reported that the inactive version of IFITM3 described in the susceptible patients has potent antiviral activity in their experimental system [48] . In conclusion, more studies are required to resolve some of the contradictions but there is promising evidence for an important role in antiviral defense of IFITM3 in humans.

Details of the early steps of lentiviral replication including uncoating, nuclear import and integration have long been incompletely understood. Recent genome-wide RNAi studies have started to shed some light and instigated new intriguing research concepts to this enigmatic field of research. The first two genome-wide siRNA screens discovered members of the nucleo-cytoplasmic transport machinery as important host factors, such as the nuclear pore proteins Nup153 and Nup358 and Transportin-SR2/TNPO3 [8 ,9] . The latter was identified independently in a yeast-to-hybrid screen as an HIV-interacting protein [49] . The precise step at which these cellular factors act on viral replication had been a matter of discussion in the field (reviewed in [50] ). However, their involvement in nuclear import of the pre-integration complex (PIC) has been heavily supported by various reports, starting with the initial mapping to the nuclear import step [8 ] up to mapping of TNPO3 by De Iaco et al. [51] . An intriguing model of import-coupled integration had been suggested based on the observations, that (i) two more members of the nucleo-cytoplasmic transport machinery, amongst them Nup98 confirmed in two screens [8 ,12] , affected unexpectedly HIV-1 integration [8 ,52] , and that (ii) integration of HIV is dependent on the nuclear transport machinery even in cycling cells where post-nuclear envelope breakdown would otherwise make the nucleus accessible to the HIV PIC [8 ] . Follow-up studies extended the finding that correct trafficking through the pore facilitates integration steps such that preferred regions of the genome for integration are targeted [53 ,54] . Moreover, blocking the interaction between cyclophilin A, a long-known cellular factor relevant for HIV-1 infection [55] , and viral capsid relieves the dependence on TNPO3 and Nup358 and subsequently alters integration targeting [54] . Interestingly, a truncated version of the cleavage and polyadenylation specificity factor-6 (CPSF6) identified in a murine cDNA expression screen as a HIV-1 restricting gene had been shown to prevent nuclear entry [56] . On the basis of mutational studies, a model was proposed that binding of CPSF6 to the HIV-1 capsid mediates the dependence for TNPO3 and Nup358 [57] . An indirect role for TNPO3 promoting HIV-1 infection has been proposed: TNPO3, responsible for import of cargo proteins containing RS domains [58] , transports CSPF6 possessing such a domain into the nucleus [51] . In the absence of TNPO3, CPSF6 accumulates in the cytoplasm causing a delay in nuclear import of the viral DNA [51] . Recently, the study by Rasaiyaah et al. went a step ahead and described for the first time that cofactor usage is linked to evasion of innate sensors [59 ] . The suggested model posits that host factors, such as Cyclophilin A together with CPSF6 and Nup358, prevent premature uncoating and improper timing of reverse transcription, thus avoiding sensing of viral DNA by the DNA sensor cGAS [60] . Together with the engagement by other host factors, such as TNPO3 and Nup153, transport of the PICs through the nuclear pore can take place and will lead to proper integration site selection (reviewed in [61, 62] ).

Recently, an overexpression screening approach to discover restriction factors of viral replication identified Myxovirus resistance protein 2 (MxB) as an ISG inhibiting HIV-1 replication [63 ] . Subsequently, three reports described MxB as a potent inhibitor of early events in the life cycle [64] [65] [66] , though the precise step of inhibition still needs to be determined (summarized in [67] ). Intriguingly, the expression of MxB, a protein accumulating at the nuclear rim [68] , was shown to influence the integration site selection of the provirus, similar to cellular import factors such as TNPO3 or Nup358 [69 ] . These observations further point to the fact that HIV PIC nuclear import and integration may be functionally linked. Though much progress has been made by identification of the above mentioned host factors, still many questions are unanswered, such as the role of these factors and not yet identified co-factors in the timing and spatial model of the coupled processes of uncoating -nuclear import -integration.

As evidenced by the examples described above, follow-up studies from RNAi screen have led to exciting new findings and opened up new areas of research, for example, the IFITM restriction factors, or led to novel concepts, for example, the coupled processes for viral nuclear import and integration site selection. However, when looking at the numbers of host factors identified by various approaches, only very few hits have been confirmed and further characterized for their proviral or antiviral role. In order to fully exploit the potential of the screens many more follow-up studies are required.

It is often difficult to choose promising host factors from hit lists that contain several hundred factors. This has been further complicated by the observation that the overlap in hits is surprisingly small between different screens for the same virus [70] [71] [72] . This discrepancy can be partially explained by differences in experimental systems, such as virus strain, cell line or screening assay or limitations of high-throughput screenings, such as offtarget effects, false positives and false negatives [70, 73] , but a major contributing factor for variation between screens seems to be the different filtering criteria that are employed to rank the best genes [71] . The hit identification process will automatically introduce a bias into the otherwise unbiased genome-wide datasets. Despite the divergence in gene sets, a greater overlap was identified in shared overrepresented functional groups, pathways [71, 72] or shared protein complexes [71] . Thus, an analysis of multiple datasets will be more effective in identifying intriguing new candidates and pathways exploited by viruses. However, a re-analysis of the primary datasets from multiple screens would be most useful. Unfortunately, for most screens the primary data are not published and therefore not accessible for other researchers. In order to overcome this current limitation a public database for the deposit of primary screening datasets would be desirable. Such a repository could also help to make the integration of datasets from different methodological approaches, for example, proteomic, transcriptomic and RNAi data, possible. Single 'omics' datasets can only capture a part of the whole and thus, it will be necessary to look from various angles to define the parameters affecting virus replication.

An additional limitation of the currently available datasets is the need to use convenient experimental systems for high-throughput assays. First, in most screens transformed cell lines that are easy to transfect have been used and it is unclear how results from these systems can be extrapolated to primary cells. For instance, cGAMP responses differ in mouse versus human cells [74] and pattern recognition receptors and other pathway members are not expressed equally in all cells (e.g. STING and cGAS lack expression in 293Tcells [60] ), and thus primary sentinel cells of the immune system would be more appropriate to screen for antiviral effects than cell lines. Improved methods to perturb experimental systems based on primary cells or tissues are expected to be developed and solve such technical problems. Moreover, in vivo screens are already being established to address the important question which aspects of the virus-host interplay hold true in animal models [75] .

Second, current approaches to modulate gene expression by siRNA or shRNA come with off-target effects and usually do not block the expression of a gene completely. Future screening approaches using CRISPR/cas9 methodology will overcome some of the limitations [76 ,77 ,78 ] . CRISPR provides an elegant way of introducing targeted loss-of-function mutations at specific sites in the genome. The advantages include high screening sensitivity by homozygous knockouts, which is especially important when partial knockdown retains gene function. Moreover, whereas RNAi is limited to transcripts, CRISPR can target different elements across the genome, such as promoters, introns and intergenic regions. Catalytically inactive mutants of Cas9 linked to different functional domains can furthermore provide a means for genome-scale gain-of-function screening approaches using Cas9 activators, epigenetic modifiers or GFP-tagged Cas9 proteins to visualize genomic sequences [79, 80] . Specifically, the latter could provide a promising platform for imaging of viral sequences embedded within the native chromatin organization and dynamics in living human cells. Current limitations of the technology include the inability to target genes essential for cell survival, for example, main regulators of the cell cycle. Moreover, also for CRISPR/cas9 off-target effects have been described. Novel strategies to address this problem, such as the concerted action of paired nickases, are being pursued [79] . In sum, the CRISPR/ cas9 methodology will be complementary to RNAi and can broaden the repertoire of perturbation modalities.

In recent years massive efforts have been undertaken to shed light on virus-host interactions via unbiased highthroughput screening approaches. Such genomics, proteomics, transcriptomics and other methodologies have already revealed exciting new insights into the intricate interplay between viruses and their hosts but the available datasets have even more potential. Currently, the integration of different datasets is difficult and often restricted by the availability of primary data. Future efforts should focus on providing a framework for primary datasets and comparative and integrated analysis to uncover the full potential of the screens. Ultimately, such a meta-analysis will shed light on the three-dimensional map of host-pathogen interactions, and support the development of novel antivirals, adjuvants, and vaccines.

The cell in an era of systems biology

Human host factors required for influenza virus replication

The IFITM proteins mediate cellular resistance to influenza A H1N1 virus, West Nile virus, and dengue virus

Genome-wide RNAi screen identifies human host factors crucial for influenza virus replication

Host modulators of H1N1 cytopathogenicity

Pooled RNAi screen identifies ubiquitin ligase Itch as crucial for influenza A virus release from the endosome during virus entry

This is an important follow-up study from RNAi screens for IAV host factors providing mechanistic insight into IAV uncoating

Knockdown of specific host factors protects against influenza virus-induced cell death

Global analysis of host-pathogen interactions that regulate early-stage HIV-1 replication

The study proposes for the first time a molecular coupling between nuclear import of the viral PIC and viral DNA integration processes

Identification of host proteins required for HIV infection through a functional genomic screen

Genome-scale RNAi screen for host factors required for HIV replication

Automated genome-wide visual profiling of cellular proteins involved in HIV infection

This is the first global proteomics approach on viral proteins interacting with the host proteome

Global mapping of herpesvirus-host protein complexes reveals a transcription strategy for late genes

A physical and regulatory map of host-influenza interactions reveals pathways in H1N1 infection

Influenza virus-host interactome screen as a platform for antiviral drug development

A combined proteomics/genomics approach links hepatitis C virus infection with nonsense-mediated mRNA decay

Viral immune modulators perturb the human molecular network by common and unique strategies

Pan-viral specificity of IFN-induced genes reveals new roles for cGAS in innate immunity

Identification of regulators of the innate immune response to cytosolic DNA and retroviral infection by an integrative approach

Systematic discovery of TLR signaling components delineates viral-sensing circuits

Cofactors required for TLR7-and TLR9-dependent innate immune responses

Mapping a dynamic innate immunity protein interaction network regulating type I interferon production

Pick E: Cullin E3 ligases and their rewiring by viral factors

What pathogens have taught us about posttranslational modifications

Quantitative phosphoproteomics reveals extensive cellular reprogramming during HIV-1 entry

The first description of global phospho-proteomics upon entry of HIV-1 into target cells

Prolidase is required for early trafficking events during influenza A virus entry

Dual function of CD81 in influenza virus uncoating and budding

Cellular proteins in influenza virus particles

Influenza: a virus uses the aggresome processing machinery for host cell entry

This is an important follow-up study from RNAi screens for IAV host factors providing mechanistic insight into IAV uncoating

Histone deacetylase 8 is required for centrosome cohesion and influenza A virus entry

Distinct patterns of IFITM-mediated restriction of filoviruses, SARS coronavirus, and influenza A virus

IFITM-2 and IFITM-3 but not IFITM-1 restrict Rift Valley fever virus

The IFITM proteins inhibit HIV-1 infection

Interferoninducible transmembrane protein 3 (IFITM3) restricts reovirus cell entry

IFITM3 inhibits influenza A virus infection by preventing cytosolic entry

IFITM3 restricts the morbidity and mortality associated with influenza

Bat and pig interferon-induced transmembrane protein 3 restrict cell entry by influenza virus and lyssaviruses

Chicken interferon-inducible transmembrane protein 3 restricts influenza viruses and lyssaviruses in vitro

Swine interferoninducible transmembrane proteins potently inhibit influenza A virus replication

IFITM3 restricts influenza A virus entry by blocking the formation of fusion pores following virus-endosome hemifusion

IFITM-family proteins: the cell's first line of antiviral defense

The antiviral effector IFITM3 disrupts intracellular cholesterol homeostasis to block viral entry

IFITM proteins incorporated into HIV-1 virions impair viral fusion and spread

This study described for the first time that IFITM proteins get incorporated into HIV virions

IFITM proteins are incorporated onto HIV-1 virion particles and negatively imprint their infectivity

Interferon-induced transmembrane protein-3 genetic variant rs12252-C is associated with severe influenza in Chinese individuals

IFITM3 and susceptibility to respiratory viral infections in the community

IFITM3 polymorphism rs12252-C restricts influenza A viruses

Transportin-SR2 imports HIV into the nucleus

A model for cofactor use during HIV-1 reverse transcription and nuclear entry

TNPO3 protects HIV-1 replication from CPSF6-mediated capsid stabilization in the host cell cytoplasm

Nup153 and Nup98 bind the HIV-1 core and contribute to the early steps of HIV-1 replication

HIV integration targeting: a pathway involving Transportin-3 and the nuclear pore protein RanBP2

HIV-1 capsidcyclophilin interactions determine nuclear import pathway, integration targeting and replication efficiency

Human immunodeficiency virus type 1 Gag protein binds to cyclophilins A and B

Flexible use of nuclear import pathways by HIV-1

CPSF6 defines a conserved capsid interface that modulates HIV-1 replication

Transportin-SR: a nuclear import receptor for SR proteins

HIV-1 evades innate immune recognition through specific cofactor recruitment

This study describes for the first time a link between cofactor usage and evasion of innate sensors

Cyclic GMP-AMP synthase is a cytosolic DNA sensor that activates the type I interferon pathway

HIV: slipping under the radar

HIV-1 uncoating: connection to nuclear entry and regulation by host proteins

A diverse range of gene products are effectors of the type I interferon antiviral response

This is the first study using an over-expression screening approach testing more than 300 ISGs on the inhibition of replication of a variety of viruses

Human MX2 is an interferon-induced post-entry inhibitor of HIV-1 infection

The interferon-inducible MxB protein inhibits HIV-1 infection

MX2 is an interferon-induced inhibitor of HIV-1 infection

MxB/Mx2: the latest piece in HIV's interferon puzzle

Human MxB protein, an interferon-a-inducible GTPase, contains a nuclear targeting signal and is localized in the heterochromatin region beneath the nuclear envelope

Host and viral determinants for MxB restriction of HIV-1 infection

Uncovering the global host cell requirements for influenza virus replication via RNAi screening

Host cell factors in HIV replication: meta-analysis of genomewide studies

Cellular networks involved in the influenza virus life cycle

Identifying HIV-1 host cell factors by genome-scale RNAi screening

Mouse, but not human STING, binds and signals in response to the vascular disrupting agent 5,6-dimethylxanthenone-4-acetic acid

An in vivo RNAi screening approach to identify host determinants of virus replication

Genetic screens in human cells using the CRISPR-Cas9 system

The first descriptions of genome-wide screening using CRISPR/cas9

Genome-scale CRISPR-Cas9 knockout screening in human cells

See annotation to Ref

Highthroughput screening of a CRISPR/Cas9 library for functional genomics in human cells

CRISPR-Cas systems for editing, regulating and targeting genomes

Dynamic imaging of genomic loci in living human cells by an optimized CRISPR/Cas system

Drosophila RNAi screen identifies host genes important for influenza virus replication

The use of random Identifying host factors involved in virus replication Kö nig and Stertz 87 www.sciencedirect.com Current Opinion in Microbiology

homozygous gene perturbation to identify novel host-oriented targets for influenza

UnPAKing'' human immunodeficiency virus (HIV) replication: using small interfering RNA screening to identify novel cofactors and elucidate the role of group I PAKs in HIV infection

A whole genome screen for HIV restriction factors

Identification of novel therapeutic targets for HIV infection through functional genomic cDNA screening

A functional genomic screen identifies cellular cofactors of hepatitis C virus replication

A genome-wide genetic screen for host factors required for hepatitis C virus propagation

Discovery of insect and human dengue virus host factors

RNA interference screen for human genes associated with West Nile virus infection

Herpesviral protein networks and their interaction with the human proteome

Systematic identification of type I and type II interferon-induced antiviral factors

A genetic screen identifies interferon-alpha effector genes required to suppress hepatitis C virus replication

A functional genomic screen reveals novel host genes that mediate interferon-alpha's effects against hepatitis C virus

Interpreting cancer genomes using systematic host network perturbations by tumour virus proteins

ViPR: an open bioinformatics database and analysis resource for virology research

VirusMINT: a viral protein interaction database

Bringing it all together: big data and HIV research

GPS-Prot: a webbased visualization platform for integrating host-pathogen interaction data

Human immunodeficiency virus type 1, human protein interaction database at NCBI

Cataloguing the HIV type 1 human protein interaction network

HIV-host interactions: a map of viral perturbation of the host system

A systems biology approach to infectious disease research: innovating the pathogen-host research paradigm

Influenza research database: an integrated bioinformatics resource for influenza research and surveillance. Influenza Other Respir Viruses

A comprehensive map of the influenza A virus replication cycle

SSt is supported by grants from the Swiss National Science Foundation (31003A_156805) and the Novartis Research Foundation. RK is supported by grants from the German Center for Infection Research (DZIF). We thank Nina Hein-Fuchs for assisting in designing the tables and together with Carsten Mü nk for critical reading of the manuscript.