Phosphatidylinositol‐4 kinase III beta and oxysterol‐binding protein accumulate unesterified cholesterol on poliovirus‐induced membrane structure

Studies on anti‐picornavirus compounds have revealed an essential role of a novel cellular pathway via host phosphatidylinositol‐4 kinase III beta (PI4KB) and oxysterol‐binding protein (OSBP) family I in poliovirus (PV) replication. However, the molecular role for this pathway in PV replication has yet to be determined. Here, viral and host proteins modulating production of phosphatidylinositol 4‐phosphate (PI4P) and accumulation of unesterified cholesterol (UC) in cells were analyzed and the role of the PI4KB/OSBP pathway in PV replication characterized. Virus protein 2BC was identified as a novel interactant of PI4KB. PI4KB and VCP/p97 bind to a partially overlapped region of 2BC with different sensitivity to a 2C inhibitor. Production of PI4P and accumulation of UC were enhanced by virus protein 2BC, but suppressed by virus proteins 3A and 3AB. In PV‐infected cells, a PI4KB inhibitor suppressed production of PI4P, and both a PI4KB inhibitor and an OSBP ligand suppressed accumulation of UC on virus‐induced membrane structure. Inhibition of PI4KB activity caused dissociation of OSBP from virus‐induced membrane structure in PV‐infected cells. Synthesis of viral nascent RNA in PV‐infected cells was not affected in the presence of PI4KB inhibitor and OSBP ligand; however, transient pre‐treatment of PV‐infected cells with these inhibitors suppressed viral RNA synthesis. These results suggest that virus proteins modulate PI4KB activity and provide PI4P for recruitment of OSBP to accumulate UC on virus‐induced membrane structure for formation of a virus replication complex.     

ACBD3-mediated recruitment of PI4KB to picornavirus RNA replication sites

Phosphatidylinositol 4-kinase IIIβ (PI4KB) is a host factor required for genome RNA replication of enteroviruses, small non-enveloped viruses belonging to the family Picornaviridae. Here, we demonstrated that PI4KB is also essential for genome replication of another picornavirus, Aichi virus (AiV), but is recruited to the genome replication sites by a different strategy from that utilized by enteroviruses. AiV non-structural proteins, 2B, 2BC, 2C, 3A, and 3AB, interacted with a Golgi protein, acyl-coenzyme A binding domain containing 3 (ACBD3). Furthermore, we identified previously unknown interaction between ACBD3 and PI4KB, which provides a novel manner of Golgi recruitment of PI4KB. Knockdown of ACBD3 or PI4KB suppressed AiV RNA replication. The viral proteins, ACBD3, PI4KB, and phophatidylinositol-4-phosphate (PI4P) localized to the viral RNA replication sites. AiV replication and recruitment of PI4KB to the RNA replication sites were not affected by brefeldin A, in contrast to those in enterovirus infection. These results indicate that a viral protein/ACBD3/PI4KB complex is formed to synthesize PI4P at the AiV RNA replication sites and plays an essential role in viral RNA replication.     

Phosphatidylinositol 4‐kinase III beta is the target of oxoglaucine and pachypodol (Ro 09‐0179) for their anti‐poliovirus activities,and is located at upstream of the target step of brefeldin A

In recent years, phosphatidylinositol 4‐kinase III beta (PI4KB) has emerged as a conserved target of anti‐picornavirus compounds. In the present study, PI4KB was identified as the direct target of the plant‐derived anti‐picornavirus compounds, oxoglaucine and pachypodol (also known as Ro 09‐0179). PI4KB was also identified as the target via which pachypodol interferes with brefeldin A (BFA)‐induced Golgi disassembly in non‐infected cells. Oxysterol‐binding protein (OSBP) inhibitor also has interfering activity against BFA. It seems that this interference is not essential for the anti‐poliovirus (PV) activities of BFA and PI4KB/OSBP inhibitors. BFA inhibited early to late phase PV replication (0 to 6 hr postinfection) as well as PI4KB inhibitor, but with some delay compared to guanidine hydrochloride treatment. In contrast with PI4KB/OSBP inhibitors, BFA inhibited viral nascent RNA synthesis, suggesting that BFA targets some step of viral RNA synthesis located downstream of the PI4KB/OSBP pathway in PV replication. Our results suggest that PI4KB is a major target of anti‐picornavirus compounds identified in vitro for their anti‐picornavirus activities and for some uncharacterized biological phenomena caused by these compounds, and that BFA and PI4KB/OSBP inhibitors synergistically repress PV replication by targeting distinct steps in viral RNA replication.     

The Salmonella effector SteA binds phosphatidylinositol 4‐phosphate for subcellular targeting within host cells

Many bacterial pathogens use specialized secretion systems to deliver virulence effector proteins into eukaryotic host cells. The function of these effectors depends on their localization within infected cells, but the mechanisms determining subcellular targeting of each effector are mostly elusive. Here, we show that the Salmonella type III secretion effector SteA binds specifically to phosphatidylinositol 4‐phosphate [PI(4)P]. Ectopically expressed SteA localized at the plasma membrane (PM) of eukaryotic cells. However, SteA was displaced from the PM of Saccharomyces cerevisiae in mutants unable to synthesize the local pool of PI(4)P and from the PM of HeLa cells after localized depletion of PI(4)P. Moreover, in infected cells, bacterially translocated or ectopically expressed SteA localized at the membrane of the Salmonella‐containing vacuole (SCV) and to Salmonella‐induced tubules; using the PI(4)P‐binding domain of the Legionella type IV secretion effector SidC as probe, we found PI(4)P at the SCV membrane and associated tubules throughout Salmonella infection of HeLa cells. Both binding of SteA to PI(4)P and the subcellular localization of ectopically expressed or bacterially translocated SteA were dependent on a lysine residue near the N‐terminus of the protein. Overall, this indicates that binding of SteA to PI(4)P is necessary for its localization within host cells.     

Valosin-containing protein (VCP/p97) is required for poliovirus replication and is involved in cellular protein secretion pathway in poliovirus infection

Poliovirus (PV) modifies membrane-trafficking machinery in host cells for its viral RNA replication. To date, ARF1, ACBD3, BIG1/BIG2, GBF1, RTN3, and PI4KB have been identified as host factors of enterovirus (EV), including PV, involved in membrane traffic. In this study, we performed small interfering RNA (siRNA) screening targeting membrane-trafficking genes for host factors required for PV replication. We identified valosin-containing protein (VCP/p97) as a host factor of PV replication required after viral protein synthesis, and its ATPase activity was essential for PV replication. VCP colocalized with viral proteins 2BC/2C and 3AB/3B in PV-infected cells and showed an interaction with 2BC and 3AB but not with 2C and 3A. Knockdown of VCP did not suppress the replication of coxsackievirus B3 or Aichi virus. A VCP-knockdown-resistant PV mutant had an A4881G (a mutation of E253G in 2C) mutation, which is known as a determinant of a secretion inhibition-negative phenotype. However, knockdown of VCP did not affect the inhibition of cellular protein secretion caused by overexpression of each individual viral protein. These results suggested that VCP is a host factor required for viral RNA replication of PV among membrane-trafficking proteins and provides a novel link between cellular protein secretion and viral RNA replication.     

Formation of enterovirus-like particle aggregates by recombinant baculoviruses co-expressing P1 and 3CD in insect cells

The assembly of enterovirus requires the cleavage of P1 polyprotein by protease 3CD into individual structural proteins. Two recombinant baculoviruses were constructed to encode P1 and 3CD of enterovirus 71 (EV71), respectively. The expressed 3CD successfully cleaved P1 in vitro and in vivo. Also, the co-infection in insect cells resulted in crystalline virus-like particle structures morphologically resembling the authentic EV71 aggregates, which are reported for the first time.     

Enhanced resistance in Theobroma cacao against oomycete and fungal pathogens by secretion of phosphatidylinositol‐3‐phosphate‐binding proteins

The internalization of some oomycete and fungal pathogen effectors into host plant cells has been reported to be blocked by proteins that bind to the effectors' cell entry receptor, phosphatidylinositol‐3‐phosphate (PI3P). This finding suggested a novel strategy for disease control by engineering plants to secrete PI3P‐binding proteins. In this study, we tested this strategy using the chocolate tree Theobroma cacao. Transient expression and secretion of four different PI3P‐binding proteins in detached leaves of T. cacao greatly reduced infection by two oomycete pathogens, Phytophthora tropicalis and Phytophthora palmivora, which cause black pod disease. Lesion size and pathogen growth were reduced by up to 85%. Resistance was not conferred by proteins lacking a secretory leader, by proteins with mutations in their PI3P‐binding site, or by a secreted PI4P‐binding protein. Stably transformed, transgenic T. cacao plants expressing two different PI3P‐binding proteins showed substantially enhanced resistance to both P. tropicalis and P. palmivora, as well as to the fungal pathogen Colletotrichum theobromicola. These results demonstrate that secretion of PI3P‐binding proteins is an effective way to increase disease resistance in T. cacao, and potentially in other plants, against a broad spectrum of pathogens.     

Phosphatidylinositol 4-kinase III beta is a target of enviroxime-like compounds for antipoliovirus activity

Enviroxime is an antienterovirus compound that targets viral protein 3A and/or 3AB and suppresses a step in enterovirus replication by unknown mechanism. To date, four antienterovirus compounds, i.e., GW5074, Flt3 inhibitor II, TTP-8307, and AN-12-H5, are known to have similar mutations in the 3A protein-encoding region causing resistance to enviroxime (a G5318A [3A-Ala70Thr] mutation in poliovirus [PV]) and are considered enviroxime-like compounds. Recently, antienterovirus activity of a phosphatidylinositol 4-kinase III beta (PI4KB) inhibitor, PIK93, was reported, suggesting that PI4KB is an important host factor targetable by antienterovirus compounds (N. Y. Hsu et al., Cell 141:799-811, 2010). In this study, we analyzed the inhibitory effects of previously identified enviroxime-like compounds (GW5074 and AN-12-H5) and a newly identified antienterovirus compound, T-00127-HEV1, on phosphoinositide (PI) kinases. We found that T-00127-HEV1 inhibited PI4KB activity with a higher specificity for than other PI kinases, in contrast to GW5074, which had a broad specificity for PI kinases. In contrast, AN-12-H5 showed no inhibitory effect on PI4KB activity and only moderate inhibitory effects on PI 3-kinase activity. Small interfering RNA (siRNA) screening targeting PI kinases identified PI4KB is a target of GW5074 and T-00127-HEV1, but not of AN-12-H5, for anti-PV activity. Interestingly, T-00127-HEV1 and GW5074 did not inhibit hepatitis C virus (HCV) replication, in contrast to a strong inhibitory effect of AN-12-H5. These results suggested that PI4KB is an enterovirus-specific host factor required for the replication process and targeted by some enviroxime-like compounds (T-00127-HEV1 and GW5074) and that enviroxime-like compounds may have targets other than PI kinases for their antiviral effect.     

Coxsackievirus mutants that can bypass host factor PI4KIIIβ and the need for high levels of PI4P lipids for replication

RNA viruses can rapidly mutate and acquire resistance to drugs that directly target viral enzymes, which poses serious problems in a clinical context. Therefore, there is a growing interest in the development of antiviral drugs that target host factors critical for viral replication, since they are unlikely to mutate in response to therapy. We recently demonstrated that phosphatidylinositol-4-kinase IIIβ (PI4KIIIβ) and its product phosphatidylinositol-4-phosphate (PI4P) are essential for replication of enteroviruses, a group of medically important RNA viruses including poliovirus (PV), coxsackievirus, rhinovirus, and enterovirus 71. Here, we show that enviroxime and GW5074 decreased PI4P levels at the Golgi complex by directly inhibiting PI4KIIIβ. Coxsackievirus mutants resistant to these inhibitors harbor single point mutations in the non-structural protein 3A. These 3A mutations did not confer compound-resistance by restoring the activity of PI4KIIIβ in the presence of the compounds. Instead, replication of the mutant viruses no longer depended on PI4KIIIβ, since their replication was insensitive to siRNA-mediated depletion of PI4KIIIβ. The mutant viruses also did not rely on other isoforms of PI4K. Consistently, no high level of PI4P could be detected at the replication sites induced by the mutant viruses in the presence of the compounds. Collectively, these findings indicate that through specific single point mutations in 3A, CVB3 can bypass an essential host factor and lipid for its propagation, which is a new example of RNA viruses acquiring resistance against antiviral compounds, even when they directly target host factors.     

Interactome analysis of the EV71 5′ untranslated region in differentiated neuronal cells SH‐SY5Y and regulatory role of FBP3 in viral replication

Enterovirus 71 (EV71), a single‐stranded RNA virus, is one of the most serious neurotropic pathogens in the Asia‐Pacific region. Through interactions with host proteins, the 5′ untranslated region (5′UTR) of EV71 is important for viral replication. To gain a protein profile that interact with the EV71 5′UTR in neuronal cells, we performed a biotinylated RNA‐protein pull‐down assay in conjunction with LC–MS/MS analysis. A total of 109 proteins were detected and subjected to Database for Annotation, Visualization and Integrated Discovery (DAVID) analyses. These proteins were found to be highly correlated with biological processes including RNA processing/splicing, epidermal cell differentiation, and protein folding. A protein–protein interaction network was constructed using the STRING online database to illustrate the interactions of those proteins that are mainly involved in RNA processing/splicing or protein folding. Moreover, we confirmed that the far‐upstream element binding protein 3 (FBP3) was able to bind to the EV71 5′UTR. The redistribution of FBP3 in subcellular compartments was observed after EV71 infection, and the decreased expression of FBP3 in host neuronal cells markedly inhibited viral replication. Our results reveal various host proteins that potentially interact with the EV71 5′UTR in neuronal cells, and we found that FBP3 could serve as a positive regulator in host cells.     

The role of the phosphatidylinositol 4-kinase PI4KA in hepatitis C virus-induced host membrane rearrangement

Background

Hepatitis C virus (HCV), like other positive-sense RNA viruses, replicates on an altered host membrane compartment that has been called the “membranous web.” The mechanisms by which the membranous web are formed from cellular membranes are poorly understood. Several recent RNA interference screens have demonstrated a critical role for the host phosphatidylinositol 4-kinase PI4KA in HCV replication. We have sought to define the function of PI4KA in viral replication.

Methodology/Principal Findings

Using a nonreplicative model of membranous web formation, we show that PI4KA silencing leads to aberrant web morphology. Furthermore, we find that PI4KA and its product, phosphatidylinositol 4-phosphate, are enriched on membranous webs and that PI4KA is found in association with NS5A in HCV-infected cells. While the related lipid kinase PI4KB also appears to support HCV replication, it does not interact with NS5A. Silencing of PI4KB does not overtly impair membranous web morphology or phosphatidylinositol 4-phosphate enrichment at webs, suggesting that it acts at a different point in viral replication. Finally, we demonstrate that the aberrant webs induced by PI4KA silencing require the activity of the viral NS3-4A serine protease but not integrity of the host secretory pathway.

Conclusions/Significance

PI4KA is necessary for the local enrichment of PI 4-phosphate at the HCV membranous web and for the generation of morphologically normal webs. We also show that nonreplicative systems of web formation can be used to order molecular events that drive web assembly.     

Functional characterization of the mutations in Pepper mild mottle virus overcoming tomato tm‐1‐mediated resistance

In tomato plants, Pepper mild mottle virus (PMMoV) cannot replicate because the tm‐1 protein inhibits RNA replication. The resistance of tomato plants to PMMoV remains durable both in the field and under laboratory conditions. In this study, we constructed several mutant PMMoVs and analysed their abilities to replicate in tomato protoplasts and plants. We found that two mutants, PMMoV‐899R,F976Y and PMMoV‐899R,F976Y,D1098N, were able to replicate in tomato protoplasts, but only PMMoV‐899R,F976Y,D1098N was able to multiply in tomato plants. Further analysis showed that the D1098N mutation of the replication proteins weakened the inhibitory effect of the tm‐1 protein and enhanced the replication efficiency of PMMoV‐899R,F976Y,D1098N. We also observed that the infectivity of the viruses decreased in the order wild‐type PMMoV > PMMoV‐899R,F976Y > PMMoV‐899R,F976Y,D1098N in original host plants, pepper and tobacco plants. On the contrary, the single mutation D1098N abolished PMMoV replication in tobacco protoplasts. On the basis of these observations, it is likely that the deleterious side‐effects of mutations in replication proteins prevent the emergence of PMMoV mutants that can overcome tm‐1‐mediated resistance.     

Structural insights into Acyl‐coenzyme A binding domain containing 3 (ACBD3) protein hijacking by picornaviruses

Many picornaviruses hijack the Golgi resident Acyl‐coenzyme A binding domain containing 3 (ACBD3) protein in order to recruit the phosphatidylinositol 4‐kinase B (PI4KB) to viral replication organelles (ROs). PI4KB, once recruited and activated by ACBD3 protein, produces the lipid phosphatidylinositol 4‐phosphate (PI4P), which is a key step in the biogenesis of viral ROs. To do so, picornaviruses use their small nonstructural protein 3A that binds the Golgi dynamics domain of the ACBD3 protein. Here, we present the analysis of the highly flexible ACBD3 proteins and the viral 3A protein in solution using small‐angle X‐ray scattering and computer simulations. Our analysis revealed that both the ACBD3 protein and the 3A:ACBD3 protein complex have an extended and flexible conformation in solution.     

Distinct Mycobacterium marinum phosphatases determine pathogen vacuole phosphoinositide pattern,phagosome maturation,and escape to the cytosol

The causative agent of tuberculosis, Mycobacterium tuberculosis, and its close relative Mycobacterium marinum manipulate phagocytic host cells, thereby creating a replication‐permissive compartment termed the Mycobacterium‐containing vacuole (MCV). The phosphoinositide (PI) lipid pattern is a crucial determinant of MCV formation and is targeted by mycobacterial PI phosphatases. In this study, we establish an efficient phage transduction protocol to construct defined M. marinum deletion mutants lacking one or three phosphatases, PtpA, PtpB, and/or SapM. These strains were defective for intracellular replication in macrophages and amoebae, and the growth defect was complemented by the corresponding plasmid‐borne genes. Fluorescence microscopy of M. marinum‐infected Dictyostelium discoideum revealed that MCVs harbouring mycobacteria lacking PtpA, SapM, or all three phosphatases accumulate significantly more phosphatidylinositol‐3‐phosphate (PtdIns3P) compared with MCVs containing the parental strain. Moreover, PtpA reduced MCV acidification by blocking the recruitment of the V‐ATPase, and all three phosphatases promoted bacterial escape from the pathogen vacuole to the cytoplasm. In summary, the secreted M. marinum phosphatases PtpA, PtpB, and SapM determine the MCV PI pattern, compartment acidification, and phagosomal escape.     

Plasmodium berghei sporozoites in nonreplicative vacuole are eliminated by a PI3P‐mediated autophagy‐independent pathway

The protozoan parasite Plasmodium, causative agent of malaria, invades hepatocytes by invaginating the host cell plasma membrane and forming a parasitophorous vacuole membrane (PVM). Surrounded by this PVM, the parasite undergoes extensive replication. Parasites inside a PVM provoke the Plasmodium‐associated autophagy‐related (PAAR) response. This is characterised by a long‐lasting association of the autophagy marker protein LC3 with the PVM, which is not preceded by phosphatidylinositol 3‐phosphate (PI3P)‐labelling. Prior to productive invasion, sporozoites transmigrate several cells and here we describe that a proportion of traversing sporozoites become trapped in a transient traversal vacuole, provoking a host cell response that clearly differs from the PAAR response. These trapped sporozoites provoke PI3P‐labelling of the surrounding vacuolar membrane immediately after cell entry, followed by transient LC3‐labelling and elimination of the parasite by lysosomal acidification. Our data suggest that this PI3P response is not only restricted to sporozoites trapped during transmigration but also affects invaded parasites residing in a compromised vacuole. Thus, host cells can employ a pathway distinct from the previously described PAAR response to efficiently recognise and eliminate Plasmodium parasites.     

Long‐term live‐cell imaging reveals new roles for Salmonella effector proteins SseG and SteA

Salmonella Typhimurium is an intracellular bacterial pathogen that infects both epithelial cells and macrophages. Salmonella effector proteins, which are translocated into the host cell and manipulate host cell components, control the ability to replicate and/or survive in host cells. Due to the complexity and heterogeneity of Salmonella infections, there is growing recognition of the need for single‐cell and live‐cell imaging approaches to identify and characterize the diversity of cellular phenotypes and how they evolve over time. Here, we establish a pipeline for long‐term (17 h) live‐cell imaging of infected cells and subsequent image analysis methods. We apply this pipeline to track bacterial replication within the Salmonella‐containing vacuole in epithelial cells, quantify vacuolar replication versus survival in macrophages and investigate the role of individual effector proteins in mediating these parameters. This approach revealed that dispersed bacteria can coalesce at later stages of infection, that the effector protein SseG influences the propensity for cytosolic hyper‐replication in epithelial cells, and that while SteA only has a subtle effect on vacuolar replication in epithelial cells, it has a profound impact on infection parameters in immunocompetent macrophages, suggesting differential roles for effector proteins in different infection models.     

Identification and functional characterization of K+ transporters encoded by Legionella pneumophila kup genes

Legionnaires' disease is an emerging, severe, pneumonia‐like illness caused by the Gram‐negative intracellular bacteria Legionella pneumophila, which are able to infect and replicate intracellularly in macrophages. Little is known regarding the mechanisms used by intracellular L. pneumophila for the acquisition of specific nutrients that are essential for bacterial replication. Here, we investigate three L. pneumophila genes with high similarity to the Escherichia coli K⁺ transporters. These three genes were expressed by L. pneumophila and have been designated kupA, kupB and kupC. Investigation using the L. pneumophila kup mutants revealed that kupA is involved in K⁺ acquisition during axenic growth. The kupA mutants replicated efficiently in rich axenic media, but poorly in a chemically defined medium. The kupA mutants were defective in the recruitment of polyubiquitinated proteins to the Legionella‐containing vacuole that is formed in macrophages and displayed an intracellular multiplication defect during the replication in Acanthamoeba castellanii and in mouse macrophages. We found that bafilomycin treatment of macrophages was able to rescue the growth defects of kupA mutants, but itdid not influence the replication of wild‐type bacteria. The defects identified in kupA mutants of L. pneumophila were complemented by the expression E. coli trkD/Kup gene in trans, a bona fide K⁺ transporter encoded by E. coli. Collectively, our data indicate that KupA is a functional K⁺ transporter expressed by L. pneumophila that facilitates the bacterial replication intracellularly and in nutrient‐limited conditions.