Aphid transmission of cauliflower mosaic virus requires the viral PIII protein

The open reading frame (ORF) III product (PIII) of cauliflower mosaic virus is necessary for the infection cycle but its role is poorly understood. We have used in vitro protein binding ('far Western') assays to demonstrate that PIII interacts with the cauliflower mosaic virus (CaMV) ORF II product (PII), a known aphid transmission factor. Aphid transmission of purified virions of the PII-defective strain CM4-184 was dependent upon added PII, but complementation was efficient only in the presence of PIII, demonstrating the requirement of PIII for transmission. Deletion mutagenesis mapped the interaction domains of PIII and PII to the 30 N-terminal and 61 C-terminal residues of PIII and PII, respectively. A model for interaction between PIII and PII is proposed on the basis of secondary structure predictions. Finally, a direct correlation between the ability of PIII and PII to interact and aphid transmissibility of the virus was demonstrated by using mutagenized PIII proteins. Taken together, these data argue strongly that PIII is a second 'helper' factor required for CaMV transmission by aphids.     

Stabilization of cauliflower mosaic virus P3 tetramer by covalent linkage

Cauliflower mosaic virus (CaMV) open reading frame (ORF) III encodes a 15 kDa protein (P3) that is indispensable for viral infectivity. Although P3 has been shown to be a prerequisite for CaMV aphid transmission, its role in viral replication remains unknown. We previously showed that P3 forms a tetramer in planta and that P3 tetramer co-sediments with viral coat protein on sucrose gradient centrifugation, suggesting that a tetramer may be the functional form of P3. We presumed that disulfide bonds were involved in tetramer formation because 1) the tetramer was detected by Western blotting after electrophoresis under non-reducing conditions, and 2) the cysteine-X-cysteine motif is well conserved in CaMV P3 and P3 homologues among Caulimoviruses. Therefore we mutated either or both of the cysteine residues of CaMV P3. The mutant viruses were infectious and accumulated to a similar extent as the wild-type. An analysis of mutant proteins confirmed that the wild-type P3 molecules in the tetramer are covalently bound with one another through disulfide bonds. It was also suggested that mutant proteins are less stable than wild-type protein in planta. Furthermore, sedimentation study suggested that the disulfide bonds are involved in stable association of P3 with CaMV virions or virion-like particles, or both. The mutant viruses could be transmitted by aphids. These results suggested that the covalent bonds in P3 tetramer are dispensable for biological activity of P3 under experimental situations and may have some biological significance in natural infection in the field.     

Cauliflower mosaic virus ORF III product forms a tetramer in planta: its implication in viral DNA folding during encapsidation.

Cauliflower mosaic virus (CaMV) open reading frame (ORF) III encodes a 15 kDa protein; the function of which is as yet unknown. This protein has non-sequence-specific DNA binding activity and is associated with viral particles, suggesting that the ORF III product (P3) is involved in the folding of CaMV DNA during encapsidation. In this study, we demonstrated that P3 forms a tetramer in CaMV-infected plants. A P3-related protein with an apparent molecular weight of 60 kDa was detected by Western blotting analysis using anti-P3 antiserum under non-reducing conditions, while only 15 kDa P3 was detected under reducing conditions. Analysis of P3 using viable mutants with a 27-bp insertion in either ORF III or IV revealed that the 60 kDa protein was a tetramer of P3. The P3 tetramer co-sedimented with viral coat protein in multiple fractions on sucrose gradient centrifugation, suggesting that P3 tetramer binds to mature and immature virions. These results strongly suggested that CaMV P3 forms a tetramer in planta and that disulfide bonds are involved in its formation and/or stabilization. The finding of P3 tetramer in planta suggested that viral DNA would be folded compactly by the interaction with multiple P3 molecules, which would form tetramers, while being packaged into the capsid shell.     

The cauliflower mosaic virus virion-associated protein is dispensable for viral replication in single cells

Cauliflower mosaic virus (CaMV) open reading frame III (ORF III) codes for a virion-associated protein (Vap), which is one of two viral proteins essential for aphid transmission. However, unlike the aphid transmission factor encoded by CaMV ORF II, Vap is also essential for systemic infection, suggesting that it is a multifunctional protein. To elucidate the additional function or functions of Vap, we tested the replication of noninfectious ORF III-defective mutants in transfected turnip protoplasts. PCR and Western blot analyses revealed that CaMV replication had occurred with an efficiency similar to that of wild-type virus and without leading to reversions. Electron microscopic examination revealed that an ORF III frameshift mutant formed normally structured virions. These results demonstrate that Vap is dispensable for replication in single cells and is not essential for virion morphogenesis. Analysis of inoculated turnip leaves showed that the ORF III frameshift mutant does not cause any detectable local infection. These results are strongly indicative of a role for Vap in virus movement.     

Interaction of the cauliflower mosaic virus coat protein with the pregenomic RNA leader

Using the yeast three-hybrid system, the interaction of the Cauliflower mosaic virus (CaMV) pregenomic 35S RNA (pgRNA) leader with the viral coat protein, its precursor, and a series of derivatives was studied. The purine-rich domain in the center of the pgRNA leader was found to specifically interact with the coat protein. The zinc finger motif of the coat protein and the preceding basic domain were essential for this interaction. Removal of the N-terminal portion of the basic domain led to loss of specificity but did not affect the strength of the interaction. Mutations of the zinc finger motif abolished not only the interaction with the RNA but also viral infectivity. In the presence of the very acidic C-terminal domain, which is part of the preprotein but is not present in the mature CP, the interaction with the RNA was undetectable.     

Molecular basis for mitochondrial localization of viral particles during beet necrotic yellow vein virus infection

During infection, Beet necrotic yellow vein virus (BNYVV) particles localize transiently to the cytosolic surfaces of mitochondria. To understand the molecular basis and significance of this localization, we analyzed the targeting and membrane insertion properties of the viral proteins. ORF1 of BNYVV RNA-2 encodes the 21-kDa major coat protein, while ORF2 codes for a 75-kDa minor coat protein (P75) by readthrough of the ORF1 stop codon. Bioinformatic analysis highlighted a putative mitochondrial targeting sequence (MTS) as well as a major (TM1) and two minor (TM3 and TM4) transmembrane regions in the N-terminal part of the P75 readthrough domain. Deletion and gain-of-function analyses based on the localization of green fluorescent protein (GFP) fusions showed that the MTS was able to direct a reporter protein to mitochondria but that the protein was not persistently anchored to the organelles. GFP fused either to MTS and TM1 or to MTS and TM3-TM4 efficiently and specifically associated with mitochondria in vivo. The actual role of the individual domains in the interaction with the mitochondria seemed to be determined by the folding of P75. Anchoring assays to the outer membranes of isolated mitochondria, together with in vivo data, suggest that the TM3-TM4 domain is the membrane anchor in the context of full-length P75. All of the domains involved in mitochondrial targeting and anchoring were also indispensable for encapsidation, suggesting that the assembly of BNYVV particles occurs on mitochondria. Further data show that virions are subsequently released from mitochondria and accumulate in the cytosol.     

Structure of the mature P3-virus particle complex of cauliflower mosaic virus revealed by cryo-electron microscopy

The cauliflower mosaic virus (CaMV) has an icosahedral capsid composed of the viral protein P4. The viral product P3 is a multifunctional protein closely associated with the virus particle within host cells. The best-characterized function of P3 is its implication in CaMV plant-to-plant transmission by aphid vectors, involving a P3-virion complex. In this transmission process, the viral protein P2 attaches to virion-bound P3, and creates a molecular bridge between the virus and a putative receptor in the aphid's stylets. Recently, the virion-bound P3 has been suggested to participate in cell-to-cell or long-distance movement of CaMV within the host plant. Thus, as new data accumulate, the importance of the P3-virion complex during the virus life-cycle is becoming more and more evident. To provide a first insight into the knowledge of the transmission process of the virus, we determined the 3D structures of native and P3-decorated virions by cryo-electron microscopy and computer image processing. By difference mapping and biochemical analysis, we show that P3 forms a network around the capsomers and we propose a structural model for the binding of P3 to CaMV capsid in which its C terminus is anchored deeply in the inner shell of the virion, while the N-terminal extremity is facing out of the CaMV capsid, forming dimers by coiled-coil interactions. Our results combined with existing data reinforce the hypothesis that this coiled-coil N-terminal region of P3 could coordinate several functions during the virus life-cycle, such as cell-to-cell movement and aphid-transmission.     

The polerovirus minor capsid protein determines vector specificity and intestinal tropism in the aphid

Aphid transmission of poleroviruses is highly specific, but the viral determinants governing this specificity are unknown. We used a gene exchange strategy between two poleroviruses with different vectors, Beet western yellows virus (BWYV) and Cucurbit aphid-borne yellows virus (CABYV), to analyze the role of the major and minor capsid proteins in vector specificity. Virus recombinants obtained by exchanging the sequence of the readthrough domain (RTD) between the two viruses replicated in plant protoplasts and in whole plants. The hybrid readthrough protein of chimeric viruses was incorporated into virions. Aphid transmission experiments using infected plants or purified virions revealed that vector specificity is driven by the nature of the RTD. BWYV and CABYV have specific intestinal sites in the vectors for endocytosis: the midgut for BWYV and both midgut and hindgut for CABYV. Localization of hybrid virions in aphids by transmission electron microscopy revealed that gut tropism is also determined by the viral origin of the RTD.     

Virus Factories of Cauliflower Mosaic Virus Are Virion Reservoirs That Engage Actively in Vector Transmission

Cauliflower mosaic virus (CaMV) forms two types of inclusion bodies within infected plant cells: numerous virus factories, which are the sites for viral replication and virion assembly, and a single transmission body (TB), which is specialized for virus transmission by aphid vectors. The TB reacts within seconds to aphid feeding on the host plant by total disruption and redistribution of its principal component, the viral transmission helper protein P2, onto microtubules throughout the cell. At the same time, virions also associate with microtubules. This redistribution of P2 and virions facilitates transmission and is reversible; the TB reforms within minutes after vector departure. Although some virions are present in the TB before disruption, their subsequent massive accumulation on the microtubule network suggests that they also are released from virus factories. Using drug treatments, mutant viruses, and exogenous supply of viral components to infected protoplasts, we show that virions can rapidly exit virus factories and, once in the cytoplasm, accumulate together with the helper protein P2 on the microtubule network. Moreover, we show that during reversion of this phenomenon, virions from the microtubule network can either be incorporated into the reverted TB or return to the virus factories. Our results suggest that CaMV factories are dynamic structures that participate in vector transmission by controlled release and uptake of virions during TB reaction.     

Protection against virus infection in tobacco plants expressing the coat protein of grapevine fanleaf nepovirus

Summary Grapevine fanleaf nepovirus (GFLV) is responsible for the economically significant court-noué disease in vineyards. Its genome is made up of two single-stranded RNA molecules (RNA1 and RNA2) which direct the synthesis of polyproteins P1 and P2 respectively. A chimeric coat protein gene derived from the C-terminal part of P2 was constructed and subsequently introduced into a binary transformation vector. Transgenic Nicotiana benthamiana plants expressing the coat protein under the control of the CaMV 35S promoter were engineered by Agrobacterium tumefaciens-mediated transformation. Protection against infection with virions or viral RNA was tested in coat protein-expressing plants. A significant delay of systemic invasion was observed in transgenic plants inoculated with virus compared to control plants. This effect was also observed when plants were inoculated with viral RNA. No coat protein-mediated cross-protection was observed when transgenic plants were infected with arabis mosaic virus (ArMV), a closely related nepovirus also responsible for a court-noué disease.Abbreviations GFLV-F13 grapevine fanleaf virus F13 isolate - ArMV arabis mosaic virus - CP coat protein - MS Murashige and Skoog - NPTII neomycin phosphotransferase II - CaMV cauliflower mosaic virus - ELISA enzyme linked immunosorbent assay - VPg genome linked viral protein - TMV tobacco mosaic virus - PVX potato virus X - PVY potato virus Y - TRV tobacco rattle virus - +CP CP expressing - -CP control plant, not expressing CP - CPMP coat protein-mediated protection - CPMCP coat crotein-mediated cross protection     

Distinct domains in ORF52 tegument protein mediate essential functions in murine gammaherpesvirus 68 virion tegumentation and secondary envelopment

Epstein-Barr virus and Kaposi's sarcoma-associated herpesvirus are etiologically associated with several types of human malignancies. However, as these two human gammaherpesviruses do not replicate efficiently in cultured cells, the morphogenesis of gammaherpesvirus virions is poorly understood. Murine gammaherpesvirus 68 (MHV-68) provides a tractable model to define common, conserved features of gammaherpesvirus biology. ORF52 of MHV-68 is conserved among gammaherpesviruses. We have previously shown that this tegument protein is essential for the envelopment and egress of viral particles and solved the crystal structure of ORF52 dimers. To more closely examine its role in virion maturation, we performed immunoelectron microscopy of MHV-68-infected cells and found that ORF52 localized to both mature, extracellular virions and immature viral particles in the cytoplasm. ORF52 consists of three α-helices followed by one β-strand. To understand the structural requirements for ORF52 function, we constructed mutants of ORF52 and examined their ability to complement an ORF52-null MHV-68 virus. Mutations in conserved residues in the N-terminal α1-helix and C terminus, or deletion of the α2-helix, resulted in a loss-of-function phenotype. Furthermore, the α1-helix was crucial for the predominantly punctate cytoplasmic localization of ORF52, while the α2-helix was a key domain for ORF52 dimerization. Immunoprecipitation experiments demonstrated that ORF52 interacts with another MHV-68 tegument protein, ORF42; however, a single point mutation in R95 in the C terminus of ORF52 led to the loss of this interaction. Moreover, the homologues of MHV-68 ORF52 in Kaposi's sarcoma-associated herpesvirus and Epstein-Barr virus complement the defect in ORF52-null MHV-68 and interact with MHV-68 ORF52. Taken together, these data uncover the relationship between the α-helical structure and the molecular basis for ORF52 function. This is the first structure-based functional domain mapping study for an essential gammaherpesvirus tegument protein.     

Highly Divergent Strains of Porcine Reproductive and Respiratory Syndrome Virus Incorporate Multiple Isoforms of Nonstructural Protein 2 into Virions

Viral structural proteins form the critical intermediary between viral infection cycles within and between hosts, function to initiate entry, participate in immediate early viral replication steps, and are major targets for the host adaptive immune response. We report the identification of nonstructural protein 2 (nsp2) as a novel structural component of the porcine reproductive and respiratory syndrome virus (PRRSV) particle. A set of custom α-nsp2 antibodies targeting conserved epitopes within four distinct regions of nsp2 (the PLP2 protease domain [OTU], the hypervariable domain [HV], the putative transmembrane domain [TM], and the C-terminal region [C]) were obtained commercially and validated in PRRSV-infected cells. Highly purified cell-free virions of several PRRSV strains were isolated through multiple rounds of differential density gradient centrifugation and analyzed by immunoelectron microscopy (IEM) and Western blot assays using the α-nsp2 antibodies. Purified viral preparations were found to contain pleomorphic, predominantly spherical virions of uniform size (57.9 nm ± 8.1 nm diameter; n = 50), consistent with the expected size of PRRSV particles. Analysis by IEM indicated the presence of nsp2 associated with the viral particle of diverse strains of PRRSV. Western blot analysis confirmed the presence of nsp2 in purified viral samples and revealed that multiple nsp2 isoforms were associated with the virion. Finally, a recombinant PRRSV genome containing a myc-tagged nsp2 was used to generate purified virus, and these particles were also shown to harbor myc-tagged nsp2 isoforms. Together, these data identify nsp2 as a virion-associated structural PRRSV protein and reveal that nsp2 exists in or on viral particles as multiple isoforms.     

Biochemical characterization of the helper component of Cauliflower mosaic virus

The helper component of Cauliflower mosaic virus is encoded by viral gene II. This protein (P2) is dispensable for virus replication but required for aphid transmission. The purification of P2 has never been reported, and hence its biochemical properties are largely unknown. We produced the P2 protein via a recombinant baculovirus with a His tag fused at the N terminus. The fusion protein was purified by affinity chromatography in a soluble and biologically active form. Matrix-assisted laser desorption time-of-flight mass spectrometry demonstrated that P2 is not posttranslationally modified. UV circular dichroism revealed the secondary structure of P2 to be 23% alpha-helical. Most alpha-helices are suggested to be located in the C-terminal domain. Using size exclusion chromatography and aphid transmission testing, we established that the active form of P2 assembles as a huge soluble oligomer containing 200 to 300 subunits. We further showed that P2 can also polymerize as long paracrystalline filaments. We mapped P2 domains involved in P2 self-interaction, presumably through coiled-coil structures, one of which is proposed to form a parallel trimer. These regions have previously been reported to also interact with viral P3, another protein involved in aphid transmission. Possible interference between the two types of interaction is discussed with regard to the biological activity of P2.     

Kaposi's Sarcoma-Associated Herpesvirus ORF45 Interacts with Kinesin-2 Transporting Viral Capsid-Tegument Complexes along Microtubules

Open reading frame (ORF) 45 of Kaposi''s sarcoma-associated herpesvirus (KSHV) is a tegument protein. A genetic analysis with a null mutant suggested a possible role for this protein in the events leading to viral egress. In this study, ORF45 was found to interact with KIF3A, a kinesin-2 motor protein that transports cargoes along microtubules to cell periphery in a yeast two-hybrid screen. The association was confirmed by both co-immunoprecipitation and immunoflorescence approaches in primary effusion lymphoma cells following virus reactivation. ORF45 principally mediated the docking of entire viral capsid-tegument complexes onto the cargo-binding domain of KIF3A. Microtubules served as the major highways for transportation of these complexes as evidenced by drastically reduced viral titers upon treatment of cells with a microtubule depolymerizer, nocodazole. Confocal microscopic images further revealed close association of viral particles with microtubules. Inhibition of KIF3A–ORF45 interaction either by the use of a headless dominant negative (DN) mutant of KIF3A or through shRNA-mediated silencing of endogenous KIF3A expression noticeably decreased KSHV egress reflecting as appreciable reductions in the release of extracellular virions. Both these approaches, however, failed to impact HSV-1 egress, demonstrating the specificity of KIF3A in KSHV transportation. This study thus reports on transportation of KSHV viral complexes on microtubules by KIF3A, a kinesin motor thus far not implicated in virus transportation. All these findings shed light on the understudied but significant events in the KSHV life cycle, delineating a crucial role of a KSHV tegument protein in cellular transport of viral particles.     

Aphid transmission of cauliflower mosaic virus: The role of the host plant

Transmission of plant viruses is the result of interactions between a given virus, the host plant and the vector. Most research has focused on molecular and cellular virus-vector interactions, and the host has only been regarded as a reservoir from which the virus is acquired by the vector more or less accidentally. However, a growing body of evidence suggests that the host can play a crucial role in transmission. Indeed, at least one virus, Cauliflower mosaic virus, exploits the host''s cellular pathways to form specialized intracellular structures that optimize virus uptake by the vector and hence transmission.Key words: virus, vector, host plant, transmission, interactionsTransmission is a step in a virus''s life cycle that is often neglected. Nonetheless, it is obvious that also this step is obligatory for a virus, as it could not maintain itself without dispersing to other hosts and infecting them. Most plant viruses are transmitted by insects, using two different strategies: “circulant transmission” where the virus, once taken up by the vector during feeding on an infected plant, passes from the intestine via the body lumen to the salivary glands and is finally inoculated with the saliva into a new host plant; the second strategy is “non-circulant transmission” where transmissible virus particles attach only to the exterior mouthpieces of the insect from which they are released into a new host. Whereas the first strategy obviously requires highly specific interactions between the virus and the vector to allow for passage of the virus through the vector, non-circulant transmission was initially thought of as a more or less accidental event, where virus sticks non-specifically to the mouthpieces. However, it becomes more and more evident that also non-circulant transmission is the result of sophisticated interactions between a given virus, a host and a vector. The vectors are most often aphids that, due to their non-destructive feeding behavior, are ideally suited as virus vectors. In fact, once landed on a plant, aphids first probe the prospective food source by short, only seconds lasting intracellular punctures in epidermis and mesophyll cells that do not even kill the punctured cells.¹ After these exploratory punctures and when they judge the plant as suited, the aphids insert their proboscis-like mouthpieces (stylets) into the phloem and feed from its sap for time spans that may exceed several hours. Depending on the tissues they infect, plant viruses can be acquired by aphids during either or only one of the two puncture phases. For example, Luteoviruses are only acquired from the vascular tissues,² whereas Cauliflower mosaic virus is acquired from both tissues.³Cauliflower mosaic virus (CaMV) is one of the best studied viruses on what concerns non-circulant transmission, the most often used transmission mode employed by plant viruses. For its transmission, a transmissible complex must form that attaches to a protein receptor located in the stylets of the aphid.⁴ This complex is not only, as for some viruses, composed of the virus particle, but also, as for many non-circulantly transmitted plant viruses, of a viral helper protein that with one domain interacts with the virus particle and with another with the stylet receptor⁵ (Fig. 1A). The helper protein of CaMV, P2, seems to have no other function but to assist in transmission as CaMV mutants deleted of P2 are perfectly infectious but not transmissible.⁶ A puzzling fact is that P2 may be acquired independently of the virus particle, meaning that it alone can bind to the stylet receptor and that virus particles either attach concomitantly with P2 onto the stylets or later attach to pre-bound P2. This has consequences for the composition of the transmitted viral population as it can be compiled of virus particles originating from the same cell from which P2 was acquired, but also from other cells and even sieve tubes that themselves do not contain P2.³ In fact, this potentially sequential acquisition mode of CaMV by the vector is controlled by the intracellular⁷ and tissue-specific localization of P2 that is only found in epidermis and parenchyma cells.³ In these cells, P2 localizes exclusively in a single viral inclusion, the transmission body, that has been proposed and recently been shown to be specialized for transmission:^8–10 if this structure does not form, CaMV can not be taken up by the aphid, even if functional P2 is present in the infected cell.Open in a separate windowFigure 1(A) The different strategies of non-circulant transmission: Viruses (V) using the capsid strategy (CS) attach directly to a receptor (R) in the tip of the a proboscis forming aphid stylets (blue), whereas in the helper strategy (HS) this interaction is mediated by the viral helper protein (H) that binds the virus particle to the receptor. Note that the helper protein can bind independently of the virus to the stylets. Whether the same receptor is used by different viruses as presented in the schema, is not known. (B) A turnip protoplast transfected with CaMV was double-labelled late in infection for CaMV helper protein P2 (red) and the marker protein for the virus factories P6 (green). It is visible that P2 localizes in a single, large transmission body, whereas the numerous virus factories are devoid of P2 (Colocalization would be revealed by yellowish color (M) in this superposition). (C and D) Turnip protoplasts were cotransfected with CaMV and TBK5-GFP and immunolabelled for P2 (red) and TBK5 was detected by GFP fluorescence. (C) shows a cell early in infection, where P2 and TBK5-GFP colocalize on a network that we identified as the microtubule cytoskeleton (unpublished data). (D) shows a cell later in infection where P2 and TBK5-GFP colocalize, as indicated by the yellowish color, in a transmission body. Note that TBK5-GFP also strongly labels the nucleus (N).This posed the interesting question how the transmission body forms during infection because elucidating this mechanism would show that CaMV hijacks cellular pathways for the sole purpose to ensure its transmission. It was known that besides the single transmission body a second type of viral inclusion bodies is found in infected cells: the numerous “electron-dense inclusions” that are assumed to be the virus factories (Fig. 1B) where all viral synthesis occurs¹¹ and where most virus particles accumulate. However, P2 was never described in the factories, presenting the paradox: if it is translated in the factories why is it not found there? Of different possible scenarios we chose to test the hypothesis that P2 is produced in the factories and then exported. Protoplasts were transfected with CaMV particles and kinetics of P2 accumulation followed by immunofluorescence. The results showed that P2 is indeed translated in the viral factories but then associates temporally with microtubules before finally condensing into a single transmission body. Also the other known components of the transmission body, the viral protein P3 and to a lesser degree, some virus particles, followed the same route from viral factories to the transmission body.Experiments with cytoskeleton drugs confirmed that transient localization of transmission body components with microtubules, but not with actin filaments, is necessary for transmission body formation. The results also indicated that both microtubules and actin filaments are apparently not required for other steps of the intracellular infection cycle because formation of viral factories was only slightly inhibited by the drugs.The results show that CaMV specifically uses the microtubule cytoskeleton to form the transmission body and thus enable vector transmission. Consequently, non-circulant transmission of at least this virus is not a random event where the vector takes up some transmissible complexes by chance. It is rather the result of highly specific interactions, where the virus “intentionally” (ab)uses cellular pathways to optimize acquisition by the vector, and this long before arrival of the latter on an infected plant.A lot of questions remain open, though. Are P2 and the other components of the transmission body actively transported on microtubules, or is their transient colocalization with microtubules part of an alternative transport mode? We started to more closely examine interaction between P2 and microtubules and privileged the hypothesis that the protein might be transported by a motor activity on microtubules. As preliminary data indicated that P2 does not possess an innate translocating activity, we looked for a cellular motor protein and tested as a candidate the kinesin TBK5.¹² This transport protein is, when overexpressed, able to bundle microtubules into a single focus, just as transmission bodies are singular structures in the cell. When healthy protoplasts were cotransfected with TBK5 and CaMV, TBK5 localized transiently with P2 on microtubules and in transmission bodies (Fig. 1C and D). This might be taken as the first evidence that a kinesin might be involved in formation of transmission bodies, but more experimentation is needed to confirm this hypothesis.A by far more important question is: Have also other viruses, whether from the plant or the animal kingdoms, that are noncirculantly (or mechanically, as animal virologists call this mode of transmission) transmitted, developed similar strategies that fine-tune interactions between the host and the virus to prepare and perfect transmission?     

Delineating the site of interaction on the pIII protein of filamentous bacteriophage fd with the F-pilus of Escherichia coli

The minor coat protein pIII at one end of the filamentous bacteriophage fd, mediates the infection of Escherichia coli cells displaying an F-pilus. pIII has three domains (D1, D2 and D3), terminating with a short hydrophobic segment at the C-terminal end. Domain D2 binds to the tip of F-pilus, which is followed by retraction of the pilus and penetration of the E. coli cell membrane, the latter involving an interaction between domain D1 and the TolA protein in the membrane. Surface residues on the D2 domain of pIII were replaced systematically with alanine. Mutant virions were screened for D2-pilus interaction in vivo by measuring the release of infectious virions from E. coli F(+) cells infected with the mutants. A competitive ELISA was developed to measure in vitro the ability of mutant phages to bind to purified pili. This allowed the identification of amino acid residues involved in binding to F and to EDP208 pili. These residues were found to cluster on the outer rim of the 3D structure of the D2 domain, unexpectedly identifying this as the F-pilus binding region on the pIII protein.     

A role for plant microtubules in the formation of transmission-specific inclusion bodies of Cauliflower mosaic virus

Interactions between microtubules and viruses play important roles in viral infection. The best-characterized examples involve transport of animal viruses by microtubules to the nucleus or other intracellular destinations. In plant viruses, most work to date has focused on interaction between viral movement proteins and the cytoskeleton, which is thought to be involved in viral cell-to-cell spread. We show here, in Cauliflower mosaic virus (CaMV)-infected plant cells, that viral electron-lucent inclusion bodies (ELIBs), whose only known function is vector transmission, require intact microtubules for their efficient formation. The kinetics of the formation of CaMV-related inclusion bodies in transfected protoplasts showed that ELIBs represent newly emerging structures, appearing at late stages of the intracellular viral life cycle. Viral proteins P2 and P3 are first produced in multiple electron-dense inclusion bodies, and are later specifically exported to transiently co-localize with microtubules, before concentrating in a single, massive ELIB in each infected cell. Treatments with cytoskeleton-affecting drugs suggested that P2 and P3 might be actively transported on microtubules, by as yet unknown motors. In addition to providing information on the intracellular life cycle of CaMV, our results show that specific interactions between host cell and virus may be dedicated to a later role in vector transmission. More generally, they indicate a new unexpected function for plant cell microtubules in the virus life cycle, demonstrating that microtubules act not only on immediate intracellular or intra-host phenomena, but also on processes ultimately controlling inter-host transmission.     

Distinct mechanisms of neutralization by monoclonal antibodies specific for sites in the N-terminal or C-terminal domain of murine leukemia virus SU

The epitope specificities and functional activities of monoclonal antibodies (MAbs) specific for the murine leukemia virus (MuLV) SU envelope protein subunit were determined. Neutralizing antibodies were directed towards two distinct sites in MuLV SU: one overlapping the major receptor-binding pocket in the N-terminal domain and the other involving a region that includes the most C-terminal disulfide-bonded loop. Two other groups of MAbs, reactive with distinct sites in the N-terminal domain or in the proline-rich region (PRR), did not neutralize MuLV infectivity. Only the neutralizing MAbs specific for the receptor-binding pocket were able to block binding of purified SU and MuLV virions to cells expressing the ecotropic MuLV receptor, mCAT-1. Whereas the neutralizing MAbs specific for the C-terminal domain did not interfere with the SU-mCAT-1 interaction, they efficiently inhibited cell-to-cell fusion mediated by MuLV Env, indicating that they interfered with a postattachment event necessary for fusion. The C-terminal domain MAbs displayed the highest neutralization titers and binding activities. However, the nonneutralizing PRR-specific MAbs bound to intact virions with affinities similar to those of the neutralizing receptor-binding pocket-specific MAbs, indicating that epitope exposure, while necessary, is not sufficient for viral neutralization by MAbs. These results identify two separate neutralization domains in MuLV SU and suggest a role for the C-terminal domain in a postattachment step necessary for viral fusion.     

Regulation of filamentous bacteriophage length by modification of electrostatic interactions between coat protein and DNA

Bacteriophage fd gene VIII, which encodes the major capsid protein, was mutated to convert the serine residue at position 47 to a lysine residue (S47K), thereby increasing the number of positively charged residues in the C-terminal region of the protein from four to five. The S47K coat protein underwent correct membrane insertion and processing but could not encapsidate the viral DNA, nor was it incorporated detectably with wild-type coat proteins into hybrid bacteriophage particles. However, hybrid virions could be constructed from the S47K coat protein and a second mutant coat protein, K48Q, the latter containing only three lysine residues in its C-terminal region. K48Q phage particles are approximately 35% longer than wild-type. Introducing the S47K protein shortened these particles, the S47K/K48Q hybrids exhibiting a range of lengths between those of K48Q and wild-type. These results indicate that filamentous bacteriophage length (and the DNA packaging underlying it) are regulated by unusually flexible electrostatic interactions between the C-terminal domain of the coat protein and the DNA. They strongly suggest that wild-type bacteriophage fd makes optimal use of the minimum number of coat protein subunits to package the DNA compactly.