Abstract
Vector-borne pathogens influence host characteristics relevant to host–vector contact, increasing pathogen transmission and survival. Previously, we demonstrated that infection with Turnip mosaic virus, a member of one of the largest families of plant-infecting viruses, increases vector attraction and reproduction on infected hosts. These changes were due to a single viral protein, NIa-Pro. Here we show that NIa-Pro responds to the presence of the aphid vector during infection by relocalizing to the vacuole. Remarkably, vacuolar localization is required for NIa-Pro’s ability to enhance aphid reproduction on host plants, vacuole localization disappears when aphids are removed, and this phenomenon occurs for another potyvirus, Potato virus Y, suggesting a conserved role for the protein in vector–host interactions. Taken together, these results suggest that potyviruses dynamically respond to the presence of their vectors, promoting insect performance and transmission only when needed.
Similar content being viewed by others
Introduction
Viruses dominate our planet, parasitizing all forms of life including other viruses. Because viruses are obligate parasites, they must encounter and then infect susceptible hosts to survive. After successful infection, transmission of a virus to the next host is a critical step for survival. Due to their limited mobility, many viruses, including ∼80% of all plant-infecting viruses, rely on other organisms for transmission1. The specific organism that transmits a virus is known as a vector. Vectors are found among many different taxa, but for plant-infecting viruses they most often are hemipteran arthropods, and in particular aphids2,3,4.
Because of their agricultural importance, plant viruses and their transmission have been the subject of research for more than a century. It has been documented that the yellow leaf colour and specific volatiles emitted by diseased plants modulate attractiveness for vectors (for review, see refs 5, 6). In parallel, several studies have shown that viruses can suppress plant defences and thus vectors feeding on virus-infected plants often possess greater fitness than those residing on healthy plants (for review, see refs 5, 7, 8, 9, 10). These findings suggest that viruses may facilitate their own transmission by modulating host characteristics. Recently, it has been demonstrated that Cauliflower mosaic virus (CaMV) responds actively to the presence of its vector, changing transmission body morphs and increasing the potential for transmission11. This new concept in virology has been called ‘perceptive viral behaviour’ and relies on the fact that viruses respond directly or via the host to potential vectors11.
Turnip mosaic virus (TuMV) is considered to be one of the most damaging viruses of vegetable crops worldwide12,13,14, infecting >300 species of dicotyledonous plants15. TuMV is a member of the Potyviridae family and is non-persistently transmitted by >80 aphid species including Myzus persicae (green peach aphid)16. Its genome is a single ∼10 kb RNA molecule that codes for a large polyprotein plus the pipo frameshift protein. The polyprotein is cleaved into 1 coat protein and 10 non-structural products via 3 virus-encoded proteinases named P1 protein (P1), Helper component proteinase (HC-Pro) and Nuclear inclusion protein a protease (NIa-Pro)17,18,19. During infection, NIa-Pro exists as a fully processed form and as a fusion with another TuMV protein, the viral genome-linked protein (VPg)19,20,21. The fusion contains VPg at the N terminus and NIa-Pro at the C terminus and is known as ‘NIa’ (Fig. 1a). Previously, we demonstrated that TuMV infection suppresses callose deposition, an important plant defence induced in response to aphid feeding, and increases aphid fecundity on infected plants. We determined that expression of NIa-Pro was responsible for decreased plant defences and increased aphid reproduction through changes in the phytohormone ethylene9,22. However, the cellular mechanisms by which NIa-Pro mediates changes in plant physiology remain unclear.
In this study, we investigate the subcellular localization of NIa-Pro and the function of localization in virus–vector–plant interactions. We demonstrate that NIa-Pro localizes in the cytoplasm and in the nucleus, similar to the precursor NIa (VPg:NIa-Pro) during infection20. However, in the presence of the insect vector, NIa-Pro relocalizes to the vacuole of the cell and this relocalization is essential for its ability to decrease plant defences and increase aphid performance on host plants. Surprisingly, when aphids are removed NIa-Pro disappears from the vacuole, suggesting that TuMV promotes vector performance only when needed. Furthermore, we demonstrate that this may be a more general phenomenon for potyviruses, one of the largest genera of plant-infecting RNA viruses23. These results demonstrate that NIa-Pro responds actively to the presence of the insect vector and links a biochemical and ecological function to the relocalization, a phenomenon never before demonstrated.
Results
The NIa-Pro protein is required to increase aphid fecundity
Previously we demonstrated that TuMV NIa-Pro promotes aphid performance and suppresses plant defences9. To confirm that the NIa-Pro protein versus its RNA sequence mediates increased aphid fecundity on host plants, we made a new construct that contains the full sequence of the NIa-Pro open reading frame but prevents production of the functional protein in a green fluorescent protein (GFP)-expressing vector. The construct introduced one extra thymine immediately after the first codon of the NIa-Pro open reading frame, resulting in a frameshift mutation that generates a stop codon directly after the first codon, thus preventing production of the functional protein (GFP:NIa-Pro:Fs; Supplementary Fig. 1a–c). To determine whether NIa-Pro protein production is critical for enhancing aphid performance, we performed fecundity tests on Nicotiana benthamiana transiently expressing GFP:NIa-Pro, GFP:NIa-Pro:Fs or the empty expression vector (free GFP). Consistent with our previous findings, expression of NIa-Pro increased aphid fecundity compared with aphids feeding on plants expressing the free GFP9. Inhibiting production of the NIa-Pro protein in the NIa-Pro:Fs mutant led to no increase in aphid fecundity (Supplementary Fig. 1d). This result demonstrates that host plant changes mediating increased aphid fecundity are conferred by the NIa-Pro protein and not by its RNA sequence.
NIa-Pro relocalizes in the cell with aphids present
To analyse the intracellular localization of NIa-Pro, we transiently expressed NIa-Pro fused to GFP under the control of the 35S promoter (GFP:NIa-Pro) in N. benthamiana plants (Fig. 1a). As a control we used the same construct without NIa-Pro in transient expression experiments (free GFP). GFP:NIa-Pro localized to the nucleus and to the cytoplasm of the cell, similar to the free GFP (Fig. 1b). Nuclear localization was verified using 4,6-diamidino-2-phenylindole (DAPI) staining24 and by examining single sections on the confocal microscope (Fig. 1b, single sections shown in small panels). We next wanted to see if the presence of aphids on leaves alters NIa-Pro cellular localization because TuMV and NIa-Pro often occur with insect vectors in nature. To assess this, we allowed aphids to feed for 24 h on leaves transiently expressing free GFP or GFP:NIa-Pro. Surprisingly, aphids induced a relocalization of GFP:NIa-Pro in the cell, whereas free GFP localization did not change in the presence of the aphids (Fig. 1c).
NIa-Pro relocalizes to the vacuole with aphids present
GFP:NIa-Pro appeared to relocalize to the lumen of the vacuole in the presence of aphids25. To confirm vacuolar localization, we stained the leaves with SNARF-1, a marker for the vacuolar lumen26. As expected, when aphids were present GFP:NIa-Pro co-localized with the vacuole, whereas the free GFP control did not (see single sections; Fig. 2a,b). To further confirm localization to the lumen of the vacuole, we used a second marker, the spRFP:AFVY fusion protein27. Using this construct, GFP:NIa-Pro also colocalized with the vacuole when aphids were present, whereas the free GFP did not (see single sections; Fig. 2c,d). We next wanted to confirm that the phenotypes observed were not due to autofluorescence of dead cells using time-lapse imaging. We captured active trafficking of the free GFP control (cytoplasmic streaming) and the GFP:NIa-Pro (intra-vacuolar trafficking) verifying the cells were still alive (Supplementary Fig. 2). Previous studies have demonstrated that the GFP protein can be visualized in the plant vacuole28,29. Nevertheless, in a last control, we excited the GFP:NIa-Pro at 488 nm and performed a scan across 380–800 nm. We observed that the phenotypes observed plus or minus aphids were characteristic of the GFP emission (Supplementary Fig. 3). The scan revealed some chloroplast autofluorescence around 650 nm of emission.
Vacuolar localization disappears when aphids are removed
To determine the kinetics of NIa-Pro relocalization, we next allowed aphids to feed for different durations of time (2, 6 and 24 h) on leaves transiently expressing free GFP or GFP:NIa-Pro. After 2 h of aphid feeding, no relocalization was observed in either treatment, suggesting that insect probing may not be enough to induce the response (Fig. 3a, second panel). However, after 6 h of aphid feeding, cytoplasmic vesicles were observed in plants expressing GFP:NIa-Pro, while there was no change in phenotype for free GFP (Fig. 3a, third panel). After 24 h of aphid feeding, ∼60% of the visible epidermal cells exhibited relocalization of NIa-Pro throughout the vacuole lumen (Fig. 3a, fourth panel; Fig. 3b). The large numbers of cells exhibiting the phenotype after 24 h of feeding suggest that the response is not restricted to cells probed by the aphids, but is instead mediated by a systemic signal. In parallel experiments, aphids were allowed to feed for 24 h and then removed. Leaves were allowed to recover for 2 h before microscopic imaging. Surprisingly, vacuolar localization of GFP:NIa-Pro was no longer observed 2 h after aphid removal (Fig. 3a, right panel), suggesting that GFP:NIa-Pro was able to relocalize to the nucleus or was degraded in the vacuole after aphids were removed. Quantification of three independent experiments established that aphid presence significantly modifies localization of GFP:NIa-Pro and nuclear localization is restored when aphids are removed (Fig. 3b).
Because free GFP is small enough to freely diffuse through the nuclear pore30, we could not discount the fact that the GFP observed in the nucleus in the GFP:NIa-Pro experiments could be GFP cleaved from NIa-Pro. To verify that the GFP from the GFP:NIa-Pro fusion is not cleaved, we performed a western blot with a GFP antibody using the agroinfiltrated N. benthamiana leaves expressing free GFP, GFP:NIa-Pro with and without aphid feeding and after reversion (Fig. 3c). We found that GFP:NIa-Pro is not cleaved (Fig. 3c). Because GFP:NIa-Pro is ∼54 kD and too large to diffuse into the nucleus, our data suggest that the nuclear accumulation of GFP:NIa-Pro is due to a property of NIa-Pro and not just because of its small size, like the free GFP30.
Relocalization is required to increase aphid fecundity
To determine the functional significance of NIa-Pro relocalization in the presence of aphid vectors, we created two NIa-Pro localization mutants. For one mutant, we confined NIa-Pro to the nucleus by adding a strong nuclear localization signal (NLS; PKKKRKV) and for the other, we inhibited nuclear localization by adding a nuclear export signal (NES; NELALKLAGLDINK) to the C-terminal end of NIa-Pro31,32. Localization was verified using transient expression, confocal microscopy and DAPI staining (Fig. 4a–d; Supplementary Fig. 4). Localization of the GFP control and GFP:NIa-Pro was consistent with previous experiments with and without aphids (Fig. 4a,b). In contrast, GFP:NIa-Pro:NLS localized exclusively to the nucleus with and without aphids (Fig. 4c). For the GFP:NIa-Pro:NES construct, some GFP:NIa-Pro:NES still localized to the nucleus before aphid presence, yet in the presence of the aphids there was a greater number of cells with GFP:NIa-Pro:NES in the vacuoles compared with plants expressing GFP:NIa-Pro (Fig. 4d).
Next, we allowed aphids to feed and recorded callose deposition on plants transiently expressing the empty vector (free GFP), GFP:NIa-Pro, GFP:NIa-Pro:NLS and GFP:NIa-Pro:NES. Consistent with our previous findings, callose induction by aphids was significantly reduced in the leaves expressing NIa-Pro compared with free GFP (Fig. 4e)9. Interestingly, aphid-induced callose was not reduced in plants expressing GFP:NIa-Pro:NLS, whereas in plants expressing GFP:NIa-Pro:NES, aphid-induced callose deposition was still inhibited (Fig. 4e). These results suggest that the presence of NIa-Pro outside of the nucleus is required to decrease plant defenses. We also recorded aphid fecundity on plants expressing the NIa-Pro localization mutants and controls. Similar to our previous findings, aphid fecundity was significantly higher on plants transiently expressing GFP:NIa-Pro compared with the free GFP (Fig. 4f; refs 9, 22). In contrast, aphids were not more fecund on plants expressing GFP:NIa-Pro confined to the nucleus as compared with the control (Fig. 4f; GFP:NIa-Pro:NLS).
NIa-Pro relocalizes during actual viral infection
To test whether NIa-Pro behaves similarly during actual viral infection, we expressed the GFP:NIa-Pro fusion in the context of the TuMV genome using an infectious clone. To do this, we used the TuMV backbone pCambia/TuMV/6k2:GFP33 and replaced the 6k2:GFP with GFP:NIa-Pro (Fig. 5a). To verify that the new construct also increases aphid fecundity similar to the unmodified TuMV/GFP9, we performed aphid fecundity experiments with the TuMV/GFP:NIa-Pro. Consistent with our previous findings, TuMV/GFP:NIa-Pro also increased aphid fecundity compared with controls (Fig. 5b; refs 9, 22). A western blot analyses was performed with an antibody specific to the TuMV coat protein to verify the infectivity of the new mutant, TuMV/GFP:NIa-Pro (Fig. 5c). We next examined subcellular localization in the viral context using confocal microscopy. During infection, GFP:NIa-Pro also localized to the nucleus and cytoplasm without aphids and relocalized to the vacuole in the presence of the aphid vectors (Fig. 5d). Quantification of three independent experiments using TuMV/GFP:NIa-Pro established that aphid presence significantly induces GFP:NIa-Pro relocalization in the viral context (Fig. 5e).
Next, we wanted to further confirm vacuole localization using the TuMV/GFP:NIa-Pro infectious clone, vacuole purification and western blotting. We first purified vacuoles from leaves expressing the empty vector or TuMV/GFP:NIa-Pro with or without aphids present. Next, total protein isolated from vacuoles was analysed by western blot using a GFP antibody. Consistent with the microscopy work, GFP:NIa-Pro was only found in vacuoles purified from leaves with aphids present (Fig. 5f). As a loading control a TuMV-CP antibody was used to confirm equal isolation of vacuoles from different treatments (Fig. 5f). Recently, TuMV particles were found in the vacuoles34.
The function of NIa-Pro is conserved
As all potyvirus genomes encode NIa-Pro, we next wanted to determine whether this is a more generalized phenomenon. To address this, we examined the impact of another potyvirus, Potato virus Y (PVY), and expression of its NIa-Pro in host plants on aphid vector performance. Plants infected with PVY increased aphid fecundity compared with controls, similar to TuMV infection (Fig. 6a; refs 9, 22). Perhaps, more interesting plants transiently expressing GFP:NIa-ProPVY also increased aphid fecundity compared with aphids feeding on controls (Fig. 6b). Next, we examined NIa-ProPVY localization using GFP and confocal microscopy. Similar to the phenomenon observed with GFP:NIa-ProTuMV, GFP:NIa-ProPVY also localized to the nucleus without aphids and to the vacuole with aphids present (Fig. 6c). Quantification of three independent experiments demonstrated that aphid presence significantly modifies GFP:NIa-ProPVY localization (Fig. 6d). This observation suggests NIa-Pro may have a conserved function for the genus Potyvirus, representing over 30% of all described plant viruses19.
NIa-Pro relocalization is insect dependent
We next wanted to determine whether GFP:NIa-Pro also relocalizes in the presence of others piercing-sucking insects, or whether it is specific to the aphid vector. To address this, we examined GFP:NIa-Pro relocalization in the presence of two distinct phloem-feeding insects: the beet leafhopper Circulifer tenellus and the silverleaf whitefly, Bemisa tabaci biotype A. Like aphids, whiteflies feed by moving their stylets intercellularly on the way to the phloem causing minimal cell damage. However, whiteflies generally make fewer intracellular probes before reaching the phloem and thus feeding is not equivalent to aphids35. Leafhoppers, on the other hand, have larger mouthparts compared with aphids and whiteflies. Because of this, leafhoppers generally damage many cells on their intracellular pathway to the phloem35. Some relocalization of GFP:NIa-Pro to the vacuole was observed in the presence of leafhoppers and whiteflies (Fig. 6e). However, the number of cells with GFP:NIa-Pro in the vacuole was significantly higher for aphid vectors compared with non-vector insects (aphids: ∼60% of cells; leafhoppers and whiteflies: ∼30% of cells; Fig. 6e). This suggests relocalization is not correlated with feeding damage, as whiteflies cause less damage and leafhoppers cause more damage during feeding as compared with aphids. Although previous studies have demonstrated that both whiteflies and leafhoppers can transmit viruses to N. benthamiana plants36,37, we next wanted to confirm insects were probing in our experiments. To address this, we collected the leaves that aphids, whiteflies and leafhoppers were confined to and stained them with acid fuchsin. Staining with acid fuchsin allowed us to visualize the saliva sheaths and verify plants were probed38 (Supplementary Fig. 5).
NIa-Pro relocalization is host dependent
Although numerous studies have shown viruses can manipulate plant metabolism and promote vector performance, there is wide variation in response both within and across plant species39. Previous studies have shown that NIa-Pro increases aphid performance on Arabidopsis thaliana in addition to N. benthamiana9,22, suggesting that this may be a general response across plants. To determine whether NIa-Pro also relocalizes in Arabidopsis in the presence of aphids, we generated transgenic plants expressing free GFP or GFP:NIa-Pro as previously described40. Consistent with the N. benthamiana experiments, after 24 h of aphids infestation GFP:NIa-Pro was observed in the vacuole, whereas for free GFP there was no relocalization (Fig. 7a).
Next, we examined insect performance on Nicotiana tabacum plants infected with TuMV, PVY or expressing the corresponding NIa-Pro. In contrast to N. benthamiana and Arabidopsis plants9,22, aphids were not more fecund on infected N. tabacum plants compared with controls (Fig. 7b). Furthermore, aphids did not have enhanced fecundity on N. tabacum plants expressing GFP:NIa-ProTuMV or GFP:NIa-ProPVY compared with the appropriate controls (Fig. 7b). We next conducted confocal microscopy experiments using transient expression in N. tabacum to determine whether GFP:NIa-Pro is still able to relocalize to the vacuole. In contrast to the other host plants, GFP:NIa-ProTuMV and GFP:NIa-ProPVY did not relocalize in N. tabacum with aphids present (Fig. 7c,d), further supporting the role of relocalization in increased aphid fecundity and changes in plant metabolism. A western blot demonstrated that the expression level was similar for free GFP, GFP:NIa-ProTuMV or GFP:NIa-ProPVY in N. tabacum and in N. benthamiana (Fig. 7e). These observations suggest NIa-Pro must respond to the presence of the vector using a host plant-derived signal.
Discussion
Our results demonstrate that TuMV initiates host changes in response to vector presence, promoting insect performance and the likelihood of transmission at the most opportune moment. We show that NIa-Pro from TuMV relocalizes to the vacuole in the presence of insect vectors on infected hosts (Figs 1c, 2, 3a,b and 5d–f). Further, we demonstrate that relocalization is essential for NIa-Pro’s ability to inhibit plant defenses and increase vector fecundity on host plants (Fig. 4e,f). The large number of cells observed with the relocalization phenotype suggests that NIa-Pro responds to a systemic signal that moves throughout the leaf from the cells the aphid come in contact with. Almost twice as much NIa-Pro relocalization was observed in the presence of aphid vectors as compared with non-vector insects (Fig. 6e). Because NIa-Pro relocalization did not correlate with insect damage (that is, whiteflies cause less damage and leafhoppers cause more damage compared with aphids; Fig. 6e), the systemic signal may be only partially due to the physical damage caused during insect probing. This suggests vector-specific factors may also contribute to the systemic signal recognized by NIa-Pro, such as salivary secretions, or other aphid-derived material. Our results also demonstrate that NIa-Pro from PVY, another potyvirus, has the same properties (Fig. 6), suggesting a conserved role for the protein in vector–host interactions. Finally, we demonstrate that the nature of the host is very important for relocalization of NIa-Pro and the impact of viral infection on host–vector interactions, shedding light on new aspects that may determine viral host range and epidemiology in nature.
Previous studies have reported that animal and plant viruses can alter host physiology and host–vector interactions in ways that are predictive of enhanced transmission9,22,41,42,43,44,45. Our results demonstrate viruses can alter host plant physiology in response to vector presence, promoting insect performance and transmission through host plant changes only when needed. The virus must ‘recognize’ the presence of the vector and respond actively through changes in host physiology, a phenomenon that has not been previously demonstrated for any animal or plant viruses to our knowledge. Recent evidence has demonstrated CaMV responds actively to its aphid vector through structural changes11,46. In these studies, aphid-induced changes in CaMV transmission morphs increased the likelihood of transmission by the insect vector11,46. Our findings are unique compared with previous studies with CaMV and viral ‘recognition’ of aphid vectors as CaMV proteins only responded in cells that were directly damaged by the aphids during the probing punctures11. Our study may also show a slightly different mechanism, where it is not the virus recognizing the vector and initiating host changes for enhanced transmission but possibly the aphid manipulating the viral protein to suppress aphid defenses. Although the exact mechanisms are still unknown, it may be a ‘perceptive insect behaviour’ instead of a ‘perceptive viral behaviour’.
Aphids move their needle-like mouthpart, the stylet, intercellularly to the phloem and puncture multiple cells before feeding (for review, see ref. 6). Because most plant cells have one large vacuole that occupies up to 90% of the cell volume, aphids may encounter vacuoles often during probing. The vacuole has numerous functions, including storage of metabolic products known to be involved in plant defence against microbial pathogens and herbivores47,48,49,50. Vacuolar localization of NIa-Pro during insect presence might be important for inhibition of aphid-induced plant signals or defenses known to be stored in the vacuole50,51. Previous studies have shown that NIa-Pro has protease activity52 and DNAse activity53,54. As a protease, NIa-Pro could degrade proteins in the vacuole directly involved in plant defence or known to activate other molecule in defence pathways. Recently, a study has shown that TuMV particles and HC-Pro, another TuMV protein, also accumulate in the vacuole34. HC-Pro is involved in aphid transmission, although the role of vacuolar localization in transmission remains unknown.
This is also the first evidence that NIa-Pro can localize into the nucleus without VPg. Previous studies have demonstrated that VPg encodes a NLS (Fig. 1a), mediating VPg-NIa-Pro accumulation in the nucleus, although its function in the nucleus remains unclear20,55. It was previously suggested that once NIa-Pro is liberated from NIa, it might diffuse into the cytoplasm, as it is only 27 kD (ref. 20). Here we demonstrate that VPg is not essential for nuclear localization. Interestingly, NIa-Pro does not have any known NLSs, suggesting an unknown signal exists or that it uses a different mechanism to move in and out of the nucleus.
Vector-borne pathogens account for >17% of all infectious diseases worldwide, contributing to reductions in agricultural productivity, disrupted ecosystem services and over 1 million deaths each year56. Viral pathogens specifically are the aetiologic agents of 5 of the 10 most important vector-borne diseases worldwide, in terms of impact on mortality56. Surprisingly, very few studies using animal or plant viruses have examined the impact of viruses in combination with their vectors on hosts. The phenomenon described here not only opens up new areas of research for plant virology but also poses new questions for vector-borne viruses of humans and other animals. For example, mosquito vectors preferentially feed on hens infected with an arbovirus compared with control hens42 and lambs infected with Rift Valley fever virus are fed on more frequently by the mosquito vectors compared with uninfected animals43. These studies suggest host traits that influence transmission dynamics also change in animals systems after infection, but the mechanisms mediating these changes remain unknown. These studies and ours are contributing to a rapidly changing image of virus transmission and in particular the host–virus–vector relationship, which is more complex than expected.
Methods
Plants and growth conditions
Nicotiana benthamiana and Arabidopsis seeds were originally obtained from Georg Jander (Boyce Thompson Institute, Ithaca, NY). Nicotiana tabacum cv. Glurck were obtained from Bryce Falk (University of California, Davis, CA). Plants were grown in growth chambers under controlled conditions (25/20 °C day/night with a photoperiod of 12/12 h day/night).
Aphids
Non-viruliferous aphid clones of a tobacco-adapted red strain of Myzus persicae were reared under controlled conditions (25/20 °C day/night with a photoperiod of 12/12 h day/night) on N. tabacum. Aphids were originally obtained from Georg Jander (Boyce Thompson Institute, Ithaca, NY).
Virus infection
TuMV/GFP was propagated from the infectious clone p35:TuMV/GFP53 by agroinfiltration as described in the ‘Protein expression in Nicotiana spp’ section below. PVY-O was obtained from Stewart Gray at Cornell University, Ithaca, NY57 and propagated by rub-inoculation. To prepare inoculum, fully infected N. benthamiana leaves were collected 3 weeks after inoculation and weighed. Leaves were then ground in two volumes 20 mM phosphate buffer (pH 7.2). For experiments, two leaves per plant were dusted with carborundum (Sigma-Aldrich, St Louis, MO) and rub-inoculated with the virus sap using a cotton-stick applicator. A corresponding set of control plants were dusted with carborundum and mock-inoculated with a cotton-stick applicator that was soaked in uninfected N. benthamiana sap in 20 mM phosphate buffer.
Aphid fecundity
One apterous adult aphid was placed on the underside of a fully infected or agroinfiltrated N. benthamiana leaf and confined in a plastic clip cage (2 cm diameter). After 24 h, all aphids except one nymph were removed. After 7–9 days, depending on the experiment, the progeny of this single nymph were counted to determine fecundity.
Plasmid constructs
The constructs were produced using the Gateway cloning kit (Invitrogen, Carlsbad, CA, USA, http://www.lifetechnologies.com) following the manufacturers instructions. In brief, PCR products were amplified using gene-specific primers for each construct flanked by the attB1 and attB2 universal primers (Supplementary Table 1). The PCR products were cloned into the pDONR207 vector using BP clonase and then they were re-cloned into the pSITE:GFP destination vector58,59 or the pTA7001destination vector40, using LR clonase. To construct the localization mutants, the NLS from SV40 (PKKKRKV) and the consensus NES (NELALKLAGLDINK) sequence were added in the primers31,32.
The TuMV/GFP:NIa-Pro construct was created by amplifying a PCR product with pSITE:GFP:NIa-Pro as the template using oligonucleotides containing a SacII restriction site (SacII-eGFP-F and NIa-Pro-SacII-R; Supplementary Table 1). The PCR product was digested with the SacII restriction endonuclease and inserted into the corresponding restriction endonuclease site in TuMV/6K2:GFP after removal of 6K2:GFP and dephosphorylation33,60.
Protein expression in Nicotiana spp
Constructs containing the coding sequence for the proteins fused to gfp were introduced into Agrobacterium tumefaciens GV3101 by heat shock and selected on LB plus 10 μg ml−1 of rifampicin and 50 μg ml−1 of spectinomycin for the pSITE plasmid or plus 10 μg ml−1 of rifampicin and 50 μg ml−1 of kanamycin for pCAMBIA and spRFP:AFVY. One fresh colony was selected and grown overnight in liquid culture. The pellet of the culture was resuspended in 10 mM MES pH 5.85; 10 mM MgCl2 and 150 μM acetosyringone and left at room temperature for 2 h. The solution was then diluted to an optical density of 0.1 at 600 nm for transient expression experiments and at 0.3 for the infectious clones. Single leaves from 3-week-old N. benthamiana or N. tabacum plants were then agroinfiltrated with the solution. For N. benthamiana, entire leaves were infiltrated. For N. tabacum, a circle of ∼5 cm diameter was infiltrated for each leaf. Plants were used in experiments 2 days after infiltration. Expression was verified by microscopy, PCR and/or western blot as previously described9.
Transgenic Arabidopsis
The coding sequence from GFP or GFP:NIa-Pro was inserted into pTA7001 plasmid, containing the glucocorticoid-inducible system40 as described above. Wild-type Columbia (Col-0) Arabidopsis plants were transformed using the floral dip method as previously described61. The seeds were then plated on MS plate plus 20 μg ml−1 of hygromycin. Resistant seedlings were selected after 2 weeks and moved to pots with soil. One month later, the plants were sprayed with 3 μM of dexamethasone and 24 h after plants were used in microscopy experiments with and without aphids.
Insect presence experiments
Approximately 50 aphids, 100 whiteflies or 50 leafhoppers were confined in a plastic clip cage with a 2 cm diameter and allowed to feed for 2, 6 or 24 h on the underside of a N. benthamiana or N. tabacum leaf, 2 days post agroinfiltration. The number of insects used for each species was selected to completely cover the surface of the leaf exposed in each cage. A plastic clip cage without insects was used as a control in all experiments. At least one leaf from two different plants was used for each treatment in each experiment and each experiment was repeated three times.
Stains
Two days after infiltration or immediately after aphid treatment, leaves were cut into small pieces and emerged in 10 μg ml−1 of DAPI to stain the nucleus (Sigma-Aldrich, St. Louis, MO) or with 10 μM of SNARF-1 (Invitrogen, Carlsbad, CA, USA, http://www.lifetechnologies.com) to stain the vacuole for 2 h at room temperature.
Salivary sheath staining
Insects were caged to N. benthamiana leaves as described above. After 24 h, insects were removed and leaves were cleared in 70% ethanol for at least 48 h. Following clearing, leaves were soaked in an acid fuchsin solution (0.035% in acetic acid:water, 1:3 V) for 2 min at room temperature38 and then immediately rinsed with water. Next leaves were mounted on a glass slide in 50% glycerol and analysed directly using a light microscope.
Microscopy
Leaves were cut into small pieces and placed on glass slides with a drop of perfluorodecalin (Sigma-Aldrich, St Louis, MO) and observed with a Leica TCS SP5 confocal laser scanning microscope system (Leica Micro- systems, Bannockburn, IL, USA). GFP fluorescence was detected with excitation at 488 nm and emission capture at 500–530 nm. The DAPI was excited with a 405 nm laser, and emission was collected from 405–500 nm. SNARF-1 was excited at 514 nm and emission was collected from 600–700 nm. spRFP:AFVY was excited at 532 nm and emission was collected from 550–700 nm. Images were captured at 2,361 μm intervals using a × 20 objective Final figures were prepared using ImageJ software (imagej.nih.gov/ij/).
NIa-Pro localization quantification
Five microscopy fields were randomly selected for each leaf and visualized. For each field, the number of cells showing GFP inside the nucleus or inside the vacuole was quantified. Two leaves from separate plants were examined for each treatment and three independent experiments were conducted.
Vacuole purification
The vacuole isolation was performed as previously described32. Briefly, N. benthamiana leaves agroinfiltrated with TuMV/GFP:NIa-Pro or the empty vector were sliced into 1 mm stripes with a razor blade. The cut leaves were then placed in protoplastation solution (0.4 M mannitol, 20 mM Mes, pH 5.7. 20 mM KCl, 1.5% (w/v) Cellulase R-10, 0.2% (w/v) Macerozyme R-10, 0.1% (w/v) BSA, 10 mM CaCl2). Vacuum was applied for 20 min followed by dark incubation for 3.5 h at room temperature. The protoplasts were then filtered with a miracloth filter, and centrifuged at 80g for 5 min. Protoplasts were washed two times in washing buffer (0.4 M mannitol, 20 mM Mes, pH 5.7), and then resuspended in 10 ml of prewarmed (37 °C) lysis buffer (0.2 M mannitol, 10% (w/v) Ficoll, 10 mM EDTA, pH 8.0, 5 mM sodium phosphate, pH 8.0). After 5 min of incubation, 5 ml of the solution was overlayed with 3 ml 4% (w/v) Ficoll solution and 1 ml ice-cold vacuole buffer (0.2 M mannitol, 2 mM EDTA, pH 8.0, 5 mM sodium phosphate, pH 7.5). The gradient was centrifuged at 1,500g for 20 min at 10 °C, and the vacuoles were collected from the interface between 0 and 4% Ficoll. The purity and quality of the protoplast isolations and of vacuole isolations were accessed using light microscopy (Supplementary Fig. 6).
Western blotting
Two days post agroinfiltration, the leaves were crushed in a lysis buffer (50 mM Tris pH 7.5, 300 mM NaCl, 1 mM PMSF, 1% Cocktail antiprotease) and then boiled in Laemmeli buffer62. The plant extract was then centrifuged for 5 min at 8,000g. The supernatant was fractionated by a 12% SDS–polyacrylamide gel electrophoresis gel under reducing conditions and transferred to a nitrocellulose membrane using a transfer apparatus according to the manufacturer’s protocols (Bio-Rad, Hercules, CA). After incubation with 5% nonfat milk in PBST (137 mM NaCl, 2.7 mM KCl, 8 mM Na2HPO4, 2 mM KH2PO4, 0.3% Tween 20) for 30 min, the membrane was incubated with an antibody against GFP (1:2,000 dilution) for 2 h at room temperature. The GFP antibody was already conjugated to the horseradish peroxidase (Anti-GFP-HRP, http://www.miltenyibiotec.com, #130-091-833). For a loading control, the membrane was also incubated with an antibody specific to the coat protein of TuMV (provided by J-F Laliberté) (1:1,000 dilution) for 2 h at room temperature and then with a horseradish peroxidase-conjugated goat anti-rabbit antibody (Bio-Rad, #1706515, 1:10,000). Blots were washed with PBST three times for 10 min each and developed with an enhanced chemiluminescence system according to the manufacturer (Bio-Rad, Hercules, CA). All uncropped gel/blot images are available in Supplementary Figs 7 and 8.
Statistical analysis
The statistical analyses were performed using JMP 8 software (SAS Institute, Cary, NC, USA) and data were analysed by Student’s t-tests or analysis of variance followed by a Tukey’s honest significant difference post hoc test. All experiments were repeated at least three times. For fecundity, each experiment had at least 12 experimental units per repetition depending of the experiment. For localization experiments, at least two plants were used for each treatment and three repetitions were performed.
Data availability
The authors declare that all data supporting the findings of this study are available in the manuscript and its Supplementary Information files or are available from the corresponding author upon request.
Additional information
How to cite this article: Bak, A. et al. A viral protease relocalizes in the presence of the vector to promote vector performance. Nat. Commun. 8, 14493 doi: 10.1038/ncomms14493 (2017).
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
References
Hogenhout, S. A., Ammar, E. D., Whitfield, A. E. & Redinbaugh, M. G. Insect vector interactions with persistently transmitted viruses. Annu. Rev. Phytopathol. 46, 327–359 (2008).
Granier, F., Durand-Tardif, M., Casse-Delbart, F., Lecoq, H. & Robaglia, C. Mutations in zucchini yellow mosaic virus helper component protein associated with loss of aphid transmissibility. J. Gen. Virol. 74, 2737–2742 (1993).
Huet, H., Gal-On, A., Meir, E., Lecoq, H. & Raccah, B. Mutations in the helper component protease gene of zucchini yellow mosaic virus affect its ability to mediate aphid transmissibility. J. Gen. Virol. 75, 1407–1414 (1994).
Brault, V., Uzest, M., Monsion, B., Jacquot, E. & Blanc, S. Aphids as transport devices for plant viruses. C. R. Biol. 333, 524–538 (2010).
Stout, M. J., Thaler, J. S. & Thomma, B. P. Plant-mediated interactions between pathogenic microorganisms and herbivorous arthropods. Annu. Rev. Entomol. 51, 663–689 (2006).
Fereres, A. & Moreno, A. Behavioural aspects influencing plant virus transmission by homopteran insects. Virus Res. 141, 158–168 (2009).
Ziebell, H. et al. Cucumber mosaic virus and its 2b RNA silencing suppressor modify plant-aphid interactions in tobacco. Sci. Rep. 1, 187 (2011).
Casteel, C. L. & Jander, G. New synthesis: investigating mutualisms in virus-vector interactions. J. Chem. Ecol. 39, 809 (2013).
Casteel, C. L. et al. The NIa-Pro protein of Turnip mosaic virus improves growth and reproduction of the aphid vector, Myzus persicae (green peach aphid). Plant J. 77, 653–663 (2014).
Su, Q. et al. Manipulation of host quality and defense by a plant virus improves performance of whitefly vectors. J. Econ. Entomol. 108, 11–19 (2015).
Martinière, A. et al. A virus responds instantly to the presence of the vector on the host and forms transmission morphs. eLife 2, e00183 (2013).
Tomlinson, J. A. Epidemiology and control of virus diseases of vegetables. Ann. Appl. Biol. 110, 661–681 (1987).
Nguyen, H. D. et al. Turnip mosaic potyvirus probably first spread to Eurasian brassica crops from wild orchids about 1000 years ago. PLoS ONE 8, e55336 (2013).
Yasaka, R. et al. Phylodynamic evidence of the migration of turnip mosaic potyvirus from Europe to Australia and New Zealand. J. Gen. Virol. 96, 701–713 (2015).
Walsh, J. A. & Jenner, C. E. Turnip mosaic virus and the quest for durable resistance. Mol. Plant Pathol. 3, 289–300 (2002).
Shattuck, V. I. The biology, epidemiology, and control of turnip mosaic virus. Horticult. Rev. 14, 199–238 (1992).
Urcuqui-Inchima, S., Haenni, A. L. & Bernardi, F. Potyvirus proteins: a wealth of functions. Virus Res. 74, 157–175 (2001).
Chung, B. W., Miller, W. A., Atkins, J. F. & Firth, A. E. An overlapping essential gene in the Potyviridae. Proc. Natl Acad. Sci. USA 105, 5897–5902 (2008).
Revers, F. & Garcia, J. A. Molecular biology of potyviruses. Adv. Virus Res. 92, 101–199 (2015).
Carrington, J. C., Haldeman, R., Dolja, V. V. & Restrepo-Hartwig, M. A. Internal cleavage and trans-proteolytic activities of the VPg-proteinase (NIa) of tobacco etch potyvirus in vivo. J. Virol. 67, 6995–7000 (1993).
Carrington, J. C. & Dougherty, W. G. Small nuclear inclusion protein encoded by a plant potyvirus genome is a protease. J. Virol. 61, 2540–2548 (1987).
Casteel, C. L. et al. Disruption of ethylene responses by Turnip mosaic virus mediates suppression of plant defense against the aphid vector. Plant Physiol. 169, 209–218 (2015).
Ohshima, K. Plant potyvirus evolution: the survey of the genetic structure of populations. Uirusu 62, 151–160 (2012).
Kapuscinski, J. DAPI: a DNA-specific fluorescent probe. Biotech. Histochem. 70, 220–233 (1995).
Foresti, O. et al. A recycling-defective vacuolar sorting receptor reveals an intermediate compartment situated between prevacuoles and vacuoles in tobacco. Plant Cell 22, 3992–4008 (2010).
Viotti, C. et al. The endoplasmic reticulum is the main membrane source for biogenesis of the lytic vacuole in Arabidopsis. Plant Cell 25, 3434–3449 (2013).
Hunter, P. R. et al. Fluorescent reporter proteins for the tonoplast and the vacuolar lumen identify a single vacuolar compartment in Arabidopsis cells. Plant Physiol. 145, 1371–1382 (2007).
Mitsuhashi, N., Shimada, T., Mano, S., Nishimura, M. & Hara-Nishimura, I. Characterization of organelles in the vacuolar-sorting pathway by visualization with GFP in tobacco BY-2 cells. Plant Cell Physiol. 41, 993–1001 (2000).
Di Sansebastiano, G. P., Paris, N., Marc-Martin, S. & Neuhaus, J. M. Regeneration of a lytic central vacuole and of neutral peripheral vacuoles can be visualized by green fluorescent proteins targeted to either type of vacuoles. Plant Physiol. 126, 78–86 (2001).
Seibel, N. M., Eljouni, J., Nalaskowski, M. M. & Hampe, W. Nuclear localization of enhanced green fluorescent protein homomultimers. Anal. Biochem. 368, 95–99 (2007).
Liu, J. Z. & Whitham, S. A. Overexpression of a soybean nuclear localized type–III DnaJ domain-containing HSP40 reveals its roles in cell death and disease resistance. Plant J. 74, 110–121 (2013).
Xu, T., Johnson, C. A., Gestwicki, J. E. & Kumar, A. Conditionally controlling nuclear trafficking in yeast by chemical-induced protein dimerization. Nat. Protoc. 5, 1831–1843 (2010).
Thivierge, K. et al. Eukaryotic elongation factor 1A interacts with Turnip mosaic virus RNA-dependent RNA polymerase and VPg-Pro in virus-induced vesicles. Virology 377, 216–225 (2008).
Wan, J. et al. Ultrastructural characterization of Turnip mosaic virus induced cellular rearrangements reveal membrane-bound viral particles accumulating in vacuoles. J. Virol. 10, 2138–2150 (2015).
Stafford, C. A., Walker, G. P. & Ullman, D. E. Hitching a ride: Vector feeding and virus transmission. Commun. Integr. Biol. 5, 43–49 (2012).
Briddon, R. W., Pinner, M. S., Stanley, J. & Markham, P. G. Geminivirus coat protein gene replacement alters insect specificity. Virology 177, 85–94 (1990).
Khan, J. A. & Ahmad, J. Diagnosis, monitoring and transmission characteristics of Cotton leaf curl virus. Curr. Sci. 88, 1803–1809 (2005).
Jaouannet, M., Morris, J. A., Hedley, P. E. & Bos, J. I. B. Characterization of Arabidopsis transcriptional responses to different aphid species reveals genes that contribute to host susceptibility and non-host resistance. PLoS Pathog. 11, e1004918 (2015).
Mauck, K., Bosque-Pérez, N. A., Eigenbrode, S. D., De Moraes, C. M. & Mescher, M. C. Transmission mechanisms shape pathogen effects on host–vector interactions: Evidence from plant viruses. Funct. Ecol. 26, 1162–1175 (2012).
Aoyama, T. & Chua, N. H. A glucocorticoid-mediated transcriptional induction system in transgenic plants. Plant J. 11, 605–612 (1997).
Moshkin, M., Gerlinskaya, L., Morozova, O., Bakhvalova, V. & Evsikov, V. Behaviour, chemosignals and endocrine functions in male mice infected with tick-borne encephalitis virus. Psychoneuroendocrinology 27, 603–608 (2002).
Mahon, R. & Gibbs, A. in Viral Diseases in Southeast Asia and the western Pacific (ed. Mackenzie, J. D.) 502–504 (Academic Press, 1982).
Turell, M. J., Bailey, C. L. & Rossi, C. A. Increased mosquito feeding on Rift Valley fever virus-infected lambs. Am. J. Trop Med. Hyg. 33, 1232–1238 (1984).
Mauck, K. E., De Moraes, C. M. & Mescher, M. C. Deceptive chemical signals induced by a plant virus attract insect vectors to inferior hosts. Proc. Natl Acad. Sci. USA 107, 3600–3605 (2010).
Mauck, K. E., De Moraes, C. M. & Mescher, M. C. Biochemical and physiological mechanisms underlying effects of Cucumber mosaic virus on host-plant traits that mediate transmission by aphid vectors. Plant Cell Environ. 37, 1427–1439 (2014).
Bak, A. et al. Virus factories of Cauliflower mosaic virus are virion reservoirs that engage actively in vector transmission. J. Virol. 87, 12207–12215 (2013).
Hatsugai, N. & Hara-Nishimura, I. Two vacuole-mediated defense strategies in plants. Plant Signal Behav. 5, 1568–1570 (2010).
Iglesias, V. A. & Meins, F. Jr Movement of plant viruses is delayed in a beta-1,3-glucanase-deficient mutant showing a reduced plasmodesmatal size exclusion limit and enhanced callose deposition. Plant J. 21, 157–166 (2000).
Grob, K. & Matile, P. H. Vacuolar location of glucosinolates in horseradish root cells. Plant Sci. Lett. 14, 327–335 (1979).
Shumway, L. K., Yang, V. V. & Ryan, C. A. Evidence for the presence of proteinase inhibitor I in vacuolar protein bodies of plant cells. Planta 129, 161–165 (1976).
Fürstenberg-Hägg, J., Zagrobelny, M. & Bak, S. Plant defense against insect herbivores. Int. J. Mol. Sci. 14, 10242–10297 (2013).
Hwang, D. C., Kim, D. H., Kang, B. H., Song, B. D. & Choi, K. Y. Molecular cloning, expression, and purification of Nuclear Inclusion A protease from tobacco vein mottling virus. Mol. Cells 10, 148–155 (2000).
Lellis, A. D., Kasschau, K. D., Whitham, S. A. & Carrington, J. C. Loss-of-susceptibility mutants of Arabidopsis thaliana reveal an essential role for eIF(iso)4E during potyvirus infection. Curr. Biol. 12, 1046–1051 (2002).
Anindya, R. & Savithri, H. S. Potyviral NIa proteinase, a proteinase with novel deoxyribonuclease activity. J. Biol. Chem. 279, 32159–32169 (2004).
Hajimorad, M. et al. NIa and NIb of peanut stripe potyvirus are present in the nucleus of infected cells, but do not form inclusions. Virology 224, 368–379 (1996).
World Health Organization. Vector-borne diseases. Available at http://www.who.int/mediacentre/factsheets/fs387/en/ (2016).
Kersch-Becker, M. F. & Thaler, J. S. Virus strains differentially induce plant susceptibility to aphid vectors and chewing herbivores. Oecologia 174, 883–892 (2013).
Martin, K. et al. Transient expression in Nicotiana benthamiana fluorescent marker lines provides enhanced definition of protein localization, movement and interactions in planta. Plant J. 59, 150–162 (2009).
Curtis, M. D. & Grossniklaus, U. A gateway cloning vector set for high-throughput functional analysis of genes in planta. Plant Physiol. 133, 462–469 (2003).
Cotton, S. et al. Turnip mosaic virus RNA replication complex vesicles are mobile, align with microfilaments, and are each derived from a single viral genome. J. Virol. 83, 10460–10471 (2009).
Clough, S. J. & Bent, A. F. Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. Plant J. 16, 735–743 (1998).
Laemmli, U. K. Cleavage of structural proteins during assembly of head of bacteriophage-T4. Nature 227, 680–685 (1970).
Acknowledgements
We thank Georgia Drakakaki for advice on vacuole localization experiments and use of the SNARF-1 dye from her lab. We thank Jean-François Laliberté for providing the original pCambia/TuMV/6k2:GFP construct from his publications and for the TuMV-CP antibody. We thank Lorenzo Frigerio for the spRFP:AFVY construct. We thank Bob Gilbertson for providing beet leafhoppers and Bryce Falk for providing whiteflies. This publication was supported by the United States Department of Agriculture award 2015-04607 and University of California start-up funds to C.L.C., and by a grant from the US National Science Foundation, IOS-1121788 to S.A.W.
Author information
Authors and Affiliations
Contributions
C.L.C. conceived the project. A.B. and C.L.C. designed the research. A.B., A.C., C.Y. and C.L.C. performed research. A.B., A.C. and C.L.C. analysed the data. C.Y. and S.A.W. provided input on experimental design. A.B. and C.L.C. wrote the article with contributions of all the authors.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Supplementary information
Supplementary Information
Supplementary Figures and Supplementary Tables (PDF 9057 kb)
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Bak, A., Cheung, A., Yang, C. et al. A viral protease relocalizes in the presence of the vector to promote vector performance. Nat Commun 8, 14493 (2017). https://doi.org/10.1038/ncomms14493
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/ncomms14493
This article is cited by
-
Endosymbionts modulate virus effects on aphid-plant interactions
The ISME Journal (2023)
-
Molecular basis of methyl-salicylate-mediated plant airborne defence
Nature (2023)
-
Versatility in acyltransferase activity completes chicoric acid biosynthesis in purple coneflower
Nature Communications (2021)
-
Mixed infection of plant viruses: diagnostics, interactions and impact on host
Journal of Plant Diseases and Protection (2021)
-
The Oxylipin Signaling Pathway Is Required for Increased Aphid Attraction and Retention on Virus-Infected Plants
Journal of Chemical Ecology (2020)
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.