Pseudomonas oleovorans Strain KBPF-004 Culture Supernatants Reduced Seed Transmission of Cucumber green mottle mosaic virus and Pepper mild mottle virus, and Remodeled Aggregation of 126 kDa and Subcellular Localization of Movement Protein of Pepper mild mottle virus

Article information

Plant Pathol J. 2017;33(4):393-401
Publication date (electronic) : 2017 August 01
doi : https://doi.org/10.5423/PPJ.OA.03.2017.0047
1Central Research Institute, Kyung Nong Co., Ltd., Gyeongju 38175, Korea
2Department of Applied Biology, College of Agriculture and Life Sciences, Chungnam National University, Daejeon 34134, Korea
3Department of Crop Sciences, University of Illinois at Urbana-Champaign, United States Department of Agriculture- Agricultural Research Service (USDA-ARS), Urbana, IL 61801, USA
4Floral and Nursery Plants Research Unit, United States National Arboretum, United States Department of Agriculture- Agricultural Research Service (USDA-ARS), Beltsville, MD 20705, USA
*Co-corresponding authors. HS Lim, Phone) +82-42-821-5766, FAX) +82-42-823-8679, E-mail) hyounlim@cnu.ac.kr. J Hammond, Phone) +1-301-504-5313, FAX) +1-301-504-5096, E-mail) John.Hammond@ars.usda.gov
Handling Associate Editor : Ju, Ho-Jong†These authors contributed equally to this study as first authors.
Received 2017 March 06; Accepted 2017 April 13.

Abstract

Efforts to control viral diseases in crop production include several types of physical or chemical treatments; antiviral extracts of a number of plants have also been examined to inhibit plant viral infection. However, treatments utilizing naturally selected microorganisms with activity against plant viruses are poorly documented. Here we report isolation of a soil inhabiting bacterium, Pseudomonas oleovorans strain KBPF-004 (developmental code KNF2016) which showed antiviral activity against mechanical transmission of tobamoviruses. Antiviral activity was also evaluated in seed transmission of two tobamoviruses, Pepper mild mottle virus (PMMoV) and Cucumber green mottle mosaic virus (CGMMV), by treatment of seed collected from infected pepper and watermelon, respectively. Pepper and watermelon seeds were treated with culture supernatant of P. oleovorans strain KBPF-004 or control strain ATCC 8062 before planting. Seeds germinated after treatment with water or ATCC 8062 yielded about 60% CGMMV or PMMoV positive plants, whereas < 20% of KBPF-004-treated seeds were virus-infected, a significantly reduced seed transmission rate. Furthermore, supernatant of P. oleovorans strain KBPF-004 remodeled aggregation of PMMoV 126 kDa protein and subcellular localization of movement protein in Nicotiana benthamiana, diminishing aggregation of the 126 kDa protein and essentially abolishing association of the movement protein with the microtubule network. In leaves agroinfiltrated with constructs expressing the coat protein (CP) of either PMMoV or CGMMV, less full-size CP was detected in the presence of supernatant of P. oleovorans strain KBPF-004. These changes may contribute to the antiviral effects of P. oleovorans strain KBPF-004.

Introduction

Yield loss and low quality products of watermelon were reported in Korea in 2015, and the cause was usually the seed-transmitted virus Cucumber green mottle mosaic virus (CGMMV, genus Tobamovirus, family Virgaviridae), and which is a major viral cause of yield loss in cucurbits. CGMMV is not only the major seed-transmitted virus in watermelon (Citrullus lanatus) but also in cucumber (Cucumis sativus) and squash (Cucurbita moschata) (Lovisolo, 1979). CGMMV transmission is mainly by direct mechanical contact through contaminated soil, propagation stock materials and seeds (Choi, 2001; Hollings et al., 1975; Wu et al., 2011).

Many plant viruses are known to be seed-transmitted, and many tobamovirus infections result from transmission through seed. Seed transmission occurs either inside the embryo, or by external contamination of the seed coat (non-embryonic seed transmission). Embryonic seed-transmitted viruses are able to infect the embryo directly from maternal tissue, or through infected pollen (Liu et al., 2014). Embryonic seed transmission infects the newly germinated seedling and most seed-transmitted viruses have been identified as embryo-infecting. Meanwhile non-embryonically-transmitted viruses are unable to invade the embryo, and are found on the surface of seeds or spread through the seed coat as a contaminant, but are able to be transmitted mechanically to the developing seedling. Viruses that undergo strictly non-embryonic seed transmission are carried on the surface of seeds or as contaminants in seed lots and are not detected in the embryo. In general, members of the genus Tobamovirus have been shown to be seed transmitted in a non-embryonic way (Agarwal and Sinclair, 1996; Hull, 2002), although CGMMV has been shown to also internalize to the seed (Reingold et al., 2015).

Another tobamovirus, Pepper mild mottle virus (PMMoV) is also reported to result in yield loss caused by seed transmission (Wetter and Conti, 1988). As with other members of the genus Tobamovirus, CGMMV and PMMoV have a single-stranded, positive-sense RNA genome encapsidated in rigid rod-shaped particles by a single type of coat protein (CP) (Adams et al., 2009). The genomic RNA contains a 5′ cap and a tRNA-like structure in the 3′ untranslated region, and encodes four polypeptides. The tobamovirus 128 kDa protein and read-through 183 kDa RNA-dependent RNA polymerase proteins translated from the genomic RNA are used for viral replication (Derrick et al., 1997), whereas the 30 kDa cell-to-cell movement protein (MP) and the 17 kDa CP are translated from 3′ co-terminal subgenomic RNAs (Takamatsu et al., 1987).

Many efforts have been applied for reduction or elimination of seed transmission. Either trisodium phosphate or dry heat can be used to reduce seed transmission of PMMoV and other tobamoviruses in Capsicum spp. The disadvantage of chemical treatment is that it is not sufficiently effective to sterilize the virus from infected seeds. Either type of treatment has the risk of reducing seed viability or longevity (Demski, 1981; Nagai, 1981; Rast and Stijger, 1987).

Therefore, new advances in seed processing are required to overcome these disadvantages in order to produce high-quality seeds. The effects of extracts of some plants as inhibitors of plant virus infection have long been known (Duggar and Armstrong, 1925; Jones et al., 1959; Kassanis and Kleczkowski, 1948; Verma et al., 1969), with at least some of the active factors, such as pokeweed antiviral protein, known to be ribosome-inactivating proteins (Endo et al., 1988). Several micro-organisms have also long been recognized to produce inhibitors of plant viruses, including Aerobacter aerogenes and Aspergillus niger (Johnson, 1938), and extracts of multiple fungal species tested by Gupta and Price (1950), including filtrates of Trichothecium roseum and Neurospora sitophila. At least two compounds were identified from T. roseum, of which one is a complex ester known as trichothecin, and another a polysaccharide containing a high proportion of galactose (Bawden and Freeman, 1952). Occasionally researchers have tried to apply biological treatments to reduce virus concentration on the seeds. Few methods have been reported to treat seed and protect plants from viruses, such as use of Acinetobacter strain KNF2022T isolated from tobacco plant roots, which showed inhibitory effects on Tobacco mosaic virus (TMV) (Lee et al., 2009), and Enterobacter asburiae, which induced resistance to Tomato yellow leaf curl virus (TYLCV) through plant growth promoting rhizobacteria (Li et al., 2016). Whereas seed treatment with some botanical extracts had some inhibitory effects on reducing tobamovirus concentration in mechanically-inoculated pepper and tomato seedlings, apparently resulting from induced resistance (Madhusudhan et al., 2011), no effects on seed transmission of the viruses was reported. However, previous reports lacked information on the mechanism(s) to inhibit virus using these biological control methods. In this research we investigated potential interactions between a soil-borne bacteria-produced product and viral proteins to control viral disease using the seed-transmitted tobamoviruses CGMMV and PMMoV.

Materials and Methods

Screening of antiviral bacteria

We screened for bacteria from the rhizosphere of tobacco (Nicotiana tabacum) on Mueller-Hinton agar (MHA; Difco, Detroit, MI, USA) media, at Daejeon, Republic of Korea. More than 1,000 colonies of bacteria were isolated based on colony appearance, and grown on MHA media for 24 h at 30°C for further analyses. The culture filtrate of isolates used for antiviral activity screening were prepared by growth in Mueller-Hinton broth (MHB; Difco) for 2 day at 30°C on a shaking incubator (180 rpm). The culture broth was centrifuged at 10,000g × for 30 min to remove bacterial cell and culture debris. N. tabacum cv. Xanthi-nc was used for local lesion assay of TMV infection in the greenhouse. For the virus inoculum, leaves (0.1 g) of N. tabacum cv. NC82, systemically infected with TMV, were ground in 20 ml of potassium phosphate buffer (0.02 M, pH 7.3). The sap was filtered through two layers of cheesecloth, and the extract then centrifuged at 3,000 rpm for 15 min to remove debris; the supernatant was used as TMV inoculum. Antiviral activity in the local lesion host was tested by using the half-leaf method (Choi and Lee, 1995; Fukami et al., 1981). The 20-fold dilutions of culture filtrates were applied with cotton swabs to the upper surface of one half leaf, while Mueller Hinton broth was applied on the remaining leaf half as control. The virus was inoculated 24 h after application of the culture filtrate by using ordinary carborundum (600 mesh) methods, with five half leaves inoculated per treatment. The symptoms on the inoculated plants was observed at 3 to 4 days after the inoculation, and the effects of the treatment were measured by comparing the number of local lesions on the treated and untreated (control) leaf halves. Antiviral activity was assayed using three tobacco plants per strain. The antiviral activity was described as mean ± SE. All data obtained from the repeated experiments in each test were expressed as means ± standard deviation. Differences were statistically evaluated using R package (3.3.2). One-way ANOVA followed by a Duncan’s multiple range test was applied for multiple comparisons.

Identification of the selected bacterial strain

The bacterial morphology was observed by scanning electron microscopy (HITACHI S4300N; Hitachi, Tokyo, Japan) and transmission electron microscopy (Philips CM20; Philips, Amsterdam, Netherlands). Cultural and physiological characteristics of the bacterial isolate were examined by the usual methods for its classification (Schaad et al., 2001). Carbon source assimilation was examined using the Biolog GN test kit (Biolog Inc., Hayward, CA, USA) according to manufacturer’s specifications. The genomic DNA for 16S rRNA gene sequencing and phylogenetic analyses were extracted and purified according to the method of Sambrook and Russell (2001). The 16S rRNA gene was amplified by PCR using two universal primers, 27F (5′-AGAGTTTGATCMTGGCTCAG-3′) and 1492R (5′-GGTTACCTTGTTACGACTT-3′) (Weisburg et al., 1991). The purified gene fragment was sequenced using a BigDye Terminator Cycle Sequencing Ready Reaction Kit (Applied Biosystems, Foster City, CA, USA) and examined using an automated DNA analyzer (Applied Biosystems 3730xl DNA Analyzer; Applied Biosystems). The sequence obtained was compared with available 16S rRNA gene sequences from GenBank (http://www.ncbi.nlm.nih.gov/blast/) and EzTaxon (http://www.eztaxon.org/) (Kim et al., 2012). Phylogenetic analyses were performed using the MEGA6 (Tamura et al., 2013) with three algorithms, the neighbor-joining (Saitou and Nei, 1987), maximum-likelihood (Felsenstein, 1993) and maximum- parsimony (Fitch, 1971) methods. Bootstrap values were calculated based on 1,000 replicates (Felsenstein, 1985).

Comparison to type strain

The type strain of Pseudomonas oleovorans, ATCC 8062, was obtained from Korean Collection for Type Cultures (KCTC) in order to compare antiviral activity with the selected strain.

Origin and maintenance of virus strains

The virus strains of PMMoV and CGMMV used to test for anti-viral effects of bacterial culture extracts were collected from soils of fields used for growing pepper or watermelon in areas of Jeollanam-do province where these viruses were detected. PMMoV and CGMMV were propagated separately by mechanical transmission to N. benthamiana. In addition, in vitro transcripts of infectious clones of PMMoV (Han et al., 2017) and CGMMV (Park et al., 2017) were used to infect seedlings of pepper and watermelon, respectively, in order to obtain infected seeds for further testing.

Determination of seed transmission rate after treatment of pepper and watermelon seeds from infected plants with strain KBPF-004 culture supernatants

To compare seed transmission in P. oleovorans strain KBPF-004 supernatant-treated and non-treated PMMoV-and CGMMV-infected seeds, we used virus infected seeds harvested from infected pepper and watermelon, respectively. To obtain virus infected seed, infectious clones of PMMoV (Han et al., 2017; J-76 KX399389) and CGMMV (Park et al., 2017; OMpj KX443592) were used. In vitro transcripts of each infectious clone were inoculated to seedlings of pepper and watermelon respectively. Healthy plants, and inoculated plants which were confirmed as infected by RT-PCR at 10 dpi, were transplanted in greenhouse. After 60 days pepper and watermelon seeds were harvested, cleaned, and dried at room temperature for 48 h. Dried seeds were then soaked in supernatant of strain KBPF-004 or control ATCC 8062 (each at OD600: 0.2) in 50 ml Falcon tubes with shaking for 20 min and dried again for 48 h at room temperature. Control seed were washed in the same manner, with water instead of culture supernatant, and similarly dried at room temperature. More than 300 dried seeds per treatment were directly planted in pots containing garden grow soil to germinate, in two separate experiments. At 10 days after germination each whole plant was separated from soil, and total RNA was extracted for cDNA synthesis and RT-PCR essentially as described (Han et al., 2017; Park et al., 2017) for PMMoV detection using primers PMMoVCP-F (5′-AAGGTGTTGATACCCAAGTTT-3′) and PMMoV-CP-R (5′-CAACGAGTTCTCGACTGAC-3′), yielding a product of 498 bp; or CGMMV detection using primers CGMMV-CP-F (5′-TTATGACATCGGCGGTAACT-3′) and CGMMV-CP-R (5′-GATTGTAAGCCATCTTCAAA-3′), yielding a product of 456 bp.

Subcellular localization of MP, CP and 126 kDa Protein of PMMoV and CGMMV after treatment with strain KBPF-004 culture supernatants

Green fluorescent protein (GFP) fusion proteins of the MP, CP and 126 kDa protein of PMMoV and CGMMV in binary vector pGDG (Goodin et al., 2002) were prepared as reported (Han et al., 2017; Park et al., 2017). The GFP:126 kDa, GFP:MP and GFP:CP of PMMoV, and GFP:CP of CGMMV binary vector constructs were grown in A. tumefaciens GV2260, diluted to OD600: 0.6, and infiltrated to N. benthamiana (Bragg and Jackson, 2004) in combination with an equal volume of various ratios of culture supernatants of strain KBPF-004 and ATCC 8062 at equivalent concentration. N. benthamiana leaves were divided into regions infiltrated with A. tumefaciens expressing individual GFP fusion constructs mixed with either strain KBPF-004 or ATCC 8062, essentially as shown in Li et al. (2014). At 2 dpi pieces of N. benthamiana leaves were collected for fluorescence detection. Confocal microscopy using a Zeiss LSM 710 (Zeiss, Oberkochen, Germany) detected green fluorescence with excitation at 488 nm from an argon laser; emission was monitored at 500–520 nm.

Western blot detection of GFP fusion proteins in agroinfiltrated leaves

Total proteins were extracted from agro-infiltrated leaves of N. benthamiana, separated by electrophoresis, blotted to PVDF membranes, and GFP fusion proteins detected using anti-GFP Living Colors monoclonal antibody (Clontech, Mountain View, CA, USA), as previously reported (Han et al., 2017).

Results

Screening and identification of antiviral bacteria

First we isolated more than one thousand colonies of soil-borne bacteria collected in or near tobacco fields located in Daejeon, Republic of Korea. The isolated soil bacteria were grown in MHB media, and supernatants of bacterial cultures were used for antiviral activity screening. Through this antiviral assay we selected nine bacterial isolates as shown in Table 1. Among these nine selected soil-borne bacteria, isolate KBPF-004 showed the highest antiviral activity when 1/20 diluted supernatant was used to treat tobacco leaves, with a mean reduction of 85.5% in local lesion numbers compared to the control non-treated leaf regions (half-leaf method) (Table 1). The remainder of the soil-borne bacteria isolates did not show any significant antiviral activity. Isolated strain KBPF-004 was identified and assigned development code KNF2016.

Antiviral activity of soil bacterium isolated from tobacco plant rhizosphere

Identification of bacterial strain

Isolated strain KBPF-004 was an aerobic, motile, Gram-negative organism. The young colonies had circular form, convex with entire margins, moist, shiny and yellow-color. Older colonies became rough and uplifted, star-shaped and with dark yellow color. Cells were rods of about 0.5–1.0 μm in width by 1.5–3.0 μm in length at 24 h incubation on MHA, and coccoid cells occurred in old cultures. The temperature range for growth was 10–37°C with optimal growth at 30°C. The pH range for growth was pH 6.0–8.0 with optimal growth at pH 7.0. No growth occurred with an NaCl concentration of more than 5%, whereas optimal growth occurred without added NaCl. The major fatty acids in the isolate were 18:1 ω7c, 16:0, and summed feature 3, which contained one or more of the following fatty acids: 16:1 ω7c and/or 15:0 iso 2OH. The major quinone of strain KBPF-004 was Q-9. The 16S rRNA (1,473 bp) sequence of strain KBPF-004 showed 99.05% identity to that of P. oleovorans strain IAM 1508T (accession no. CP000560). The strain KBPF-004 was deposited at the KCTC as P. oleovorans strain KBPF-004 (KCTC 10159BP). Similar analysis of the type strain of P. oleovorans, ATCC 8062 was performed in order to compare with strain KBPF-004; ATCC 8062 showed 19.7% antiviral activity, whereas strain KBPF-004 showed 96.0% (Table 2). This indicated that strain KBPF-004 has antiviral characteristics significantly different from those of the P. oleovorans type strain.

Comparison of antiviral activity of strain KBPF-004 and type strain ATCC 8062

Infectivity and seed transmission rate of PMMoV- and CGMMV-infected seeds following treatment with supernatant of P. oleovorans strain KBPF-004 cultures

We have previously detected seed-transmission of up to 70% among germinated seeds with CGMMV (Park et al., 2017) and similar levels with PMMoV (Han et al., 2017). In vitro transcripts of PMMoV and CGMMV infectious clones were inoculated to seedlings of pepper and watermelon respectively. Harvested seeds were soaked in culture supernatants of either strain KBPF-004 or control strain ACTC 8062 and about 300 seeds of each treatment planted. After twenty days, RNA was extracted from germinated seedlings to detect viral RNA by RT-PCR (Table 3). Significantly fewer germinated seeds treated with P. oleovorans strain KBPF-004 were infected with PMMoV or CGMMV compared to seed treated with strain ATCC 8062. The seed transmission rate of PMMoV was decreased from 61.9% (ATCC 8062 treated) to 15.5% (KBPF-004 treated) and of CGMMV from 59.7% to 15.8% (Table 3), indicating that products of P. oleovorans strain KBPF-004 directly affected viability of CGMMV and PMMoV. Infection rates of ATCC 8062-treated seed were not significantly different from the water wash control (Table 3).

Inhibitory effects of culture filtrate from KBPF-004 on seed transmitted tobamoviruses

Effects of supernatant of P. oleovorans strain KBPF-004 on 126 kDa, MP and CP of PMMoV

Previously we have reported the subcellular localization of agroinfiltrated GFP fusions of the 126 kDa protein, MP, and CP of isolates of CGMMV (Park et al., 2017) and PMMoV (Han et al., 2017). In contrast to results reported for other tobamoviruses (Liu et al., 2005) the PMMoV isolate used in this report showed a different localization pattern of 126 kDa ORF1 (Han et al., 2017). Except for the 126 kDa protein, localization of all GFP fusion proteins followed similar patterns to those reported for other tobamoviruses. When GFP:126 kDaPMMoV, GFP:MPPMMoV, and GFP:CPPMMoV were expressed with different ratios of KBPF-004 and ATCC 8062 supernatants, some differences were observed. In contrast to the normal localization pattern of GFP:126 kDa showing strong aggregation in the cytoplasm in the presence of ATCC 8062 supernatant, we observed that the aggregation diminished in N. benthamiana leaf agroinfitrated with increasing proportion of strain KBPF-004 supernatant (Fig. 1A, 2A). As with GFP:126 kDa, GFP:MPPMMoV localization at the cytoskeleton became weaker at higher proportions of strain KBPF-004 supernatant (Fig. 1B, 2B). Unlike the 126 kDa and MP proteins, the localization pattern of the GFP:CP did not change (Fig. 1C), but GFP:CP detection was significantly reduced in the western blot in P. oleovorans strain KBPF-004-treated compared to the ATCC 8062-treated control (Fig. 1E). Western blots showed that levels of the ORF1 and MP proteins did not appear to differ between treatments (data not shown). Interestingly, the pattern of localization of GFP:CPPMMoV did not show any difference, but the western blot suggested that the amount of CP decreased in the presence of P. oleovorans strain KBPF-004 supernatant, and similar results were observed for GFP:CPCGMMV (Fig. 1D, 1E). The subcellular aggregation or localization patterns of 126 kDa and MP of PMMoV were affected more in the presence of an increased proportion of supernatant of P. oleovorans strain KBPF-004 (Fig. 2). A reduction in the size of GFP:126 kDa aggregates was observed at higher proportions of KBPF-004 supernatant, with increased distribution at the cell periphery (Fig. 2A). For GFP:MP, as the proportion of KBPF-004 supernatant increased, there was reduced association between the MP and the cytoskeleton (Fig. 2B; left to right).

Fig. 1

Subcellular localization of coat protein (CP), movement protein (MP), and 126 kDa of Pepper mild mottle virus (PMMoV) and CP of Cucumber green mottle mosaic virus (CGMMV) in Nicotiana benthamiana treated with culture supernatant of control strain ATCC 8062 or strain KBPF-004. (A) pGDG:126 kDaPMMoV, (B) pGDG:MPPMMoV, (C) pGDG:CPPMMoV, and (D) pGDG:CPCGMMV in the presence of diluted supernatant of ATCC 8062 (left) and strain KBPF-004 (right), respectively. (E) Western blot with anti-GFP ab to detect GFP:CPPMMoV and GFP:CPCGMMV in the presence of diluted supernatant of ATCC 8062 and strain KBPF-004. Confocal microscopy using a Zeiss LSM 710 detected green fluorescence with excitation at 488 nm from an argon laser, and emission monitored at 500–520 nm at 36 h after agroinfiltration. The arrow in (A) indicates an aggregate of GFP:126 kDaPMMoV. Scale bars = 50 μm.

Fig. 2

Subcellular localization of 126 kDa and movement protein of Pepper mild mottle virus (PMMoV) as influenced by the proportion of strain KBPF-004 supernatant ratio. Binary vector construct expressed from Agrobacterium was maintained at an equal concentration with each dilution of strain KBPF-004 culture supernatant. Four quadrants of each N. benthamiana leaf were infiltrated with mixtures of 1:1:0 (1 ml of binary vector expressed Agrobacterium (OD600: 0.6): 1 ml of ATCC 8062 supernatant: 0 ml of strain KBPF-004 supernatant), 1:0.8:0.2, 1:0.6:0.5, and 1:0:1, respectively. Confocal microscopy using a Zeiss LSM 710 detected green fluorescence with excitation at 488 nm from an argon laser, and emission monitored at 500–520 nm at 36 h after agroinfiltration. Scale bars = 50 μm.

Discussion

Occasional reports of soil-borne bacteria having antiviral functions exist, such as that of Acinetobacter antiviralis against TMV (Lee et al., 2009); however, the detailed mechanism was not clearly understood. In this study we have focused on antiviral activity of candidate bacteria collected from field soils contaminated with tobamoviruses. P. oleovorans has been reported as an oil degrading bacterium (Lee and Chandler, 1941), but here for the first time we have demonstrated that isolate strain KBPF-004 (developmental code KNF2016) has significant antiviral activity not present in type isolate ATCC 8062. Firstly, we were able to screen antiviral activity of a soil-borne bacteria against TMV using a half-leaf assay. Secondly, through our experiments with tobamovirus-infected seeds, we observed significantly reduced seed transmission rates of both PMMoV and CGMMV following seed treatment with P. oleovorans strain KBPF-004 supernatant. Our further experiments to examine expression levels and subcellular localization of individual gene product:GFP fusion proteins in the presence of an increasing proportion of P. oleovorans strain KBPF-004 supernatant contribute to an understanding of these results. Tobamoviruses are often highly seed-transmitted, and the CGMMV and PMMoV isolates tested each showed about 70% seed transmission rates (Han et al., 2017; Park et al., 2017) (Table 3). However, our data showed that transmission of these seed coat-contaminating viruses was significantly reduced by seed treatment with culture supernantant of P. oleovorans strain KBPF-004; as control strain ATCC 8062 did not show any significant reduction of seed transmissibility of CGMMV and PMMoV, we suggest that soluble bacterial products in the culture supernatant of KBPF-004 directly affect the viability of virions on the surface of watermelon and pepper seeds. In addition, expression of the PMMoV CP in plant cells through agroinfiltration in presence of diluted supernatant of P. oleovorans strain KBPF-004 showed a reduced amount of CP compared to ATCC 8062. The reduction in levels of CP detected after agroinfiltration of infectious clones of PMMoV or CGMMV in the presence of culture supernatant of KBPF-004, but not ATCC 8062, is interesting. This suggests several possible mechanisms of action for the antiviral effects of KBPF-004, including (a) proteolytic cleavage directed at the CPs of both PMMoV and CGMMV; (b) interference in the production of the subgenomic RNA (sgRNA) encoding the CP; (c) inhibition of CP sgRNA translation; or (d) interference in virion stability affecting either assembly or disassembly of viral particles leading to targeting of free CP for degradation by the proteasome. The inhibition of seed transmission after seed washing in culture supernatant could potentially also be explained by proteolytic cleavage of CP in virions, exposing the genomic RNA to ribonuclease digestion, although an alternate explanation could be surfactant activity releasing viral particles from the seed coat, with or without virion destabilization. Further experiments will be directed to differentiating between these possibilities, in order to elucidate the mechanism(s) of antiviral activity of KBPF-004 culture supernatant, and to determine whether the observed antiviral effects against the tobamoviruses PMMoV and CGMMV extend to viruses from other taxonomic groups.

In addition to the reduction of CP expression by ingredient(s) of the culture supernatant in agroinfiltrated leaves, subcellular aggregation of 126 kDa, and association of MP with the cytoskeleton were both diminished by co-infiltration with diluted supernatant. The altered or diminished functions of 126 kDa and MP caused by components in the culture supernatant suggest multiple mechanisms for the diminished infectivity of seed-borne PMMoV and CGMMV when treated seeds germinated.

More than ten thousand secondary products have been reported to have been dissolved in the bacterial growth media (Monod, 1949). Thus one or multiple ingredients in supernatant of P. oleovorans strain KBPF-004 could affect CP, MP, and 126 kDa proteins of CGMMV and PMMoV. Although we have not yet been able to identify the factors in P. oleovorans strain KBPF-004 culture supernatants responsible for the observed antiviral effects, we have established procedures by which we were able to (1) initiate a screen to identify antiviral microorganisms in soil from virus infected fields and (2) evaluate multiple specific antiviral activities through the expression of viral proteins in the presence of various proportions of antiviral candidate elements contained in culture supernatant of the microorganism examined in this report.

Further research will seek to identify the unknown product(s) from P. oleovorans strain KBPF-004 (KNF2016) which confer the observed antiviral activities, and to investigate both the mechanisms of action, and possible evolutionary interactions among antiviral microorganisms, virus infected plants, and virus-contaminated soil.

Acknowledgments

This study was financially supported by research fund of Chungnam National University in 2016.

References

Adams MJ, Antoniw JF, Kreuze J. 2009;Virgaviridae: a new family of rod-shaped plant viruses. Arch Virol 154:1967–1972. 10.1007/s00705-009-0506-6. 19862474.
Agarwal VK, Sinclair JB. 1996. Principles of seed pathology 2nd edth ed. CRC Press. Boca Raton, FL, USA:
Bawden FC, Freeman GG. 1952;The nature and behaviour of inhibitors of plant viruses produced by Trichothecium roseum Link. J Gen Microbiol 7:154–168. 10.1099/00221287-7-1-2-154. 13011267.
Bragg JN, Jackson AO. 2004;The C-terminal region of the Barley stripe mosaic virus gammab protein participates in homologous interactions and is required for suppression of RNA silencing. Mol Plant Pathol 5:465–481. 10.1111/j.1364-3703.2004.00246.x. 20565621.
Choi GS. 2001;Occurrence of two tobamovirus diseases in cucurbits and control measures in Korea. Plant Pathol J 17:243–248.
Choi JK, Lee SY. 1995. Introduction to plant virology Kangwon University Press. Chuncheon, Korea: p. 240.
Demski JW. 1981;Tobacco mosaic virus is seedborne in pimiento peppers. Plant Dis 65:723–724. 10.1094/PD-65-723.
Derrick PM, Carter SA, Nelson RS. 1997;Mutation of the tobacco mosaic tobamovirus 126-and 183-kDa proteins: effects on phloem-dependent virus accumulation and synthesis of viral proteins. Mol Plant-Microbe Interact 10:589–596. 10.1094/MPMI.1997.10.5.589.
Duggar BM, Armstrong JK. 1925;The effect of treating the virus of tobacco mosaic with the juices of various plants. Ann Mo Bot Gard 12:359–366. 10.2307/2394061.
Endo Y, Tsurugi K, Lambert JM. 1988;The site of action of six different ribosome-inactivating proteins from plants on eukaryotic ribosomes: the RNA N-glycosidase activity of the proteins. Biochem Biophys Res Commun 150:1032–1036. 10.1016/0006-291X(88)90733-4. 3342056.
Felsenstein J. 1985;Confidence limits on phylogenies: an approach using the bootstrap. Evolution 39:783–791. 10.1111/j.1558-5646.1985.tb00420.x. 28561359.
Felsenstein J. 1993. {PHYLIP}: phylogenetic inference package, version 3.5c Department of Genetics, University of Washington. Seattle, WA, USA:
Fitch WM. 1971;Toward defining the course of evolution: minimum change for a specific tree topology. Syst Biol 20:406–416. 10.1093/sysbio/20.4.406.
Fukami J, Uesugi Y, Ishizuka K, Tomizawa C. 1981. Methods in pesticide science 2Soft Science. Tokyo, Japan: p. 430.
Goodin MM, Dietzgen RG, Schichnes D, Ruzin S, Jackson AO. 2002;pGD vectors: versatile tools for the expression of green and red fluorescent protein fusions in agroinfiltrated plant leaves. Plant J 31:375–383. 10.1046/j.1365-313X.2002.01360.x. 12164816.
Gupta BM, Price WC. 1950;Production of plant virus inhibitors by fungi. Phytopathology 40:642–652.
Han SH, Park JS, Han JY, Gong JS, Park CH, Kim JK, Seo EY, Domier LL, Hammond J, Lim HS. 2017;New Korean isolates of Pepper mild mottle virus (PMMoV) differ in symptom severity and subcellular localization of the 126 kDa protein. Virus Genes 53:434–445. 10.1007/s11262-017-1432-4. 28176159.
Hollings M, Komuro Y, Tochihara H. 1975 onwards. Cucumber green mottle mosaic virus. Descriptions of Plant Viruses. No. 154 URL http://www.dpvweb.net/dpv/show-adpv.php?dpvno=154. 2 January 2017.
Hull R. 2002. Matthews plant virology 4th edth ed. Academic Press. San Diego, CA, USA:
Johnson J. 1938;Plant virus inhibitors produced by microorganisms. Science 88:552–553. 10.1126/science.88.2293.552-a. 17776553.
Jones WA, Jacobson M, Kahn RP. 1959;Chemical nature of a plant-virus inhibitor from rice. Nature 184(Suppl 15):1146. 10.1038/1841146a0. 14407791.
Kassanis B, Kleczkowski A. 1948;The isolation and some properties of a virus-inhibiting protein from Phytolacca esculenta. Microbiology 2:143–153.
Kim OS, Cho YJ, Lee K, Yoon SH, Kim M, Na H, Park SC, Jeon YS, Lee JH, Yi H, Won S, Chun J. 2012;Introducing EzTaxon-e: a prokaryotic 16S rRNA gene sequence database with phylotypes that represent uncultured species. Int J Syst Evol Microbiol 62:716–721. 10.1099/ijs.0.038075-0.
Lee JS, Lee KC, Kim KK, Hwang IC, Jang C, Kim NG, Yeo WH, Kim BS, Yu YM, Ahn JS. 2009;Acinetobacter antiviralis sp. nov., from Tobacco plant roots. J Microbiol Biotechnol 19:250–256. 19349749.
Lee M, Chandler AC. 1941;A study of the nature, growth and control of bacteria in cutting compounds. J Bacteriol 41:373–386. 16560407. 374703.
Li H, Ding X, Wang C, Ke H, Wu Z, Wang Y, Liu H, Guo J. 2016;Control of Tomato yellow leaf curl virus disease by Enterobacter asburiae BQ9 as a result of priming plant resistance in tomatoes. Turk J Biol 40:150–159. 10.3906/biy-1502-12.
Li MJ, Kim JK, Seo EY, Hong SM, Hwang EI, Moon JK, Domier LL, Hammond J, Youn YN, Lim HS. 2014;Sequence variability in the HC-Pro coding regions of Korean soybean mosaic virus isolates is associated with differences in RNA silencing suppression. Arch Virol 159:1373–1383. 10.1007/s00705-013-1964-4. 24378822.
Liu HW, Luo LX, Li JQ, Liu PF, Chen XY, Hao JJ. 2014;Pollen and seed transmission of Cucumber green mottle mosaic virus in cucumber. Plant Pathol 63:72–77. 10.1111/ppa.12065.
Liu JZ, Blancaflor EB, Nelson RS. 2005;The tobacco mosaic virus 126-kilodalton protein, a constituent of the virus replication complex, alone or within the complex aligns with and traffics along microfilaments. Plant Physiol 138:1853–1865. 10.1104/pp.105.065722. 16040646. 1183377.
Lovisolo O. 1979;Virus and viroid diseases of cucurbits. Acta Hortic 88:33–82.
Madhusudhan KN, Vinayarani G, Deepak SA, Niranjana SR, Prakash HS, Singh GP, Sinha AK, Prasad BC. 2011;Antiviral activity of plant extracts and other inducers against tobamoviruses infection in bell pepper and tomato plants. Int J Plant Pathol 10.3923/ijpp.2011.35.42.
Monod J. 1949;The growth of bacterial cultures. Annu Rev Microbiol 3:371–394. 10.1146/annurev.mi.03.100149.002103.
Nagai Y. 1981. Control of mosaic disease of tomato and sweet pepper caused by tobacco mosaic virus. Special Bulletin of the Chiba-ken Agricultural Experiment Station (Japan). No. 9 Agricultural Experiment Station Chiba-ken. Chiba, Japan:
Park CH, Ju HK, Han JY, Park JS, Kim IH, Seo EY, Kim JK, Hammond J, Lim HS. 2017;Complete nucleotide sequences and construction of full-length infectious cDNA clones of cucumber green mottle mosaic virus (CGMMV) in a versatile newly developed binary vector including both 35S and T7 promoters. Virus Genes 53:286–299. 10.1007/s11262-016-1415-x.
Rast ATB, Stijger CCMM. 1987;Disinfection of pepper seed infected with different strains of capsicum mosaic virus by trisodium phosphate and dry heat treatment. Plant Pathol 36:583–588. 10.1111/j.1365-3059.1987.tb02277.x.
Reingold V, Lachman O, Blaosov E, Dombrovsky A. 2015;Seed disinfection treatments do not sufficiently eliminate the infectivity of Cucumber green mottle mosaic virus (CGMMV) on cucurbit seeds. Plant Pathol 64:245–255. 10.1111/ppa.12260.
Saitou N, Nei M. 1987;The neighbor-joining method: a new method for reconstructing phylogenetic trees. Mol Biol Evol 4:406–425. 3447015.
Sambrook JR, Russell D, DW . 2001;Molecular cloning: a laboratory manual. Quart Rev Biol 76:348–349. 10.1086/394015.
Schaad NW, Jones JB, Chun W. 2001. Laboratory guide for identification of plant pathogenic bacteria 3rd edth ed. APS Press. St. Paul, MN, USA: p. 377.
Takamatsu N, Ishikawa M, Meshi T, Okada Y. 1987;Expression of bacterial chloramphenicol acetyltransferase gene in tobacco plants mediated by TMV-RNA. EMBO J 6:307–311. 15981328. 553396.
Tamura K, Stecher G, Peterson D, Filipski A, Kumar S. 2013;MEGA6: Molecular Evolutionary Genetics Analysis version 6.0. Mol Biol Evol 30:2725–2729. 10.1093/molbev/mst197. 24132122. 3840312.
Verma VS, Raychaudhuri SP, Khan AM. 1969;Properties and nature of inhibitors of potato virus X in four medicinal plant extracts. Biol Plant 11:384–387. 10.1007/BF02921405.
Weisburg WG, Barns SM, Pelletier DA, Lane DJ. 1991;16S ribosomal DNA amplification for phylogenetic study. J Bacteriol 173:697–703. 10.1128/jb.173.2.697-703.1991. 1987160. 207061.
Wetter C, Conti M. 1988 onwards. Pepper mild mottle virus. Descriptions of Plant Viruses. No. 330 URL http://www.dpvweb.net/dpv/showdpv.php?dpvno=330. 1 January 2017.
Wu H, Qin B, Chen H, Peng B, Cai J, Gu Q. 2011;The rate of seed contamination and transmission of Cucumber green mottle mosaic virus in watermelon and melon. Scientia Agricultura Sinica 44:527–532.

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Fig. 1

Subcellular localization of coat protein (CP), movement protein (MP), and 126 kDa of Pepper mild mottle virus (PMMoV) and CP of Cucumber green mottle mosaic virus (CGMMV) in Nicotiana benthamiana treated with culture supernatant of control strain ATCC 8062 or strain KBPF-004. (A) pGDG:126 kDaPMMoV, (B) pGDG:MPPMMoV, (C) pGDG:CPPMMoV, and (D) pGDG:CPCGMMV in the presence of diluted supernatant of ATCC 8062 (left) and strain KBPF-004 (right), respectively. (E) Western blot with anti-GFP ab to detect GFP:CPPMMoV and GFP:CPCGMMV in the presence of diluted supernatant of ATCC 8062 and strain KBPF-004. Confocal microscopy using a Zeiss LSM 710 detected green fluorescence with excitation at 488 nm from an argon laser, and emission monitored at 500–520 nm at 36 h after agroinfiltration. The arrow in (A) indicates an aggregate of GFP:126 kDaPMMoV. Scale bars = 50 μm.

Fig. 2

Subcellular localization of 126 kDa and movement protein of Pepper mild mottle virus (PMMoV) as influenced by the proportion of strain KBPF-004 supernatant ratio. Binary vector construct expressed from Agrobacterium was maintained at an equal concentration with each dilution of strain KBPF-004 culture supernatant. Four quadrants of each N. benthamiana leaf were infiltrated with mixtures of 1:1:0 (1 ml of binary vector expressed Agrobacterium (OD600: 0.6): 1 ml of ATCC 8062 supernatant: 0 ml of strain KBPF-004 supernatant), 1:0.8:0.2, 1:0.6:0.5, and 1:0:1, respectively. Confocal microscopy using a Zeiss LSM 710 detected green fluorescence with excitation at 488 nm from an argon laser, and emission monitored at 500–520 nm at 36 h after agroinfiltration. Scale bars = 50 μm.

Table 1

Antiviral activity of soil bacterium isolated from tobacco plant rhizosphere

Strain Antiviral activity (%)* Mean§

I II III
KBPF-001 170/186 (8.60) 248/263 (5.70) 187/221 (15.38) 9.89 ± 4.97 b
KBPF-002 216/226 (4.42) 131/147 (10.88) 301/318 (5.35) 6.88 ± 3.49 b
KBPF-003 207/218 (5.05) 311/329 (5.47) 178/227 (21.59) 10.70 ± 9.43 b
KBPF-004 41/257 (83.86) 37/235 (84.26) 24/210 (88.52) 85.56 ± 2.61 a
KBPF-005 145/172 (15.70) 175/195 (10.26) 193/270 (28.52) 18.16 ± 9.38 b
KBPF-006 167/237 (29.54) 243/269 (9.67) 186/211 (11.85) 17.02 ± 10.90 b
KBPF-007 161/188 (14.36) 203/207 (1.93) 240/256 (6.25) 7.51 ± 6.31 b
KBPF-008 133/149 (10.74) 221/237 (6.75) 252/255 (1.18) 6.22 ± 4.80 b
KBPF-009 203/225 (9.78) 255/262 (2.67) 265/273 (2.93) 5.13 ± 4.03 b
*

Antiviral activity (%) = [1 − (number of lesions on treatment/number of lesions on control)] × 100.

§

Mean ± standard deviation indicated by letters are significantly different according to the Duncan’s multiple range test at P < 0.001. Antiviral activity was assayed using three tobacco plants per strain.

Table 2

Comparison of antiviral activity of strain KBPF-004 and type strain ATCC 8062

Strain Antiviral activity (%)* Mean§

I II III
KBPF-004 7/258 (97.29) 13/262 (95.04) 9/209 (95.69) 96.00 ± 1.16 a
ATCC 8062 152/234 (35.04) 190/211 (9.95) 212/247 (14.17) 19.72 ± 13.43 b
*

Antiviral activity (%) = [1 − (number of lesions on treatment/number of lesions on control)] × 100.

§

Mean ± standard deviation indicated by letters are significantly different according to the Duncan’s multiple range test at P < 0.001. Antiviral activity was assayed using three tobacco plants per strain.

Table 3

Inhibitory effects of culture filtrate from KBPF-004 on seed transmitted tobamoviruses

Treatment PMMoV CGMMV


Infected seed rate (%)* Mean§ (P < 0.01) Infected seed rate (%) Mean (P < 0.05)


I II I II
KBPF-004 38/198 (19.19) 11/93 (11.80) 15.50 ± 5.22 b 43/299 (14.38) 15/87 (17.20) 15.79 ± 1.99 b
ATCC8062 132/221 (59.73) 59/92 (64.10) 61.92 ± 3.09 a 153/301 (50.83) 61/89 (68.50) 59.67 ± 12.49 a
Control|| 159/230 (69.13) 61/98 (65.69) 65.69 ± 4.87 a 177/323 (54.80) 48/84 (57.14) 55.97 ± 1.65 a

PMMoV, Pepper mild mottle virus; CGMMV, Cucumber green mottle mosaic virus.

*

Infected seed rate (%) = (number of infected seed/number of total seed) × 100.

§

Mean ± standard deviation indicated by letters are significantly different according to the Duncan’s multiple range test.

||

Control seed were washed in water.