RESUMEN
Pocketbook plants (Calceolaria spp.) are flowering ornamentals often grown as potted plants (Poesch 1937). In December 2022, leaf blight symptoms were observed on 2-mo-old plants of C. hybrida F1 'Dainty'. The disease was found in a nursery in Ren'ai Township, Nantou, and about 20% of the plants exhibited symptoms. Symptomatic plants had brown or gray necrotic lesions of different sizes and shapes, mostly around leaf margins. Lower leaf wilting was also observed (Fig. S1, A and B). Three plants were sampled. Leaf lesions were surface-disinfected with 75% ethanol and cut into smaller pieces in 10 mM MgCl2. After observing bacterial streaming under a microscope, the bacteria were streaked onto nutrient agar (NA). Following 2 days at 28°C, a type of round, creamy white colony predominated on all the plates. Three strains (Calc-A, Calc-B, and Calc-C) were obtained, one from each plant. The strains produced fluorescent pigments on King's B medium and were tested Gram-negative. The strains were characterized with the LOPAT scheme (Schaad et al. 2001). They did not exhibit activities of pectic enzymes, arginine dihydrolase and levan sucrase, but produced oxidase and induced the hypersensitive response in tobacco. DNA was extracted from the strains for PCR amplification of the 16S rDNA with primer pair 27f/1492r as described by Lane (1991). The 16S rDNA sequences were compared with entries in the GenBank database. The sequences obtained (GenBank accession no. OR824302) matched that of Pseudomonas cichorii MAFF 301158 (accession no. AB724288; 1,403/1,403 bp) and were 99% identical to that of DSM 50259T (accession no. CP074349; 1,391/1,405 bp). The strains were also tested with the species-specific primers hrp1a and hrp2a (Cottyn et al. 2011). The amplicons were sequenced and a BLASTn search showed that the sequences (accession no. OR827305) shared the highest identity (99.3%) with that of P. cichorii strain 83-1 (accession no. DQ168848; 848/854 bp) and were 97.3% identical to the sequence of DSM 50259T (accession no. CP074349; 831/854 bp). Calc-A was selected as a representative strain and deposited in the Bioresource Collection and Research Center, Taiwan (reference no. BCRC 81432). Koch's postulates were fulfilled by spray-inoculating a suspension of Calc-A on three 2-mo-old C. hybrida F1 'Dainty' plants. The inoculum was prepared by suspending NA-grown cells in 10 mM MgCl2 including 0.02% Silwet L-77 (OD600 = 0.3; 1.5 x 108 CFU/ml). For the controls, three plants were sprayed with bacteria-free solution. The plants were bagged throughout the experiment and kept in a growth chamber (14/10 h light/dark; 26/24°C day/night). Leaf blight and wilting symptoms developed on all leaves of the inoculated plants after 30 h, but not the controls (Fig. S1, C and D). The pathogen was reisolated from the treatment group, and colony PCR with hrp1a/hrp2a showed that the reisolated strain shared the same sequence with Calc-A to Calc-C. Repeating the inoculation assay produced consistent results. This is the first report of P. cichorii affecting Calceolaria in Taiwan. The bacterium has been reported infecting diverse crops in Taiwan, such as tomato and lettuce (Tsai et al. 2014). Expanding the understanding of the pathogen's potential hosts could help prevent its spread across important crops.
RESUMEN
Pectobacterium spp. are phytopathogenic bacteria whose phylogeny has been continuously revised throughout the years. Previous studies on Pectobacterium's phenotypic diversity often analyzed strains obtained from specific crops or adopted outdated Pectobacterium classification systems. Therefore, a current perspective on trait variations in Pectobacterium species or strains infecting more diverse plant species is limited. This study conducted phylogenetic and phenotypic analyses on strains isolated from 8 eudicot and 4 monocot families in Taiwan. Phylogenetic analysis on 78 strains identified 6 recognized species, namely P. brasiliense, P. aroidearum, P. actinidiae, P. colocasium, P. carotovorum, and P. versatile. Among these, the first two were the most predominant. Patterns suggesting varying host preferences among bacterial species were detected; most P. aroidearum strains were isolated from monocots, whereas P. brasiliense and P. actinidiae tended to exhibit preferences for eudicots. Physiological tests and Biolog analyses conducted on representative strains of each species revealed great within-species phenotypic variation. Despite these strain-level variations, a combination of indole production and phosphatase activity tests was capable of distinguishing all representative strains of P. brasiliense from those of other identified species. Inoculation assays on potato, bok choy, calla lily and onion showed inter- and intra-specific heterogeneities in the tested strains' maceration potentials. Virulence patterns across Pectobacterium species and strains differed depending on the inoculated host. Altogether the findings from this work expand the understanding of Pectobacterium's phenotypic diversity and provide implications for pathogen identification and management.
RESUMEN
Codiaeum variegatum (family Euphorbiaceae) is a leaf ornamental commonly known as variegated croton, which is often found in gardens or grown as indoor plants. In December of 2022, two cutting-propagated variegated croton plants exhibiting abnormal shoot proliferation and little leaf symptoms (Fig. S1) were found in a nursery owned by a private breeder in Wanluan Township, Pingtung County, Taiwan. The plants were propagated from a single stock plant, which died during transplanting from a commercial nursery in Changzhi Township, Pingtung County. To determine the potential cause of such symptoms, leaf tissues were collected from the center of the two symptomatic plants. Their DNA were extracted with a Synergy 2.0 Plant DNA Extraction Kit (OPS Diagnostics, Lebanon, NJ) and used for further testing. As controls, two symptomless stock plants were collected from the commercial nursery in Changzhi Township and used to produce cutting-propagated plants; leaf DNA was extracted from each plant as described above. The DNA samples were subjected to PCR testing using the phytoplasma-specific primer pair P1/P7 (Schneider et al. 1995), and only DNA from the symptomatic plants produced the expected 1.8-kb amplicon. The two phytoplasma isolates detected in the plants were designated as CvaA and CvaB. After sequencing and analyzing the data using the iPhyClassifier program (Zhao et al. 2009), both CvaA and CvaB were classified to subgroup 16SrII-A (GenBank accession no. L33765) with a similarity coefficient of 1.0. The near-full-length 16S rDNA fragments of the detected isolates (GenBank accession no. OR794242) were also identical (1,463/1,463 bp) to that of NCHU2014 (GenBank accession no. CP040925, bp 537768-539230), a reference 'Ca. Phytoplasma australasiaticum'-related strain (16SrII-A) found in Taiwan (Chang et al. 2015; Rodrigues Jardim et al. 2023). To validate the results, the DNA samples were also tested with 16SrII group-specific semi-nested PCR targeting the elongation factor Tu gene. The outer and inner primer pairs used were TUF-II-F1/TUF-II-R1 and TUF-II-F2/TUF-II-R1, respectively (Al-Subhi et al. 2017). An expected amplicon was detected in the symptomatic samples but not in the symptomless counterparts. The amplified fragments' sequences (GenBank accession no. OR634931) were identical to that of the elongation factor Tu gene of the 'Ca. Phytoplasma australasiaticum'-related strain NCHU2014 (989/989 bp; GenBank accession no. CP040925, bp 139344-140332). The protein translocase gene secY of the detected phytoplasma was also amplified and sequenced using semi-nested primers SecYF1(II), SecYF2(II) and SecYR1(II) (Lee et al. 2010). Again, the sequences of the detected isolates (GenBank accession no. OR862773) were identical to that of NCHU2014 (1,263/1,263; GenBank accession no. CP040925, bp 192846-194108). The quality of the DNA samples was confirmed by PCR targeting the plant host's 28S rDNA using primer pair 28KJ/28C (Cullings 1992) and all symptomatic and symptomless samples produced the target amplicon (0.7 kb). 16SrII phytoplasmas have been detected in different host plants in Taiwan (Chang et al. 2015). To our knowledge, this is the first record of this group of pathogens infecting variegated croton in Taiwan. Branch-inducing phytoplasma has been used to improve the ornamental values of poinsettias, another Euphorbiaceae species (Lee et al. 1997). Further testing is needed to determine whether the phytoplasma detected in this work could be used for similar purposes.
RESUMEN
Zucchini yellow mosaic virus (ZYMV) seriously damages cucurbits worldwide. Control of ZYMV by cross-protection has been practised for decades, but selecting useful mild viruses is time-consuming and laborious. Most attenuated potyviruses used for cross-protection do not induce hypersensitive reaction (HR) in Chenopodium quinoa, a local lesion host Chenopodium quinoa. Here, severe ZYMV TW-TN3 tagged with green fluorescent protein (GFP), designated ZG, was used for nitrous acid mutagenesis. From three trials, 11 mutants were identified from fluorescent spots without HR in inoculated C. quinoa leaves. Five mutants caused attenuated symptoms in squash plants. The genomic sequences of these five mutants revealed that most of the nonsynonymous changes were located in the HC-Pro gene. The replacement of individual mutated HC-Pros in the ZG backbone and an RNA silencing suppression (RSS) assay indicated that each mutated HC-Pro is defective in RSS function and responsible for reduced virulence. Four mutants provided high degrees of protection (84%-100%) against severe virus TW-TN3 in zucchini squash plants, with ZG 4-10 being selected for removal of the GFP tag. After removal of the GFP gene, Z 4-10 induced symptoms similar to ZG 4-10 and still provided 100% protection against TW-TN3 in squash, thus is considered not a genetically engineered mutant. Therefore, using a GFP reporter to select non-HR mutants of ZYMV from C. quinoa leaves is an efficient way to obtain beneficial mild viruses for cross-protection. This novel approach is being applied to other potyviruses.
Asunto(s)
Cucurbita , Potyvirus , Ácido Nitroso , Potyvirus/genética , Mutagénesis , Interferencia de ARNRESUMEN
Control of plant viruses by cross-protection is limited by the availability of effective protective strains. Incorporation of an NIa-protease processing site in the extreme N-terminal region of the helper component protease (HC-Pro) of turnip mosaic virus (TuMV) resulted in a mutant virus TuHND I that induced highly attenuated symptoms. Recombination analysis verified that two variations, F7I mutation and amino acid 7-upstream-deletion, in HC-Pro co-determined TuHND I attenuation. TuHND I provided complete protection to Nicotiana benthamiana and Brassica campestris subsp. chinensis plants against infection by the severe parental strain. Aphid transmission tests revealed that TuHND I was not aphid-transmissible. An RNA silencing suppression (RSS) assay by agroinfiltration suggested the RSS-defective nature of the mutant HC-Pro. In the context (amino acids 3-17) encompassing the two variations of HC-Pro, we uncovered an FWKG-α-helix 1 (αH1) element that influenced the functions of aphid transmission and RSS, whose motifs were located far downstream. We further demonstrated that HC-Pro F7 was a critical residue on αH1 for HC-Pro functions and that reinstating αH1 in the RSS-defective HC-Pro of TuHND I restored the protein's RSS function. Yeast two-hybrid and bimolecular fluorescence complementation assays indicated the FWKG-αH1 element as an integral part of the HC-Pro self-interaction domain. The possibility of regulation of the mechanistically independent functions of RSS and aphid transmission by the FWKG-αH1 element is discussed. Extension of TuMV HC-Pro FWKG-αH1 variations to another potyvirus, zucchini yellow mosaic virus, also generated nonaphid-transmissible cross-protective mutant viruses. Hence, the modification of the FWKG-αH1 element can generate effective attenuated viruses for the control of potyviruses by cross-protection.
