First report of Pseudomonas cichorii causing bacterial leaf blight of pocketbook plant (Calceolaria hybrida) in Taiwan.

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.

Inter- and intra-specific variations in phenotypic traits of Pectobacterium strains isolated from diverse eudicots and monocots in Taiwan.

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.

Complete genome sequence of Agrobacterium pusense Bbcg2-2, a strain isolated from blueberry crown gall in Taiwan.

Agrobacterium pusense Bbcg2-2 is a strain isolated from a crown gall sample of blueberry (Vaccinium corymbosum) cultivar "Flicker" grown in Taiwan. The complete genome sequence of this bacterium consists of a 2,798,342-bp circular chromosome, a 2,140,031-bp linear chromid, and a 386,016-bp circular plasmid.

First report of a 'Candidatus Phytoplasma australasiaticum'-related phytoplasma strain associated with shoot proliferation disease of variegated croton in Taiwan.

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.

Infection patterns of 'Candidatus Liberibacter europaeus' in Cacopsylla oluanpiensis, a psyllid pest of Pittosporum pentandrum.

'Candidatus Liberibacter' is a genus of plant-associated bacteria that can be transmitted by insects of the superfamily Psylloidea. Since many members of this genus are putative causal agents of plant diseases, it is crucial in studying their interactions with the psyllid vectors. However, previous studies have mainly focused on few species associated with diseases of economic significance, and this may potentially hinder the development of a more comprehensive understanding of the ecology of 'Ca. Liberibacter'. The present study showed that an endemic psyllid species in Taiwan, Cacopsylla oluanpiensis, is infected with a species of 'Ca. Liberibacter'. The bacterium was present in geographically distant populations of the psyllid and was identified as 'Ca. Liberibacter europaeus' (CLeu), a species which generally does not induce plant symptoms. Analysis of CLeu infection densities in male and female C. oluanpiensis with different abdominal colors using quantitative polymerase chain reaction revealed that CLeu infection was not significantly associated with psyllid gender and body color. Instead, CLeu infection had a negative effect on the body sizes of both male and female psyllids, which is influenced by bacterial titer. Investigation on CLeu's distribution patterns in C. oluanpiensis's host plant Pittosporum pentandrum indicated that CLeu does not behave as a plant pathogen. Also, results showed that nymph-infested twigs had a greater chance of carrying high loads of CLeu, suggesting that ovipositing females and the nymphs are the main source of the bacterium in the plants. This study is not only the first to formally report the presence of CLeu in C. oluanpiensis and plants in the family Pittosporaceae, but also represents the first record of the bacterium in Taiwan. Overall, the findings in this work broaden the understanding of associations between psyllids and 'Ca. Liberibacter' in the field.

First report of Robbsia andropogonis causing bacterial leaf spot of bougainvilleas in Taiwan.

Bougainvilleas (Bougainvillea spp.) are popular ornamentals commonly grown as bushes, vines, or trees worldwide (Kobayashi et al. 2007). Leaf spot symptoms were observed on a bougainvillea hedge located in North District, Taichung, Taiwan during August of 2022. The lesions were brown, necrotic and had yellow halos (Fig. S1). All the plants at the location showed similar symptoms. Leaf samples were collected from five plants and symptomatic tissues were minced in 10 mM MgCl2. The samples were streaked onto nutrient agar (NA) and after culturing at 28°C for 2 days, small, round, creamy white colonies were consistently isolated from all the samples. A total of five strains (BA1 to BA5) were obtained; each of them was isolated from a different plant. All five strains induced hypersensitive response in tobacco leaves. Amplification and sequencing of the isolated strains' 16S rDNA using primers 27F and 1492R (Lane 1991) revealed that all five strains shared identical sequences (GenBank accession no. OQ053015) with Robbsia andropogonis LMG 2129T (formerly Burkholderia andropogonis and Pseudomonas andropogonis; GenBank accession no. NR104960; 1,393/1,393 bp). Further testing of BA1 to BA5's DNA samples using the pathogen's species-specific primers Pf (5'-AAGTCGAACGGTAACAGGGA-3') and Pr (5'-AAAGGATATTAGCCCTCGCC-3'; Bagsic et al. 1995) successfully amplified the expected 410-bp amplicon in all five samples; the sequences of the PCR products completely matched to those of BA1 to BA5's 16S rDNA. Strains BA1 to BA5 also tested negative for arginine dihydrolase and oxidase activity, and failed to grow at 40°C, all of which are consistent with descriptions of R. andropogonis (Schaad et al. 2001). Pathogenicity of the isolated bacteria was confirmed by spray inoculation. Three representative strains, BA1 to BA3, were used for the assay. Bacterial colonies were scraped from NA plates and suspended in 10 mM MgCl2 added with 0.02% Silwet L-77. The concentrations of the suspensions were adjusted to 4.4-5.8 x 108 cfu/ml. The suspensions were sprayed onto three-month-old, cutting-propagated bougainvillea plants (to runoff). Controls were treated with bacteria-free solutions. Three plants were used for each treatment group (and the controls). The plants were placed in a growth chamber (27/25°C, day/night; 14-hour photoperiod) and bagged for three days. Within 20 days post inoculation, brown, necrotic lesions resembling those observed in the sampling site were observed on all inoculated plants, but not on the controls. One strain was re-isolated for each treatment group and the re-isolated strains all shared the same colony morphology and 16S rDNA sequence with BA1 to BA5. Additional PCR testing of these re-isolated strains using Pf and Pr also produced the expected amplicon. This is the first formal report of R. andropogonis affecting bougainvilleas in Taiwan. The pathogen has been reported causing diseases of betel palm (Areca catechu), corn and sorghum in Taiwan (Hseu et al. 2007; Hsu et al. 1991), some of which are economically important (Lisowicz 2000; Navi et al. 2002). As such, infected bougainvilleas could potentially serve as an inoculum source for these diseases.

First report of Dickeya dadantii causing bacterial soft rot of Scindapsus pictus in Taiwan.

Scindapsus pictus (satin pothos or silver vine) is an evergreen climbing plant belonging to the Araceae family, subfamily Monstereae (Bown, 2000), which is also cultivated as a foliage ornamental (Masnira et al. 2019). In September of 2022, soft rot symptoms were observed on potted S. pictus plants grown in a greenhouse in Nantun District, Taichung, Taiwan, in which soft rot of another aroid (philodendron) has also been reported (Wu et al. 2023). The symptoms appeared on the petioles and most of them tended to extend to the leaf blades; the colors of leaf lesions ranged from dark brown to gray (Fig. S1). Some 70% of the plants in the greenhouse showed similar symptoms and losses were estimated to be 15-30%. Four symptomatic plants were sampled. Macerated tissues from rotting petioles were soaked in 10 mM MgCl2 and observed under a light microscope (Nikon, Japan) at 400 x magnification. Motile, rod-shaped bacteria were observed, and 1-2 loopfuls of undiluted sample suspension were streaked onto nutrient agar (NA; Gibco, USA). After culturing at 28°C for 1 day, all samples yielded round, creamy-white colonies (0.9 mm in diameter) and from each of the four samples a pure culture was obtained (Spi1-Spi4). All isolates exhibited oxidative and fermentative metabolism of glucose (Schaad et al. 2001). They caused pitting on crystal violet pectate agar, induced maceration on potato tuber and were tested positive for phosphatase activity and indigoidine production (Lee and Yu 2006; Schaad et al. 2001). Polymerase chain reaction tests using Dickeya-specific primers 5A and 5B (Chao et al. 2006) amplified the expected amplicon (0.5 kb) in extracted DNA samples of all isolates. Identification of the strains was achieved by amplifying and sequencing fragments of the housekeeping genes gyrB, recN, dnaA, dnaJ, and dnaX (Marrero et al. 2013); the lengths of the five gene fragments analyzed were 822, 762, 720, 672, and 450 bp, respectively (accession nos. OP985528-OP985532). The five sequences were concatenated for every isolate; the resulting 3,426 bp sequences were aligned with ClustalW and found to be identical. A maximum-likelihood analysis was conducted using the 3,426-bp sequences and those of known Dickeya species' type strains. Spi1 to Spi4 clustered with D. dadantii subsp. dieffenbachiae NCPPB 2976T and D. dadantii subsp. dadantii CFBP 1269T (Fig. S2) with sequence identities of 98.4 and 98%, respectively. To fulfil Koch's Postulates, stab inoculations of the four isolates into the petioles of cutting propagated, 38-day-old S. pictus plants (3 plants per isolate) were conducted using sterile toothpicks. The amounts of bacteria used was approximately 106 cfu per toothpick; the bacterial loads were estimated by suspending the cells in 10 mM MgCl2 and spread-plating diluted suspensions on NA. Sterile toothpicks were used as control. All tested plants were sealed in plastic bags (containing wet paper towel) and kept in a growth chamber (28°C; 12-h photoperiod). After 1 day, all isolates induced soft rot symptoms resembling those observed under natural conditions in the greenhouse. Bacteria were re-isolated, and they all shared the same dnaX sequence with strains Spi1 to Spi4. This is the first report of S. pictus affected by D. dadantii in Taiwan. Further investigation is needed to determine whether Spi1-Spi4 belong to D. dadantii subsp. dieffenbachiae. Dickeya dadantii has been found infecting different aroids (Lee and Chen 2021; Lin et al. 2012). The species has also been reported in Taiwan on poinsettia (Wei et al., 2019) and philodendron (Wu et al. 2023). Because these plants are often grown closely in the same facilities, growers should be wary of D. dadantii's spread among these plants. Reduction of environmental humidity and avoiding overhead irrigation may be effective in preventing the pathogen's transmission.

Bacterial Leaf Blight of Polyscias guilfoylei Caused by a Novel Pathovar of Xanthomonas euvesicatoria.

Polyscias guilfoylei is a popular ornamental belonging to the Araliaceae family. The present study identified and characterized bacterial strains causing leaf lesions on P. guilfoylei in a nursery in Taiwan. Strains Pgu1 to Pgu5 were isolated from infected leaf tissues and Koch's postulates were fulfilled. Observation of Pgu1 under a transmission electron microscope revealed that its cells were single flagellated and rod shaped. Sequencing of Pgu1 to Pgu5's 16S ribosomal DNA showed that they belong to the genus Xanthomonas. The biochemical and physiological traits of these bacteria were determined, and many of them also resemble those of other xanthomonads. However, the strains were unable to produce yellow pigments typically found in most members of the Xanthomonas genus, even when grown on yeast dextrose calcium carbonate (YDC) agar. Physiological assays and phylogenetic analyses based on multiple loci showed that the isolates were closely associated with members of the species Xanthomonas euvesicatoria and phylogenetically distant from X. hortorum pv. hederae, the currently only known xanthomonad capable of inducing diseases on Polyscias spp. Artificial inoculation into different host plants revealed that a representative strain, Pgu1, is specialized to P. guilfoylei and perhaps other members of the Araliaceae family. Based on the results from the phylogenetic and phenotypic analyses, the present work concludes that these strains belong to a novel pathovar of X. euvesicatoria. The pathovar epithet polysciadis is proposed.

Infection Patterns of a Liberibacter Associated with Macrohomotoma gladiata, a Psyllid Feeding on Ficus microcarpa.

Almost all known Liberibacters can be transmitted by psyllids. This suggests that there is a coevolutionary relationship between these two groups of organisms. However, detailed investigation of Liberibacters and psyllids have often focused on only a few species, thus potentially limiting knowledge on Liberibacter-psyllid associations. This study investigated the infection patterns of a Liberibacter inhabiting Macrohomotoma gladiata, a psyllid species feeding on Ficus microcarpa. Comparison of the Liberibacter's near-full-length 16S rDNA sequence with those of other known Liberibacters revealed that it is closely related to Candidatus Liberibacter asiaticus. A survey of different M. gladiata populations in Taiwan using conventional and quantitative PCR (qPCR) indicated that the Liberibacter could be detected with variable frequencies in all the tested populations; the proportions of individuals carrying large Liberibacter populations also differed depending on the population. Additional analysis of a larger set of samples collected from one specific population revealed that the psyllid's gender and abdominal color were associated with Liberibacter infection density. Significantly greater proportions of individuals with a blue/green abdomen carried high Liberibacter titers. Analysis of the psyllids' body lengths revealed that body size was not affected by Liberibacter infection status and that females, particularly those with an orange abdomen, tended to be larger. The infection patterns of Liberibacter in nymph-infested and nymph-free twigs of F. microcarpa were also determined, and Liberibacter distribution was found to be associated with the presence of nymphs. These findings broaden the understanding of Liberibacter ecology in general and have implications for managing Liberibacter-associated diseases. IMPORTANCE Despite the ever-increasing interest in Liberibacter-psyllid interactions, most of the current knowledge on the subject has been established from studies focusing on species associated with crop diseases. To obtain a more holistic understanding of Liberibacter ecology, we investigated the infection patterns of a Liberibacter recently detected in Macrohomotoma gladiata, a psyllid pest of Ficus microcarpa. We showed that a Liberibacter closely related to Candidatus Liberibacter asiaticus is widely distributed across M. gladiata populations in Taiwan. The study also identified factors associated with the Liberibacter infection patterns, both in M. gladiata and in F. microcarpa. The effects of Liberibacter infection status on psyllid body sizes were also examined. Some of the patterns detected in this work were similar those found in well-known Liberibacters, while some were the opposite. The findings in this work broaden our understanding of Liberibacter ecology in general and may facilitate development of strategies for managing plant diseases.

First report of Pectobacterium carotovorum and Pectobacterium brasiliense causing bacterial soft rot of bok choy in Taiwan.

Bok choy (Brassica rapa var. chinensis) is one of the most popular leafy green vegetables in Asia (Wang et al. 2019; Zhang et al. 2014). In May 2022, disease resembling bacterial soft rot was observed in a commercial greenhouse located in Xiluo, Yunlin County, Taiwan. Affected plants exhibited maceration, primarily close to the base of the plants (Fig. S1). Almost all bok choy plants (about 1,800 plants in total) on site were symptomatic. Macerated tissues were collected from six plants. The samples were homogenized in 10 mM MgCl2 and bacteria were isolated on nutrient agar (NA) by streak plating. After 1 day of culturing at 28°C, creamy-white, round colonies were consistently grown on all the plates, and six strains (Br1 to Br6) were obtained; each isolated from a different plant. The strains were able to ferment glucose and induced maceration on potato tuber slices (Schaad et al. 2001) but could not produce indigoidine on NGM medium (NA added with glycerol and MnCl2; Lee and Yu 2006). The DNA samples of these strains were tested with Pectobacterium-specific primers Y1 and Y2 (Darrasse et al. 1994) and all samples produced the expected amplicon. To identify the isolated pathogens, 1,592-bp sequences concatenated from fragments of the leuS (452 bp), dnaX (492 bp), and recA (648 bp) genes (GenBank accession nos. OP360013-OP360021) were obtained for each strain as previously described (Portier et al. 2019). Three genotypes were detected, the sequences of strains Br1, Br2, Br4, and Br5 were identical, while strains Br3 and Br6 each belong to a different genotype. The sequence identity between Br3 and Br6 was 98.2%. The concatenated sequences (dnaX-leuS-recA), along with those of type strains from known Pectobacterium species, were subjected to maximum likelihood analysis. The reconstructed trees showed that strains Br1, Br2, Br4, and Br5 grouped with P. carotovorum CFBP2046T (Fig. S2); the sequence identity between the isolated strains and the type strain was 98.7%. Strains Br3 and Br6 clustered with P. brasiliense CFBP6617T (Fig S2); the sequence identity between CFBP6617T and Br3 and Br6 were 97.5% and 98.4%, respectively. The six strains were inoculated onto 55-day-old bok choy plants using previously described prick inoculation methods (Wei et al. 2019). Autoclaved toothpicks, each carrying 9.3 x 106- 5.6 x 107 cfu of bacteria, were used to inoculate the base of plant leaves. All six strains were tested, and each strain had three replicates. Plants in the control group were stabbed with bacteria-free toothpicks. The plants were enclosed in clear plastic bags during the assay to maintain humidity and kept in a growth chamber (27/25°C day/night; 14-h photoperiod). After 1 d, all inoculated plants produced soft rot symptoms resembling those observed in the sampling site. No noticeable differences were observed among symptoms produced by different strains. The controls were symptomless. One strain was re-isolated from each treatment group and their identity were confirmed by sequencing the dnaX gene. All re-isolated strains shared the same sequences with those of the original strains tested. This is the first report of P. brasiliense and P. carotovorum causing bacterial soft rot of bok choy in Taiwan. Importantly, the findings showed that different Pectobacterium species and genotypes could induce symptoms on a crop in the same facility at the same time, highlighting the potential complexity of interactions among different soft rot bacteria in the environment.

Expression Level of a Phenylalanine Ammonia-Lyase Gene in Poinsettia Is Negatively Correlated with Poinsettia Branch-Inducing Phytoplasma Titer.

Poinsettia is an important ornamental cultivated worldwide. Commercial poinsettias are almost universally infected with a pathogen known as the poinsettia branch-inducing phytoplasma (PoiBI), which can increase the level of branching in host plants and make the plants more desirable to consumers. Despite PoiBI's crucial role in poinsettia production, little is known about PoiBI-poinsettia interactions in regard to the pathogen's in planta population dynamics. The expression profiles of a phenylalanine ammonia-lyase gene (Euphorbia pulcherrima PAL [EpPAL]) and the PoiBI titers in poinsettia tissues were investigated. Differential gene expression analyses using quantitative PCR (qPCR) showed that EpPAL expression levels differed significantly across tissue types. The highest expression levels were detected in stems, followed by root. Lower EpPAL expression levels were detected in leaf tissues, particularly in source leaves closer to the base; the average expression level in these leaves was only one-seventh of that detected in stems. Phytoplasma concentrations in source leaves close to the base were significantly greater than the other tissue types; the average value was 7.6-fold of that detected in stem tissues, which had the lowest phytoplasma titers. A negative correlation between EpPAL expression level and PoiBI load was detected, suggesting that the products of EpPAL-associated pathways or other genes indirectly associated with EpPAL may interfere with PoiBI's growth. While additional studies are needed to validate these interpretations, the results from this work provide new insights into PoiBI-poinsettia interaction and showed that correlations between pathogen load and defense-related genes could be detected in phytoplasma-associated pathosystems. IMPORTANCE Phytoplasma-plant interactions are interesting subjects for fundamental and applicative research. Although many studies have characterized molecular interplays between these pathogens and hosts, knowledge on relationships between phytoplasmas' in planta population dynamics and host gene expression remains scarce. By using the poinsettia branch-inducing phytoplasma (PoiBI) and poinsettia as a model system, a negative correlation was observed between the expression level of a plant defense-related gene and the pathogen's titer. The findings provide potential explanations to PoiBI's distribution patterns in the plant and highlight the importance of studying phytoplasma-plant interactions in regard to the pathogen's population dynamics in other pathosystems.

First report of Dickeya dadantii causing bacterial soft rot of Thaumatophyllum bipinnatifidum in Taiwan.

Philodendrons are important foliage ornamentals planted worldwide (Chen et al. 2010). In November 2021, soft rot symptoms were observed on Philodendron selloum (now known as Thaumatophyllum bipinnatifidum; Sakuragui et al. 2018) grown in a nursery in Taichung, Taiwan. On symptomatic plants, the petioles were macerated; leaf lesions were also found on some plants (Figure S1). About 60% of the plants on site were symptomatic; these plants tended to cluster together. Four plants were sampled. Infected tissues were soaked and cut into pieces in 10 mM MgCl2 (using scalpels); undiluted samples were streak-plated onto nutrient agar (NA) and grown for 24 h at 28°C. Translucent, creamy-white colonies were isolated from all of the tissues examined, and 4 isolates, PHIL1 to PHIL4, were obtained (each from a different plant). All isolates exhibited typical phenotypes of bacteria belonging to Dickeya; they could cause maceration symptoms on potato slices, ferment glucose and produce phosphatase (Schaad et al. 2001); they could also produce indigoidine on NGM medium (NA added with glycerol and MnCl2; Lee and Yu. 2006). Polymerase chain reactions using Dickeya-specific primers 5A and 5B (Chao et al. 2006) amplified the expected amplicon in all 4 isolates. The 16S rDNA of PHIL1 to PHIL4 were amplified using primer pair 27f/1492r (Lane 1991) and the amplicons were sequenced; all 4 isolates shared the same 1,395-bp sequence (accession nos. ON203122, ON479664-ON479666). Among the strains belonging to known species (in GenBank), PHIL1 to PHIL4 shared the highest sequence identity (99.93%) with D. dadantii 3937; they also shared 98.78% sequence identity with D. dadantii CFBP 1269T. Multilocus sequence analysis (MLSA) targeting fragments of PHIL1 to PHIL4's dnaA (720 bp), dnaJ (672 bp), dnaX (450 bp), gyrB (822 bp), and recN (762 bp) genes (Marrero et al. 2013) were conducted. The five-gene concatenated sequences (3,426 bp) of the 4 isolates (accession nos. ON227444-ON227448, ON494509-ON494523) were identical. A maximum-likelihood phylogenetic analysis including these sequences and those of type strains of other known Dickeya species revealed that PHIL1 to PHIL4 clustered with strains belonging to D. dadantii (Figure S2). Koch's postulates were fulfilled with an inoculation test conducted on T. bipinnatifidum (17 cm in aboveground height; 7-months-old). Stab inoculation using sterile toothpicks was conducted on petioles. Three plants were tested for each isolate and 2 petioles were inoculated for each plant; all 4 isolates were included in the assay. The pathogen loads inoculated were quantified by the spread plate method and were 3.22 - 4.81 x 107 colony forming units. Three plants were stabbed with bacteria-free toothpicks, serving as controls. All plants were bagged post inoculation and kept in a growth chamber (28°C; 14 h light). After 72 h, all of the inoculated petioles exhibited symptoms resembling those observed in the nursery. Bacteria were re-isolated from the symptomatic tissues (one isolate from each treatment), and all of their five-gene concatenated sequences were the same as those of PHIL1 to PHIL4. This is the first formal report of the occurrence of D. dadantii infecting T. bipinnatifidum in Taiwan. Studies have shown that D. dadantii could affect other Araceae plants in Taiwan (Lee and Chen 2021). Since different Araceae ornamentals are often planted together in gardens and nurseries, growers should be aware of potential transmission of D. dadantii among them.

First report of bacterial soft rot on Epipremnum aureum caused by Pectobacterium aroidearum in Taiwan.

Pothos (Epipremnum aureum) is an Araceae foliage plant with great ornamental values, which has long been enjoyed by consumers (Chen et al. 2010). In September 2021, pothos showing soft rot symptoms were found in 2 nurseries in Taichung, Taiwan. The petioles of the infected plants were macerated; some lesions extended to the leaves (Figure S1). The disease incidence was 50% in one nursery and 37.5% in the other; two and three plants were respectively collected from the two sites. Macerated tissues were homogenized in 10 mM MgCl2 and the samples were observed microscopically without dyeing. Motile, rod-shaped bacteria were observed in the samples, and the bacteria were isolated onto nutrient agar (NA) and grown at 28°C for 2 days. Fast-growing, round, creamy colonies were isolated from all 5 plants. One strain was isolated from each plant and the strains were named Ea1 to Ea5. The bacteria could ferment glucose and induce maceration on potato tuber slices (Schaad et al. 2001), but did not produce indigoidine on NGM medium (Lee and Yu 2006) and were tested negative for phosphatase activity (Schaad et al. 2001). The bacteria's DNA samples were tested using primers specific to Pectobacterium (Y1/Y2; Darrasse et al. 1994). The expected 434-bp amplicon was amplified in all five strains. Multilocus sequence analysis was conducted as previously described (Portier et al. 2019). A concatenated sequence (1,592 bp) comprising partial dnaX (492 bp), leuS (452 bp) and recA (648 bp) sequences was obtained for each strain. Two genotypes were detected among the strains; Ea1 and Ea2 belonged to one genotype (i.e., they had identical sequences), while Ea3, Ea4 and Ea5 belonged to the other (GenBank accession nos. OK416015-OK416020). Phylogenetic analysis was conducted using these data and those of representative strains of known Pectobacterium species (Klair et al. 2022). A maximum-likelihood tree showed that Ea1 to Ea5 clustered with P. aroidearum CFBP8168T (Figure S2). Sequence comparison (Table S1) showed that the similarity between the two genotypes' concatenated sequences was 99.1% (Ea1 vs. Ea3; 1,578/1,592 bp); Ea1 and Ea3 shared 99.2% and 99.3% sequence similarity with P. aroidearum CFBP8168T, respectively. The sequences obtained in this work were searched against GenBank and all of their top hits were those of strains belonging to P. aroidearum (supplementary information). Koch's Postulates were fulfilled by stab inoculating cutting-propagated pothos (8-cm tall) using toothpicks carrying bacteria grown on NA. The pathogen loads used were estimated by suspending cells (attached to individual toothpicks) in 10 mM MgCl2 and spread-plating them onto NA (after dilution); the loads were 5.5 x 106 - 2.2 x 107 CFU. Three plants were inoculated for each strain (3 petioles per plant). Control plants were stabbed with sterile toothpicks. Each plant was then bagged and placed in a growth chamber (28°C; 14 h light). After 24 h, all inoculated plants produced symptoms resembling those found in the nurseries, and the controls did not. For every treatment group, a strain was re-isolated onto NA; each of them shared the same recA sequence with the original strain inoculated. This is first report of P. aroidearum causing pothos soft rot in Taiwan. Local nurseries often grow pothos and other Araceae plants together in humid areas. Since other Araceae species are also known to be susceptible to P. aroidearum (Xu et al. 2020), growers should be cautious of the pathogen's spread across hosts.

Spectroscopic Study of the B 1Π State of NaH.

In this study, the B 1Π excited state of NaH has been experimentally studied for the first time. Pulsed laser-induced fluorescence excitation spectroscopy was used to investigate the B 1Π electronic state of NaH. A total of 48 ro-vibronic transitions were observed, including within the B-X (0-0) and B-X (0-1) transition bands. Only one B-state vibrational level was identified, and a series of PQR lines, with eight e-parity and eight f-parity sublevels (v' = 0, J' = 1-8), were assigned. The level assignment was supported by a comparison of the experimental line positions with the ab initio calculations, the dispersed laser-induced fluorescence spectrum of the NaH B 1Π â†’ X 1∑+ emission, and the V-type optical-optical double resonance spectra. The Dunham-type coefficients, the mean internuclear distance, the harmonic vibrational frequency ω, and the dissociation energies D 0 and D e of the B 1Π state were determined.

First report of a 'Candidatus Phytoplasma aurantifolia'-related strain (16SrII-V) associated with phyllody, virescence, and shoot proliferation of sweet William (Dianthus barbatus) in Taiwan.

The sweet William (Dianthus barbatus) is an ornamental belonging to the Caryophyllaceae family; the species produces clusters of flowers that comes in various colors and is grown commonly as garden plants (Lim 2014). In February 2021, sweet Williams showing symptoms typical of phytoplasma diseases were found in a garden located in Wufeng District, Taichung, Taiwan (24°04'37.6"N 120°43'20.4"E). Infected plants exhibited virescence and phyllody symptoms and produced an abnormal number of new shoots from the base of the flowers/flower-like structures (Figure S1) as well as the base of the plants. Among the fifteen plants grown in the area, two exhibited such symptoms. The two symptomatic plants, along with five symptomless plants were sampled. Two flower-like structures were collected from each of the symptomatic plants, and two flower samples were collected for each symptomless plant (Figure S2). Total DNA were extracted from each sample using the Synergy 2.0 Plant DNA Extraction Kit (OPS Diagnostics) and subjected to diagnostic PCR using primers P1/P7 (Schneider et al. 1995). All four symptomatic samples produced a 1.8-kb amplicon and the ten symptomless samples did not. The amplification products were diluted fifty-fold and used in a second round of PCR using primers R16F2n/R16R2 (Gundersen and Lee 1996). Again, only the symptomatic samples produced an expected 1.25-kb amplicon. A sample was selected for each plant and the PCR products from the first round of PCR were cloned using the pGEM-T Easy Vector System (Promega Inc.) and sequenced (three clones per sample). Fragments of the 16S rRNA gene (1,248 bp; GenBank accession: MW788688) were analyzed using iPhyClassifier (https://plantpathology.ba.ars.usda.gov/cgi-bin/resource/iphyclassifier.cgi). Sequences obtained from the two infected plants were identical, and were classified to the 16SrII-V subgroup with similarity coefficients of 1.0; they also shared 98.6% similarity with the sequence of a 'Candidatus Phytoplasma aurantifolia' reference strain (accession: U15442). BLASTn results indicated that the 16S rRNA gene sequences detected were identical to those of 16SrII-V phytoplasmas affecting mungbean (accession: MW319764), lilac tasselflower (accession: MT420682), peanut (accession: JX403944) and green manure soybean (accession: MW393690) found in Taiwan. To corroborate the above results, 16SrII group-specific primers were used to conduct nested and semi-nested PCR targeting the pathogen's 16S rRNA gene (outer primers: rpF1C/rp(I)R1A; inner primers: rp(II)F1/rp(II)R1; Martini et al. 2007) and immunodominant membrane protein gene (imp; outer primers: IMP-II-F1/IMP-II-R1; inner primers: IMP-II-F2/IMP-II-R1; Al-Subhi et al. 2017). In both assays, the symptomatic samples produced the expected amplicons and the symptomless samples did not. The coding sequence of the imp gene (519 bp; accession: MW755353) was the same among all symptomatic samples, and shared 100% identity with that of the peanut witches'-broom phytoplasma (16SrII; accession: GU214176). To our knowledge, this is the first report of a 16SrII-V phytoplasma infecting sweet Williams in Taiwan. Since 16SrII-V phytoplasmas have also been found infecting mungbeans and peanuts in Taiwan (Liu et al. 2015), the findings here suggest that by serving as a natural host in the field, the sweet William may potentially contribute to the spread of 16SrII-V phytoplasmas to food crops.

Variability of Phytoplasma Infection Density in Poinsettia and Evaluation of its Association with the Level of Branching in Host Plants.

It has long been established that phytoplasma infection is the cause of the free-branching phenotype in poinsettia. However, relatively little is known about the ecology of the pathogen in planta. The present study evaluated the infection pattern of poinsettia branch-inducing phytoplasma (PoiBI) and its association with the poinsettia phenotype during cutting propagation. The presence of this pathogen in the poinsettia variety Luv U Pink was determined using PCR and sequence analysis. The infection density of PoiBI in distinct tissue types of different plant segments were then determined using quantitative PCR coupled with plasmid-based standard curves. Both vegetative-stage and flowering-stage plants were tested. The results showed that, despite being considerably variable among plants, the infection densities of PoiBI tend to be higher in source leaves located in the lower parts of the plant. The densities were consistently lower in tissues located at the top of the plants, regardless of the tissue type. Analysis of the infection densities among samples collected from six stock plants used in commercial production also revealed significantly different levels of PoiBI load. An association between PoiBI infection density in the stock plants and the level of branching in cutting-propagated plants (derived from the stock plants) was also observed; stock plants with low infection densities tended to produce smaller proportions of plants exhibiting higher degrees of branching both before and after pinching. These data suggest that uneven distribution of PoiBI within and among stock plants may lead to the production of cuttings with variable phytoplasma densities which may, in turn, affect the phenotypic uniformity of the plants produced. Overall, findings from the present work add to the understanding of PoiBI's ecology and could provide implications to commercial poinsettia production.

First report of Pectobacterium aroidearum causing bacterial soft rot of carrot in Taiwan.

Carrot (Daucus carota) is an important root vegetable planted and consumed worldwide (Stein and Nothnagel 1995). In June 2020, carrots (cv. New Kuroda) showing soft rot symptoms were observed in a 600 sqft plot located in Pitou, Changhua, Taiwan (23°54'00.9"N, 120°28'37.3"E; with around 400 plants). About 10% of the plants on site had similar symptoms; infected taproot tissues were macerated (Figure S1) and emitted a foul odor. In most cases, the peels above the rotten tissues remain intact. Two infected plants were brought to the lab. Macerated tissues were suspended in water and examined under a microscope at 600X (without staining). Rod, motile bacteria were observed in all of the samples and the bacteria were isolated onto nutrient agar. Three bacterial strains were obtained from two taproots; strain Car1 was isolated from one plant, and strains Car2 and Car3 were isolated from the other. Their colonies were translucent, round and convex. All isolates could ferment glucose and induce soft rot symptoms on potato tuber slices (Schaad et al. 2001). They were not able to produce indigoidine on yeast dextrose calcium carbonate agar and were tested negative for phosphatase activity (Schaad et al. 2001). The 16S rDNA of Car1 to Car3 were amplified using primers 27F/1492R (Lane 1991). Cloning and sequencing of their 16S rDNA (GenBank accession no. MT889640) revealed that their sequences shared 99.9% identity (1,463/1,464 bp) with that of Pectobacterium aroidearum CFBP 8168T (SCRI 109T; GenBank accession no. NR_159926.1). Multilocus sequence analyses targeting the three isolates' dnaX, leuS and recA genes were conducted. The concatenated sequences (1,596 bp) of Car1 to Car3 and those included in a previous work (Portier et al. 2019) were subjected to phylogenetic analysis. The sequences of Car1 to Car3 were identical (GenBank accession nos. MT892671-MT892673). A maximum-likelihood tree showed that the three isolates belonged to the same clade as P. aroidearum CFBP 8168T (GenBank accession nos. MK516971, MK517115 and MK517259; Figure S2). For the concatenated sequences analyzed, the identity between P. aroidearum CFBP 8168T and our three isolates was 99.4% (1,587/1,596 bp). The pathogenicity of these isolates was determined by inoculating the bacteria into carrot (cv. Xiangyang No.2) taproots. Strains Car1 to Car3 were grown on NA for 48 h (28 °C) and cell suspensions with OD600 values of 0.3 (2.4 x 108 CFU/ml; in water) were prepared. The suspensions of each strain (100 µl) were loaded into 200 µl pipette tips. The tips were then pierced into intact carrot taproots (2.4 cm deep), ejected and left on the plants (one tip per plant). Three taproots were tested for each strain. Tips loaded with 100 µl of water were used for the controls (three replicates). The plants were incubated in a sealed plastic container kept in a growth chamber set at 28°C. After 48 h, all of the inoculated taproots produced soft rot symptoms resembling those observed in the field and plants in the control group did not. Bacteria were re-isolated from macerated tissues of the artificially infected plants and found to share the same leuS sequence with Car1 to Car3. Occurrences of carrot soft rot in Taiwan have only been attributed to Dickeya spp. (Erwinia chrysanthemi) in previous studies (Hsu and Tzeng 1981). The present study is the first report of P. aroidearum infecting carrots in Taiwan. The findings may add to our understanding of the diversity of soft rot pathogens affecting carrot production in Taiwan.

Observation of the shallow 2 Π 1 state of NaH.

The 2 1Π state of NaH has been observed up to the last bound vibrational level using pulsed optical-optical double resonance fluorescence depletion spectroscopy. A total of 20 rovibrational energy levels ( v = 2-4 and J = 1-9) were assigned to this electronic state by means of comparing the successive rovibrational spectra to the eigenvalues of the ab initio potential energy curve. The decrease of background fluorescence near the atomic asymptotic limit Na(3d) + H(1s) is an indication of reaching the dissociation limit of the NaH 2 1Π state. Unobserved rovibrational levels ( v = 0 and 1) are due to poor Franck-Condon overlap of 2 1Π â† A 1Σ+ transition within the accessible rovibrational levels of intermediate A 1Σ+ state of this work.

Genetic variation and potential coinfection of Wolbachia among widespread Asian citrus psyllid (Diaphorina citri Kuwayama) populations.

Wolbachia can profoundly influence the survival, reproduction, and defenses of insect hosts. These interactions could potentially be harnessed for managing pests or insect-transmitted diseases. Diaphorina citri Kuwayama is a phloem-feeding pest capable of transmitting the putative causal agent of citrus greening, Candidatus Liberibacter asiaticus (CLas). Like many insects, D. citri is also infected with Wolbachia (wDi). Recent studies indicate that the relative abundance of wDi could be associated with the abundance of CLas, and that wDi may contribute to regulating expression of phage lytic cycle genes in CLas, suggesting the need for better understanding of wDi biology in general. This study investigated the genetic diversity of wDi among D. citri in populations spanning eleven countries and two U.S. territories. Six Wolbachia genes, wsp, coxA, fbpA, ftsZ, gatB, and hcpA, were sequenced and compared across samples. Two prevalent wDi strains were identified across the samples, and screening of clone libraries revealed possible coinfection of wDi strains in specific populations. D. citri mitochondrial cytochrome oxidase subunit I gene (mtCOI) were more divergent between D. citri populations that were infected with different wDi strains or had different infection statuses (single infection vs. coinfection). While we could not eliminate the possibility that maternal transmission may contribute to such patterns, it is also possible that wDi may induce cytoplasmic incompatibility in their host. These findings should contribute to the understanding of wDi population ecology, which may facilitate manipulation of this endosymbiont for management of citrus greening disease worldwide.

Observation of double-well potential of NaH C 1Σ+ state: Deriving the dissociation energy of its ground state.

Vibrational levels (v = 6-42) of the NaH C 1Σ+ state including the inner and outer wells and the near-dissociation region were observed by pulsed optical-optical double resonance fluorescence depletion spectroscopy. The absolute vibrational quantum number is identified by comparing the vibrational energy difference of this experiment with the ab initio calculations. The outer well with v up to 34 is analyzed using the Dunham expansion and a Rydberg-Klein-Rees (RKR) potential energy curve is constructed. A hybrid double-well potential combined with the RKR potential, the ab initio calculation, and a long-range potential is able to describe the whole NaH C 1Σ+ state including the higher vibrational levels (v = 35-42). The dissociation energy of the NaH C 1Σ+ state is determined to be De(C) = 6595.10 ± 5 cm-1 and then the dissociation energy of the NaH ground state De(X) = 15 807.87 ± 5 cm-1 can be derived.