Contribution of Native Plasmids of Pantoea vagans C9-1 to Epiphytic Fitness and Fire Blight Management on Apple and Pear Flowers and Fruits.

Pantoea vagans C9-1 (C9-1) is a biological control bacterium that is applied to apple and pear trees during bloom for suppression of fire blight, caused by Erwinia amylovora. Strain C9-1 has three megaplasmids: pPag1, pPag2, and pPag3. Prior bioinformatic studies predicted these megaplasmids have a role in environmental fitness and/or biocontrol efficacy. Plasmid pPag3 is part of the large Pantoea plasmid (LPP-1) group that is present in all Pantoea spp. and has been hypothesized to contribute to environmental colonization and persistence, while pPag2 is less common. We assessed fitness of C9-1 derivatives cured of pPag2 and/or pPag3 on pear and apple flowers and fruit in experimental orchards. We also assessed the ability of a C9-1 derivative lacking pPag3 to reduce populations of E. amylovora on flowers and disease incidence. Previously, we determined that tolerance to stresses imposed in vitro was compromised in derivatives of C9-1 lacking pPag2 and/or pPag3; however, in this study, the loss of pPag2 and/or pPag3 did not consistently reduce the fitness of C9-1 on flowers in orchards. Over the summer, pPag3 contributed to survival of C9-1 on developing apple and pear fruit in two of five trials, whereas loss of pPag2 did not significantly affect survival of C9-1. We also found that loss of pPag3 did not affect C9-1's ability to reduce E. amylovora populations or fire blight incidence on apple flowers. Our findings partially support prior hypotheses that LPP-1 in Pantoea species contributes to persistence on plant surfaces but questions whether LPP-1 facilitates host colonization.

First report of stem blight caused by Diaporthe eres on highbush blueberry (Vaccinium corymbosum) in Michigan.

The U.S. is the world's leading producer of highbush blueberries (Vaccinium corymbosum L.), and Michigan is ranked in the top five production states (USDA NASS, 2022). In June and July of 2021, 268 blueberry stem blight samples were collected for a pathogen survey across 22 total fields in Van Buren and Ottawa counties in Michigan. Current season stems with symptoms of necrosis and wilting were collected. Stems were cut just below the necrotic area and cross-sections (2-3 mm long) were surface disinfested in 10% bleach for 1 min, rinsed twice in sterile distilled water, and dried on sterile paper towels. Stem cross-sections were plated onto potato dextrose agar (PDA) amended with 100 µg/ml streptomycin sulfate and 50 µg/ml ampicillin. Plates were incubated at 21°C under a 12-h photoperiod for 5-6 days. Outgrowing fungi with morphology similar to Diaporthe spp. were transferred to new PDA plates 2 consecutive times after 7 days of similar incubation to ensure single colony isolation. After 7 days, colonies consisted of white and light brown mycelia that were mostly flat, with some isolates that had partially raised mycelia towards the center of the plate. After 3-4 weeks, colonies turned brown and gray and produced dark brown pycnidia. Aseptate, hyaline, fusiform to ellipsoid, biguttulate alpha conidia measuring 5.4 to 7.6 x 2.6 to 3.7 µm (n = 60) were produced. No beta conidia were observed. In total, 3 isolates, representing 3 different farms (37-95 km apart) and cultivars ('Duke', 'Jersey', and 'Bluecrop'), as well as 2 counties, were identified as Diaporthe through colony morphology (Gomes et al. 2013, Udayanga et al. 2014). Amplification and subsequent Sanger sequencing were performed for the internal transcribed spacer (ITS) region and portions of the translation elongation factor (TEF) 1-α, ß-tubulin (TUB), and histone H3 (HIS) genes using primers ITS5/ITS4 (White et al. 1990), EF1-728F/EF1-986R (Carbone and Kohn 1999), T1/Bt-2b (Glass and Donaldson 1995), and CYLH3F/H3-1b (Glass and Donaldson 1995), respectively. Representative sequences were deposited in NCBI GenBank (accession no. OQ507870-OQ507872 for ITS, and OQ550272-OQ550278 for TEF, HIS, and TUB). BLASTn results revealed 97-100% identity for all 4 genes across other established D. eres isolates reported in Gomes et al. (2013). For example, JMK047 had 99.8% (577/578 bp), 99.7% (327/328 bp), 100% (701/701 bp), and 100% (439/439 bp) homology with ITS, TEF, TUB, and HIS sequences, respectively, of D. eres CBS 439.82 (accession no. KC343090, KC343816, KC344058, KC343574). Koch's Postulates were fulfilled via pathogenicity tests on 2-year-old potted 'Blueray' plants with 2 isolates. Stems were surface sterilized with 1% bleach then 8-mm long pieces of bark were removed using a sterile razor blade to expose the cambium. Plugs of sterile PDA (negative control) or mycelia from 7-day old cultures on PDA (5-mm diameter) were placed onto the cambium layer and sealed with Parafilm. Six stems on unique plants were inoculated per treatment. Plants were grown in a 20.5°C greenhouse with a 14-hr photoperiod. After 3 weeks, the stems inoculated with D. eres isolates showed similar stem blight symptoms to those observed in the field while control stems remained healthy. Re-isolation and sequencing of the ITS region of 3 replicates per treatment with the protocol described above confirmed symptoms correlated with D. eres isolates. This is the first report of D. eres associated with stem blight of highbush blueberry in Michigan, and the second report in the U.S. (Lombard et al. 2014). Increasing prevalence of D. eres in U.S. blueberries may affect disease management programs. References Carbone, I., and Kohn, L. M. 1999. Mycologia 91:553. 10.1080/00275514.1999.12061051. Glass, N. L., and Donaldson, G. C. 1995. Appl. Environ. Microbiol. 61:1323. 10.1128/aem.61.4.1323-1330.1995. Gomes, R. R., et al. 2013. Persoonia 31:1. 10.3767/003158513x666844. Lombard, L., et al. 2014. Phytopathol. Mediterr. 51(2):287. 10.14601/Phytopathol_Mediterr-14034. Udayanga, D., Castlebury, L. A., Rossman, A. Y., Chukeatirote, E., and Hyde, K. D. 2014. Fungal Divers. 67:203-229. 10.1007/s13225-014-0297-2. USDA NASS. 2022. Noncitrus Fruits and Nuts 2021 Summary. White, T. J., et al. 1990. Page 315 in: PCR Protocols: A Guide to Methods and Applications. Academic Press, Inc., San Diego, California, USA.

Strength in Numbers: Density-Dependent Volatile-Induced Antimicrobial Activity by Xanthomonas perforans.

For most of the 20th century, Xanthomonas euvesicatoria was the only known bacterium associated with bacterial spot of tomato in Florida. X. perforans quickly replaced X. euvesicatoria, mainly because of production of three bacteriocins (BCNs) against X. euvesicatoria; however, X. perforans outcompeted X. euvesicatoria even when the three known BCNs were deleted. Surprisingly, we observed antimicrobial activity against X. euvesicatoria in the BCN triple mutant when the triple mutant was grown in Petri plates containing multiple spots but not in Petri plates containing only one spot. We determined that changes in the headspace composition (i.e., volatiles) rather than a diffusible signal in the agar were required for induction of the antimicrobial activity. Other Xanthomonas species also produced volatile-induced antimicrobial compounds against X. euvesicatoria and elicited antimicrobial activity by X. perforans. A wide range of plant pathogenic bacteria, including Clavibacter michiganensis subsp. michiganensis, Pantoea stewartii, and Pseudomonas cichorii, also elicited antimicrobial activity by X. perforans when multiple spots of the species were present. To identify potential antimicrobial compounds, we performed liquid chromatography with high-resolution mass spectrometry of the agar surrounding the spot in the high cell density Petri plates where the antimicrobial activity was present compared with agar surrounding the spot in Petri plates with one spot where antimicrobial activity was not observed. Among the compounds identified in the zone of inhibition were N-butanoyl-L-homoserine lactone and N-(3-hydroxy-butanoyl)-homoserine lactone, which are known quorum-sensing metabolites in other bacteria.

Whole genome sequences reveal the Xanthomonas perforans population is shaped by the tomato production system.

Modern agricultural practices increase the potential for plant pathogen spread, while the advent of affordable whole genome sequencing enables in-depth studies of pathogen movement. Population genomic studies may decipher pathogen movement and population structure as a result of complex agricultural production systems. We used whole genome sequences of 281 Xanthomonas perforans strains collected within one tomato production season across Florida and southern Georgia fields to test for population genetic structure associated with tomato production system variables. We identified six clusters of X. perforans from core gene SNPs that corresponded with phylogenetic lineages. Using whole genome SNPs, we found genetic structure among farms, transplant facilities, cultivars, seed producers, grower operations, regions, and counties. Overall, grower operations that produced their own transplants were associated with genetically distinct and less diverse populations of strains compared to grower operations that received transplants from multiple sources. The degree of genetic differentiation among components of Florida's tomato production system varied between clusters, suggesting differential dispersal of the strains, such as through seed or contaminated transplants versus local movement within farms. Overall, we showed that the genetic variation of a bacterial plant pathogen is shaped by the structure of the plant production system.

Epidemiology, diversity, and management of bacterial spot of tomato caused by Xanthomonas perforans.

Tomato is an important crop grown worldwide. Various plant diseases cause massive losses in tomato plants due to diverse biotic agents. Bacterial spot of tomato (BST) is a worldwide disease that results in high losses in processed and fresh tomato. Xanthomonas perforans, an aerobic, single-flagellated, rod-shaped, Gram-negative plant pathogenic bacterium, is one of the leading causes of BST. Over the past three decades, X. perforans has increasingly been reported from tomato-growing regions and became a major bacterial disease. X. perforans thrives under high humidity and high temperature, which is commonplace in tropical and subtropical climates. Distinguishing symptoms of BST are necrotic lesions that can coalesce and cause a shot-hole appearance. X. perforans can occasionally cause fruit symptoms depending on disease pressure during fruit development. Short-distance movement in the field is mainly dependent on wind-driven rain, whereas long distance movement occurs through contaminated seed or plant material. X. perforans harbors a suite of effectors that increase pathogen virulence, fitness, and dissemination. BST management mainly relies on copper-based compounds; however, resistance is widespread. Alternative compounds, such as nanomaterials, are currently being evaluated and show high potential for BST management. Resistance breeding remains difficult to attain due to limited resistant germplasm. While the increased genetic diversity and gain and loss of effectors in X. perforans limits the success of single-gene resistance, the adoption of effector-specific transgenes and quantitative resistance may lead to durable host resistance. However, further research that aims to more effectively implement novel management tools is required to curb disease spread. KEY POINTS: • Xanthomonas perforans causes bacterial spot on tomato epidemics through infected seedlings and movement of plant material. • Genetic diversity plays a major role in shaping populations which is evident in loss and gain of effectors. • Management relies on copper sprays, but nanoparticles are a promising alternative to reduce copper toxicity.

Assessing Changes and Associations in the Xanthomonas perforans Population Across Florida Commercial Tomato Fields Via a Statewide Survey.

Before 1991, Xanthomonas euvesicatoria was the causal agent of bacterial spot of tomato in Florida but was quickly replaced by X. perforans. The X. perforans population has changed in genotype and phenotype despite lack of a clear selection pressure. To determine the current Xanthomonas population in Florida, we collected 585 Xanthomonas strains from 70 tomato fields, representing 22 farms across eight counties, in the Florida tomato production region. Strains were isolated from 23 cultivars across eight seed producers and were associated with eight transplant facilities during the fall 2017 season. Our collection was phenotypically and genotypically characterized. Only X. perforans was identified, and all strains except one (99.8%) were tolerant to copper sulfate and 25% of strains were resistant to streptomycin sulfate. Most of the strains (99.3%) that were resistant to streptomycin sulfate were sequence type 1. The X. perforans population consisted of tomato races 3 (8%) and 4 (92%) and all three previously reported sequence types, ranging from 22 to 46% frequency. Approximately half of all strains, none of which were sequence type 2, produced bacteriocins against X. euvesicatoria. Effector profiles were highly variable among strains, which could impact the strains' host range. The effector xopJ4, which was previously thought to be conserved in X. perforans tomato pathogens, was absent in 19 strains. Nonmetric multidimensional scaling and network analyses show how strains and strain traits were associated with production system variables, including anonymized farms and transplant facilities. These analyses show that the composition of the Florida X. perforans population is diverse and complex.