First Report of Bacterial Wilt Disease Caused by Ralstonia solanacearum on Southern Highbush Blueberries (Vaccinium corymbosum interspecific hybrids) in Georgia U.S.A.

Abstract

Members of the Ralstonia solanacearum (Rs) species complex have recently been reported to cause bacterial wilt on southern highbush (SHB) blueberries in Florida (Norman et al. 2018), a disease first reported on blueberry (northern highbush; Vaccinium corymbosum) in New Jersey (Patel et al. 2013). SHB blueberries are widely grown in the southern United States, and SHB cultivars represent the majority of the blueberry acreage in Georgia - the U.S. state with the largest blueberry acreage (NASS 2022). In Fall 2020, three-year old SHB plants (cv. ‘Indigocrisp’) showing leaf bronzing, wilting, and dieback were collected from two field sites in Clinch County, GA. At these locations, numerous plants were rapidly dying, with symptoms appearing to have spread down rows. Plant material tested positive using the ImmunoStrip® for Rs (Agdia, Inc., Elkhart, IN). From one location, the remaining sample was submitted to USDA-APHIS Select Agent Services who determined that Rs was present but a select agent (Rs Race 3, Biovar 2) was not. Following this, six adjacent, symptomatic SHB plants were collected from the same field location. These plants tested positive using the ImmunoStrip® for Rs, and red-pigmented mucoid colonies typical of Rs formed within 48 h at 28°C on triphenyltetrazolium chloroide (TZC) isolation medium (Kelman 1954). DNA was extracted from pure Rs cultures using the cetyltrimethylammonium bromide (CTAB) method (Doyle and Doyle 1987) and tested using polymerase chain reaction (PCR). Primers pairs AMB013/AMB014 (Fegan and Prior 2005) and ENDO-F/ENDO-R (Ji et al. 2007) were used to amplify 558 nt and 843 nt portions of the 16S rRNA region and Rs endoglucanase gene, respectively. Resulting amplicons were purified using an E.Z.N.A.® Cycle Pure Kit (Omega Bio-Tek, Norcross, GA), Sanger sequenced in both directions (Eurofins Genomics, Louisville, KY), and compared to publicly available Rs sequences in Genbank. The 16 rRNA sequence from all obtained isolates (accession ON938207) had 100% identity to Rs strain CFBP2957 (FP885897), while the endoglucase sequence (ON938206) had 100% identity to phylotype IIa, sequevar 5 Rs strain CIP-426 (MF461810) and phylotype IIa, sequevar 39 Rs strain 19-058 (MT314067), among others. To fulfill Koch’s postulates, an isolate (‘Ral21-1’) was grown on TZC medium for 48 h at 28°C and suspended in 8.5 g/L NaCl at 1 x 108 CFU/ml. Five young, tissue cultured SHB plants (cv. ‘Kestrel’) in 25 cm pots were drenched with 50 ml of Rs suspension. For six weeks, plants were maintained in the greenhouse at 21-32°C. Typical bacterial wilt symptoms (leaf bronzing/scorching) developed in all inoculated plants, and infections were confirmed using Immunostrip®. Rs was reisolated and confirmed via PCR and sequencing as previously described. While Ralstonia has been known to cause disease on numerous crops in Georgia, this represents a first report of bacterial wilt in Georgia blueberries. Relative to rabbiteye blueberries (V. virgatum), recent reports suggest that SHB are much more susceptible to bacterial wilt (Conner et al. 2022). Accordingly, given the transition from rabbiteye to SHB within Georgia’s blueberry production region over the past two decades and the ability of Rs to spread easily in water, soil, or via infected plant material, the presence of this disease within the state represents a significant threat to blueberry production. Additional characterization of Ralstonia isolates from Georgia may help assess the risk of future outbreaks.