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

Abstract

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.