Thermotolerant plant growth-promoting bacteria enhance growth and nutrient uptake of lettuce under heat stress conditions by altering stomatal movement and chlorophyll fluorescence.

This study investigates the effects of selected PGPB on lettuce growth performance under heat-stress conditions. Bacterial plant growth-promoting potentials have been characterized and identified successfully in ongoing studies. Based on in vitro plant growth-promoting potential, the top five bacteria were ranked and identified as Acinetobacter sp. GRB12, Bacillus sp. GFB04, Klebsiella sp. LFB06, Klebsiella sp. GRB10, and Klebsiella sp. GRB04. They were mixed to inoculate on lettuce (Lactuca sativa L.) in temperature-controlled greenhouses. Another in-vivo chamber experiment was conducted by using Bacillus sp. GFB04 and Klebsiella sp. GFB10. Plant physiological traits (chlorophyll fluorescence and transpiration) and nutrient contents were measured at harvest, along with growth, development, and yield component analyses. Uninoculated plants under heat-stress condition showed poor growth performance. In contrast, plants with PGPB inoculation showed improved growth under heat-stress conditions, as the uptake of nutrients was facilitated by the symbionts. Inoculation also improved lettuce photosystem II efficiency and decreased total water use under heat stress. In conclusion, the current study suggests that PGPB inoculation successfully enhances lettuce heat-tolerance. PGPB application could potentially help improve sustainable production of lettuce with less fertilization under increasing temperatures. Supplementary Information: The online version contains supplementary material available at 10.1007/s12298-024-01470-5.

First Report of Neopestalotiopsis rosae Causing Leaf Blight and Crown Rot on Strawberry in Taiwan.

For the past 30 years, the most predominant strawberry cultivar in Taiwan has been 'Taoyuan No. 1', which produces fruit with rich flavor and aroma but is highly susceptible to anthracnose (Chung et al. 2019). Because epidemics of anthracnose became more destructive, farmers switched to an anthracnose-tolerant cultivar 'Xiang-Shui' (~50% and ~80% of the cultivation area in 2018 and 2019, respectively). Since 2018, severe leaf blight and crown rot symptoms have been observed all year in 'Xiang-Shui' in Miaoli, Nantou, Hsinchu, Taipei, Taoyuan, and Chiayi Counties. The disease became more prevalent and severe during 2019 to 2020 and caused up to 30% plant loss after transplanting. Symptoms appeared as brown necrotic lesions with black acervuli on leaves, slightly sunken dark-brown necrosis on stolons, and sunken reddish-brown necrosis on fruit. The diseased crown tissue showed marbled reddish-brown necrosis with a dark-brown margin, and plants with severe crown rot usually showed reddish-brown discoloration on leaves (the leaves initially turned reddish-brown between the veins and could become entirely scorched at later stages). To isolate the causal agent, small fragments of diseased leaves, crowns, stolons, and fruits were surface-disinfested with 0.5% sodium hypochlorite for 30 seconds, rinsed with sterile water then placed on 1.5% water agar. Single hyphal tips extended from tissues were transferred to potato dextrose agar and cultured for 7 days at 25°C under a 12-h/12-h photoperiod. Total 20 isolates were obtained from diseased leaves, crowns, stolons, and fruits. Colonies were white with cottony aerial mycelium, irregular margins, and black acervuli distributed in concentric rings. Conidia were fusiform to ellipsoid (five cells) with one basal appendage and three or four (usually three) apical appendages. From colony and conidial morphology, the causal agent was identified as Neopestalotiopsis sp. (Maharachchikumbura et al. 2014). The internal transcribed spacer (ITS) region, ß-tubulin (TUB), and translation elongation factor 1-alpha (TEF-1α) of three isolates (ML1664 from diseased crown tissue collected in Hsinchu County; ML2147 and ML2411 from diseased leaves collected in Miaoli County) were sequenced (GenBank nos. MT469940 to MT469948). All three isolates clustered with the ex-type strain of Neopestalotiopsis rosae in the multilocus (ITS+TUB+TEF-1α) phylogenetic tree. To fulfill Koch's postulates, spore suspensions of ML1664 and ML2147 at 1×106 conidia/mL were used to spray-inoculate 'Xiang-Shui' seedlings at the 3 to 4 leaf stage until run-off (two trials, five seedlings per trial). Inoculated plants were put in a plastic bag (> 90% RH) at 25°C under a 12-h/12-h photoperiod. After 10-14 days, 80% of inoculated plants showed leaf or crown symptoms similar to those in the field. Control plants sprayed with sterile water showed no symptoms (4-5 seedlings per trial). The fungi were re-isolated from necrotic lesions with 100% frequency (n ≥ 3 isolates per trial), and morphological characters and ITS sequences were identical to the original ones. This is the first report of N. rosae causing leaf blight and crown rot in strawberry in Taiwan. N. rosae and N. clavispora have been reported as new threats to strawberry in several other countries (Rebollar-Alviter 2020; Gilardi 2019). Clarification of the pathogen provides a basis for developing strategies to control the emerging disease. Further studies are needed to evaluate the resistance/susceptibility of major strawberry cultivars and the fungicide sensitivity of the pathogen.