Abstract
This study addresses the interactive effects of deficit irrigation and huanglongbing (HLB) infection on the physiological, biochemical, and oxidative stress responses of sweet orange trees. We sought to answer: (i) What are the causes for the reduction in water uptake in HLB infected plants? (ii) Is the water status of plants negatively affected by HLB infection? (iii) What are the key physiological traits impaired in HLB-infected plants? and (iv) What conditions can mitigate both disease severity and physiological/biochemical impairments in HLB-infected plants? Two water management treatments were applied for 11 weeks to 1-year-old-trees that were either healthy (HLB–) or infected with HLB (+) and grown in 12-L pots. Half of the trees were fully irrigated (FI) to saturation, whereas half were deficit-irrigated (DI) using 40% of the water required to saturate the substrate. Our results demonstrated that: reduced water uptake capacity in HLB+ plants was associated with reduced root growth, leaf area, stomatal conductance, and transpiration. Leaf water potential was not negatively affected by HLB infection. HLB increased leaf respiration rates (ca. 41%) and starch synthesis, downregulated starch breakdown, blocked electron transport, improved oxidative stress, and reduced leaf photosynthesis (ca. 57%) and photorespiration (ca.57%). Deficit irrigation reduced both leaf respiration (ca. 45%) and accumulation of starch (ca.53%) by increasing maltose (ca. 20%), sucrose, glucose, and fructose contents in the leaves, decreasing bacterial population (ca. 9%) and triggering a series of protective measures against further impairments in the physiology and biochemistry of HLB-infected plants. Such results provide a more complete physiological and biochemical overview of HLB-infected plants and can guide future studies to screen genetic tolerance to HLB and improve management strategies under field orchard conditions.
Highlights
The most important problem in citrus production worldwide is the bacterial disease huanglongbing (HLB; syn. citrus greening), presumably caused by the bacterium Candidatus Liberibacter asiaticus (Clas; Wang and Trivedi, 2013) that triggers a cascade of events, causing phloem dysfunction, cellular collapse, and accumulation of carbohydrates in leaves (Cimò et al, 2013)
Stomatal closure is likely a direct effect of the interplay between microorganisms and plant compounds secreted during the plant-pathogen interaction, but limited to epiphytic species and related to high concentrations of bacteria (Gudesblat et al, 2009). Considering this is not the case of Ca. Liberibacter asiaticus (CLas), a systemic pathogen directly introduced in the plant by the vector, we argue that the variations in stomatal conductance observed in our study occurred in parallel to changes in the hydraulic conductance in infected plants
Given the importance of HLB, which affects citrus and causes significant losses in fruit yield and quality of commercial orchards, our research characterized biochemical and physiological traits of trees at the plant-pathogen-environment level looking for the joint effect of disease and deficit irrigation
Summary
The most important problem in citrus production worldwide is the bacterial disease huanglongbing (HLB; syn. citrus greening), presumably caused by the bacterium Candidatus Liberibacter asiaticus (Clas; Wang and Trivedi, 2013) that triggers a cascade of events, causing phloem dysfunction, cellular collapse, and accumulation of carbohydrates in leaves (Cimò et al, 2013). Citrus greening), presumably caused by the bacterium Candidatus Liberibacter asiaticus (Clas; Wang and Trivedi, 2013) that triggers a cascade of events, causing phloem dysfunction, cellular collapse, and accumulation of carbohydrates in leaves (Cimò et al, 2013). The dysfunction caused by HLB in citrus has been associated with the accumulation of starch in both. Citrate has been reported as the likely main source of energy for the phloem-inhabiting pathogen/bacteria Clas (Cruz-Munoz et al, 2018). In this case, leaf respiration (R) as a key component of plant growth (Ayub et al, 2014), if leading to a negative carbon balance, could have a central role in plant susceptibility to HLB. HLB damages photosynthetic capacity, which can be associated with the production of reactive oxygen species (ROS), oxidative stress, and components of H2O2 detoxification (Martinelli and Dandekar, 2017)
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