The purpose is to evaluate the control effect of bactericides via trunk injection.
Objective 1.
1.1. Determination of the in planta minimum bactericidal concentrations (MBCs) of bactericides against Las
We developed a new method for evaluating the effects of oxytetracycline (OTC) treatment on Las titers in planta, and determined the relationship between OTC residue levels and control levels achieved for Las using mathematical modeling in greenhouse and field experiments. In greenhouse, OTC injection at 0.05 g/tree decreased Las titers to an undetectable level (Ct value ≥ 36.0) from 7 to 30 DPA, and produced a residue level of OTC at 0.68-0.73 µg/g fresh tissue over this period. In the field, OTC injection at 0.50 g/tree resulted in the decline of Las titers by 1.52 log reduction from 14 to 60 DPA, with residue levels of OTC at 0.27-0.33 µg/g fresh tissue. In both trials, a first-order compart model of OTC residue dynamics in leaves of trunk-injected trees was specified for estimating the retention of effective concentrations. Furthermore, nonlinear modeling revealed significant positive correlations between OTC residue levels in leaves and the control levels for Las achieved. The results suggested that the minimum concentration of OTC required to suppress Las populations in planta to below the detection limit is 0.68 and 0.86 µg/g, and the minimum concentration of OTC required for initial inhibition of Las growth in planta is approximately 0.17 and 0.215 µg/g in leaf tissues under greenhouse and field conditions, respectively. This finding highlights that a minimum concentration of OTC should be guaranteed to be delivered to target Las in planta for effective control of citrus HLB. This study has been published by Phytopathology in a manuscript entitled: The in planta effective concentration of oxytetracycline against Candidatus Liberibacter asiaticus for suppression of citrus Huanglongbing.
In addition, we evaluated the inhibitory activity of streptomycin (STR) against Las in a greenhouse experiment. Citrus trees were trunk-injected with STR, and leaves were inspected for Las populations and STR residues using qPCR and HPLC assays respectively, at various times after STR injection. Assays for Las titers and STR concentration in leaf samples from field trials are also ongoing.
1.2. Effect of bactericides via trunk injection on citrus HLB disease progression, tree health, yield and fruit quality in different aged trees with a different disease severity
The field experiments were performed at four different groves on different aged trees with a different disease severity. They are one located in Avon Park, FL, 3-year old Valencia trees (planted in 04/2016); one in Bartow, FL, 2-year old W. Murrcot trees (planted in 01/2017, “CUPS”); and one in Auburndale, FL, 7-year old Hamlin trees (planted in 02/2012). The last one is in CREC-, Lake Alfred, FL, 20-year old Hamlin trees (planted in 03/1999). The HLB disease severity and tree size (canopy volume and trunk diameter) in the four groves were estimated immediately prior to treatment application. For the field tests, the experiment design is a randomized complete block design (RCBD) for 9 treatments, including 6 injection treatments (3 different doses for OTC or STR), 2 spray treatments (OTC or STR spraying), and one No treatment as a negative control. Each injection treatment consisted of 9 or 15 trees divided into 3 blocks of 3 or 5 trees each. Each spray treatment consisted of 30 trees divided into 3 blocks of 10 trees each. For all the four field trials, the injection treatment applications were completed by the end of April 2019. The first application of spray treatments were completed during spring flushing in February or March 2019, and the second applications were conducted in late June to early July 2019. Leaf samples have been collected from the treated trees at the following time points: 0 (pre- injection), 7, 14, 28 days, 2, 4, and 6 months after treatment. The estimation of Las titers in these leaf samples are ongoing with qPCR assays. The first estimation of HLB disease severity and growth performance (height, trunk diameter, and canopy volume) of immature trees after treatment were performed on May, 2019 (three months after the injection) and continued in a 3-months interval.
Objective 2.
2.1. Examination of dynamics and residues of bactericide injected into citrus and systemic movement within the vascular system
Leaf and root samples have been collected from OTC or STR treated trees in the Avon Park grove at the following time points:0 (pre- injection), 7, 14, 28 days, 2, 4, and 6 months after injection. The samples are being processed for OTC or STR extraction, and the concentrations of OTC and STR in these samples will be determined by HPLC assays. Then, the distribution of bactericides in different plant tissues will be compared in terms of translocation time and dosage.
2.2. Determination of the residue contents of bactericides in fruit and juice in each harvest
This study will be initiated during fruit harvest.
2.3. Analysis of degradation metabolites of bactericides injected into citrus trees
Leaf samples were collected from OTC or STR injected trees in the Avon Park grove at two and four months after treatment for the analysis of the degradation metabolites of the bactericides. The samples are being processed for the extraction of the degradation metabolites.
Objective 3.
3.1. Greenhouse assays of the effect of bactericides via trunk injection on Las acquisition by ACP
This assay will be initiated in the spring of 2020.
3.2. Field assays of the effect of bactericides via trunk injection on Las acquisition by ACP
This assay will be initiated in the spring of 2020.
Objective 4.
4.1. Monitoring resistance development in Las against bactericides
Leaf samples for this test have been collected from 5 trees injected with OTC and 5 trees injected with STR at the highest doses in each of the three groves at six months after the injection. DNA extraction from these samples is ongoing.
4.2. Evaluation of potential side effects of trunk injection of bactericides
We evaluated possible phytotoxity caused by OTC or STR in immature trees (3-year old Valencia) in the Avon Park grove from one week to one month after injection. The trees were be examined for the following symptoms: fruitlet drop, fruit drop, quantity of leaf drop, non-insect related leaf rolling, and leaf discoloration. There was no significant difference in fruitlet drop, fruit drop, quantity of leaf drop, or non-insect related leaf rolling between OTC or STR treatment and untreated control. About 20% (3 out of 15) trees injected with OTC or STR at the highest dose (2.0 g/tree) showed leaf discoloration (yellowing) on some young shoots. These phytotoxicity-like symptoms disappeared at 6 months post injection. There was no infection symptom by Phytophthora in the area surrounding drilling sites (injection holes), probably due to the application of the fungicide Ridomil gold immediately after drilling.
In 7-year old Hamlin trees in the Auburndale grove, three trees injected with STR at the highest dose (3.0 g/tree) showed leaf discoloration (yellowing) on some young shoots, a possible phytotoxitic effect. These phytotoxicity-like symptoms disappeared at 6 months post injection. Other treated trees all showed normal growth.
We will continue the surveys for potential side effects.