ROOTING FOR THE FUTURE: ROOT AND RHIZOSPHERE ECOLOGY FOR SUSTAINABLE PRODUCTIONS IN A CHANGING WORLD

• Sponsoring Institution: National Institute of Food and Agriculture
• Project Status: COMPLETE
• Funding Source: HATCH
• Reporting Frequency: Annual
• Accession No.: 1017625
• Project Start Date: Oct 9, 2018
• Project End Date: Sep 30, 2023
• Program Code: [(N/A)]- (N/A)

Recipient Organization
UNIVERSITY OF FLORIDA
G022 MCCARTY HALL
GAINESVILLE,FL 32611

Performing Department
Indian River Research and Education Center

Non Technical Summary
The long-term goal of this project is to improve sustainable agricultural practices, with emphasis on citrus, while improving and developing research tools to monitor plant root health and structure. The obtained results will facilitate the development of healthy agroecosystems, profitable agricultural production systems, and food security. Overall there will be tangible benefits to the community and improve living standards locally, nationally and internationally.

Animal Health Component

85%

Research Effort Categories

Basic

5%

Applied

85%

Developmental

10%

Classification

Knowledge Area (KA)	Subject of Investigation (SOI)	Field of Science (FOS)	Percent
102	0999	1020	90%
102	0110	1070	10%

Knowledge Area
102 - Soil, Plant, Water, Nutrient Relationships;

Subject Of Investigation
0110 - Soil; 0999 - Citrus, general/other;

Field Of Science
1070 - Ecology; 1020 - Physiology;

Keywords

hlb

citrus

root

rhizosphere

Goals / Objectives
1. Determine optimal nutrient concentrations for multiple citrus varieties and rootstocks under HLB-endemic conditions to improve root health and increase tree productivity.2. Develop new tools and approaches to characterize citrus root-system structure, architecture, and function in greenhouse and field trials.3. Define the extent to which progression of HLB may involve changes in the relationship between the plant and the soil microbial community.4. Identify and quantify the potential impact of emerging contaminants on rhizosphere ecology, root physiology and root anatomy.?

Project Methods
1. Determine optimal nutrient concentrations for multiple citrus varieties and rootstocks under HLB-endemic conditions to improve root health and increase tree productivity.Established, fruit-bearing groves, in the age range 4-7 years will be used for this study. They will include Hamlin (or Valencia) orange and grapefruit varieties grown in the Central Florida ridge, southwest Florida flatwoods, and the Indian River District. Replicated field plots for this proposed study will be established in these groves and current nutrient application rates assessed. The nutrient application procedures will then be modified to include a range of nutrient application rates applied via fertigation with and without foliar fertilization. Tree roots will be sampled seasonally and analyzed for all major and minor nutrients. Root health will be assessed monthly using minirhizotron scans, and semiannually with root collections for nutrient and Candidatus Liberibacter asiaticus (CLas) assessment.Visual HLB disease symptoms will be rated every 6 months along with leaf samples for CLas titer and activity (qPCR of DNA and RNA) and nutrient content. Yield per tree and per acre, fruit size and juice quality will be determined annually at harvest. Nutrient concentrations in roots for trees receiving a range of nutrient application rates from low to very high (overloaded) will be evaluated to determine the maximum potential uptake of individual macro and micronutrients beyond which further fertilization would not increase nutrient levels. By deploying a wide range of nutrient concentrations to leaves and soil from low to very high, we can determine the capacity of leaves of HLB-affected trees to take up fertilizer and/or soil nutrients.2. Develop new tools and approaches to characterize citrus root-system structure, architecture, and function in greenhouse and field trialsGreenhouse trials will compare one HLB-susceptible and several HLB-tolerant rootstocks. Rootstock seedlings about six inches high will be micro-grafted with either healthy or infected scion buds, resulting in healthy or HLB-affected plants for each rootstock type. After inoculation, leaf and root samples will be collected from all experimental plants, and DNA will be collected from leaves and roots. The extracted DNA will be used to quantify CLas-specific sequences by qRT-PCR. Although these data will not necessarily reflect levels of living CLas, they will nonetheless provide an approximate value for bacterial titer in leaves and roots. Treatments will begin after testing all plants for presence or absence of CLas.Leaves and roots will be sampled for physiological, biochemical, and nutritional analyses as well as a determination of Differentially-Expressed Genes (DEGs). Leaf and root tissues will be frozen at -80 °C and stored for future use. Plant height, diameter, leaf number, and SPAD readings will be recorded for each plant monthly for six months. Root and shoot biomass will be quantified at the end of the experiment.Nutrient content in the leaves and roots of each rootstock will be analyzed, and results compared between tolerant and susceptible rootstocks, and between healthy and infected plants of the same genotype. In addition to the leaf nutrient analysis, pH and electrical conductivity of the soil will also be recorded to assess the uptake rate as well as nutritional status of the soil used in the experiment. This will also be carried out at the same time points as other measurements.This project will also take a phenomics approach to characterizing citrus root-growth dynamics. This approach will include the development of imaging technologies, computational infrastructure, and statistical methods that can capture and analyze morphologically-complex features over time and in a high-throughput fashion. Root-system architecture encompasses the spatial and temporal organization of roots in the growth medium, and thus greatly influences the resource-capturing capacity of a plant. To achieve this goal, a system to phenotypically characterize root systems in the field (mini-rhizotrones) and greenhouse (rhizotrones) will be adapted for use with citrus. This system will be accompanied by a 2-D and 3-D modeling approach. By comparing different genotypes tolerant or sensitive to HLBthe project aims to identify genes that can help generate more HLB- resistant and sustainable citrus.3. Define the extent to which progression of HLB may involve changes in the relationship between the plant and the soil microbial communityEstablished, fruit-bearing citrus groves from 4 to 7 years old will be used for this study. They will include Hamlin (or Valencia) orange and grapefruit varieties grown at three sites: in the Central Florida ridge, the southwestern Florida flatwoods, and the Indian River District. Replicated field plots will be established in these groves. Leaf and root samples will be collected in triplicate from each tree and brought to the laboratory for analyses. Soil samples will be also collected from the different regions a few meters distant from trees (bulk soil samples). Rhizosphere samples will consist of root system parts and soil. DNA will be extracted from roots and leaves, with presence of CLas determined by PCR.We will profile the assemblage of bacterial flora associated with CLas-infected and CLas-free rhizospheres using metagenomics based on 16S rRNA. PCR products will be cloned into Agrobacterium tumefaciens and introduced into chemically competent Escherichia coli TOP10 cells. Transformed cells will be incubated on selective media, transferred to culture blocks, and aliquots grown for sequencing. Sequences will be analyzed for orientation and detection of non-16S rDNA sequences and chimeras. They will then be aligned, evaluated by principal-coordinate analysis (PCA), and phylogenetic composition evaluated.The data will be used to compare rhizosphere microbiomes of healthy and HLB-affected trees. Additional studies will include experimental perturbation of the rhizosphere of HLB-affected trees. These will be inoculated with bacterial strains obtained from healthy citrus root-associated microbiomes and the effects on the plants will be observed.4. Identify and quantify the potential impact of emerging contaminants on rhizosphere ecology, root physiology and root anatomy.Responses to different types of ENPs (i.e., CeO2NPs, TiO2NPs, etc.) will be tested in this project. Electron microscopy will be used to determine the average size and the zeta potential. Citrus and other horticultural species (i.e., tomato, lettuce, soybeans) seedlings will be grown in the greenhouse and controlled chambers under combined stresses: heavy metals + ENPs, or salinity and drought + ENPs. After a pre-determined time (variable for each tested species), the plants will be carefully removed from the growth media, rinsed with deionized water, divided into roots and leaves, and tapped dry with a paper towel. The root and leaf tissues from each replicate will be dried in an oven at 70 ºC for 7 days to determine the dry biomass and concentrations of ions and heavy metals by ICP-MS. Root samples from each plant will also be collected and stored at 4 ºC in pure methanol. Physiological measurements to correlate root health with leaf physiology will also be carried out each week using a portable photosynthesis system. At the end of the experiment, chlorophyll content will also be quantified. Roots will be analyzed under a light microscope for development of apoplastic barriers. A series of free-hand radial sections from roots from each plant will be used to visualize suberin lamellae using the fluorescence protocol developed by LUX et al. (2005). All anatomical observations will be performed at the Indian River and Research Center, University of Florida, IFAS, Fort Pierce, FL.

Progress 10/01/20 to 09/30/21

Outputs
Target Audience:Florida growers, undergraduate and graduate students, and the scientific community Changes/Problems: Nothing Reported What opportunities for training and professional development has the project provided?Graduatestudents (n = 6), undergraduates (n = 1), visiting scientists (n = 1), technicians (n = 1), and postdocs (n = 1) received trainings in root and rhizosphere ecology, while learning about experimental design and statistical analysis. Local growers and producers attended field days and trade shows (Citrus Show and Citrus Expo). How have the results been disseminated to communities of interest?Research from this project has been disseminated locally (Citrus Show and Citrus Expo) and at professional conferences: - Florida State Horticultural Society meeting 2021 - American Society for Horticultural Science conference 2022 What do you plan to do during the next reporting period to accomplish the goals?The project is advancing well. There will be more more publications and conference presenations coming out in 2022 and 2023

Impacts
What was accomplished under these goals? 1. Determine optimal nutrient concentrations for multiple citrus varieties and rootstocks under HLB-endemic conditions to improve root health and increase tree productivity. ACCOMPLISHMENTS: 1 student graduate with a Thesis 2. Develop new tools and approaches to characterize citrus root-system structure, architecture, and function in greenhouse and field trials. ACCOMPLISHMENTS: 1 greenhouse study was conducted and the paper is under preparation 3. Define the extent to which progression of HLB may involve changes in the relationship between the plant and the soil microbial community. ACCOMPLISHMENTS: one paper was published 4. Identify and quantify the potential impact of emerging contaminants on rhizosphere ecology, root physiology and root anatomy. ACCOMPLISHMENTS: 2 research studies were conducted in a greenhouse and 2 paper are expected in 2022

Publications

• Type: Journal Articles Status: Published Year Published: 2021 Citation: itrus Root and Rhizosphere Dynamics in the Age of HLB Annual Plant Reviews online 2021 Volume 4 Issue 2, May 2021 Lorenzo Rossi,Lukas M. Hallman,John M. Santiago First published: 21 June 2021 https://doi.org/10.1002/9781119312994.apr0769
• Type: Theses/Dissertations Status: Published Year Published: 2021 Citation: Lukas Hallman, Master Thesis Uptake of micronutrients by application methods for HLB-affected grapefruit trees on flatwoods soils
• Type: Journal Articles Status: Published Year Published: 2021 Citation: In Planta Localization of Endophytic Cordyceps fumosorosea in Carrizo Citrus by Ethan M. Doherty, Pasco B. Avery, Emily B. Duren, Liliana M. Cano and Lorenzo Rossi Microorganisms 2021, 9(2), 219; https://doi.org/10.3390/microorganisms9020219

Progress 10/01/19 to 09/30/20

Outputs
Target Audience:Obj.1 - Determine optimal nutrient concentrations for multiple citrus varieties and rootstocks under HLB endemic conditions to improve root health and increase tree productivity. One graduate student worked on this objective and generated data and 1 peer-reviewed publication Obj.2 -Develop new tools and approaches to characterize citrus root-system structure, architecture, and function in greenhouse and field trials. One graduate student worked on this objective. We now have more thane 150 mini-rhizotrones installed in the field and rhizoboxes in greenhouse and laboratory settings. Data has been generated and will be published with the new year. Obj. 3 -Define the extent to which progression of HLB may involve changes in the relationship between the plant and the soil microbial community. A new graduate student has been hired to work on this topic and we will start data collection with the new year. 4. Identify and quantify the potential impact of emerging contaminants on rhizosphere ecology, root physiology and root anatomy. 1 technician worked on this objective and 2 papers has been published. Changes/Problems:COVID-19 was a real problem this year and it was hard to do any lab or field work because of the restrictions. But we managed! What opportunities for training and professional development has the project provided?3 Graduate students and 1 technician have been professionally trained. How have the results been disseminated to communities of interest?Yes, data has been published in scientific journals. What do you plan to do during the next reporting period to accomplish the goals?Next year we will focus more on conference talks and greenhouse experiments. Also Obj. 3 will be fully developed by the end of the year.

Impacts
What was accomplished under these goals? Obj.1 - Determine optimal nutrient concentrations for multiple citrus varieties and rootstocks under HLB endemic conditions to improve root health and increase tree productivity. One peer-reviewed publication has been published, data have been collected and a presentation to a conference is planned for next year. Obj.2 -Develop new tools and approaches to characterize citrus root-system structure, architecture, and function in greenhouse and field trials. We now have more thane 150 mini-rhizotrones installed in the field and rhizoboxes in greenhouse and laboratory settings. Data has been generated and will be published with the new year. Obj. 3 -Define the extent to which progression of HLB may involve changes in the relationship between the plant and the soil microbial community. A new graduate student has been hired to work on this topic and we will start data collection with the new year. 4. Identify and quantify the potential impact of emerging contaminants on rhizosphere ecology, root physiology and root anatomy. Two papers has been published and more studies are coming next year.

Publications

• Type: Journal Articles Status: Published Year Published: 2020 Citation: Lorenzo Rossi,Lukas M. Hallman, Sawyer N. Adams and Walter O. Ac-Pangan Impact of a Soil Conditioner Integrated into Fertilization Scheme on Orange and Lemon Seedling Physiological Performances Plants 2020, 9(7), 812 https://doi.org/10.3390/plants9070812
• Type: Journal Articles Status: Published Year Published: 2020 Citation: John-PaulFox, Jonathan D.Capen, Weilan Zhang, Xingmao Ma, LorenzoRossi Effects of cerium oxide nanoparticles and cadmium on corn (Zea mays L.) seedlings physiology and root anatomy NanoImpact, Volume 20, October 2020, 100264 https://doi.org/10.1016/j.impact.2020.100264

Progress 10/09/18 to 09/30/19

Outputs
Target Audience:The project started on Oct. 2018. In this first years we organized meeting with citrus growers in the Indian River region, we collected information about the type of research needed and we started 2 main research project founded by CRDF and USDA-APHIS-MAC. The first set of data as been collected. University of Florida 3 under-graduate students, 1 Biological Scientistand 2 Graduate Studentshave been involved in projects directly related to this REEport. 2 peer-reviewed publications has been published. Changes/Problems: Nothing Reported What opportunities for training and professional development has the project provided?3 Undergraduate student, 1 Biological Scientist, 1 Visiting Scientist and 2 Graduate Studentshave been trained about citrus root biology and HLB. They attended seminars and workshops and they partecipate in research related to thios project. How have the results been disseminated to communities of interest?Results has been disseminated via extension and peer-reviewedpublications, oral talks at scientific conferences and meetings with growers and local communities. What do you plan to do during the next reporting period to accomplish the goals?Next reporting period will focus primarily on goal # 1,#2 and #4. With the awarded projects from Citrus Research and Development foundation and USDA-APHIS-MAC and the presence of 2 trained graduate students and OPS in the laboratory we will work on 1) Determiningoptimal nutrient concentrations for multiple citrus varieties and rootstocks under HLB-endemic conditions to improve root health and increase tree productivity.2) Develop new tools and approaches to characterize citrus root-system structure, architecture, and function in greenhouse and field trials and 3) Identify and quantify the potential impact of emerging contaminants on rhizosphere ecology, root physiology and root anatomy.

Impacts
What was accomplished under these goals? 1. Determine optimal nutrient concentrations for multiple citrus varieties and rootstocks under HLB-endemic conditions to improve root health and increase tree productivity. A 3 year project has been awarded from the Citrus Research and Development Foundation to work on this specific goal. We selected the site for the experiment and we met with growers. A graduate student has been hired. The data collection is underway. A 2year project has been awarded from the USDA-APHIS-MAC to work on this specific goal. We selected the site for the experiment and we met with growers. Agraduate student has been hired. The data collection is underway. 2. Develop new tools and approaches to characterize citrus root-system structure, architecture, and function in greenhouse and field trials. A rhizotron system has been develop for greenhouse studies using different citrus rootstocks. The experiment is underway and will generate knowledge about differences in the root system architecture of different genotypes under HLB infection. A visiting student from Guatemala worked on the project. 150 Mini-Rhizotrones have been installed in the field. 2 gradaute students are working on this specific goal. 3. Define the extent to which progression of HLB may involve changes in the relationship between the plant and the soil microbial community. Nothing to report 4. Identify and quantify the potential impact of emerging contaminants on rhizosphere ecology, root physiology and root anatomy. With the citrus industry declining, it is imperative to study all the potential environmental stresses affecting the citrus cultivation and to conduct screening tests to evaluate which rootstock can perform better best under these new challenging conditions. A salt stress study have been conducted to assess root physiological and anatomical characteristics of rootstock US-942 under salt stress. Two papers have been published.

Publications

• Type: Book Chapters Status: Published Year Published: 2019 Citation: LOMBARDINI L., ROSSI L. 2019. Ecophysiology of Plants in Dry Environments. In: D'Odorico P., Porporato A., Wilkinson Runyan C. (eds) Dryland Ecohydrology. Springer, Cham. DOI: https://doi.org/10.1007/978-3-030-23269-6_4
• Type: Journal Articles Status: Published Year Published: 2019 Citation: ROSSI L., BAGHERI M., ZHANG W., BURKEN J., MA X. 2019. Using the Artificial Neural Network to investigate physiological changes and cerium oxide nanoparticles and cadmium uptake in Brassica napus plants. Environmental Pollution, DOI: https://doi.org/10.1016/j.envpol.2018.12.029
• Type: Journal Articles Status: Published Year Published: 2019 Citation: ADAMS S., AC PANG�N W., ROSSI L. 2019. Effects of Soil Salinity on US-942 Citrus Physiology and Root Anatomy. HortScience, DOI: https://doi.org/10.21273/HORTSCI13868-19
• Type: Conference Papers and Presentations Status: Published Year Published: 2019 Citation: ROSSI L., PITINO M., DORADO C., SHATTERS R.G., CANO L.M. 2019. Physiological effects of oak bioactive compounds on Florida citrus when applied to contain and suppress HLB disease. Proceedings of the 6th International Research Conference on HLB. March 10-15, 2019, Riverside, GA, USA
• Type: Conference Papers and Presentations Status: Published Year Published: 2019 Citation: HALLMAN LM, AC-PANGAN WO, ADAMS SN, ROSSI L. 2019. Optimal Nutrient Concentrations and Use of Root Growth Enhancers to Improve Citrus Root Health. HortScience 54(9) S241-S241. Proceedings of the Annual Meeting of the American Society of Horticultural Sciences. July 21st-25th 2019, Las Vegas, NV, USA.