- Author: Ben Faber
USDA Report on Mexican Citrus Industry
This is a recent USDA report on the state of the Mexican citrus industry. It's interesting to hear how this industry is doing faced with HLB. And Drought.
Significant and ongoing drought conditions in many citrus-producing states have resulted in a reduction in all citrus production, compared to the previous report, with orange production forecast to fall forty-five percent. As a result of low orange supplies for processing, fresh concentrated orange juice exports to the United States are expected to fall to nearly half of the MY 2018/19 export level. COVID-19 sanitary measures are affecting domestic consumption of citrus fruit and juice, as many hotels and restaurants have been closed since mid-March. Full consumption effects will depend on the length of ‘stay at home' orders and the long term effect on the hotel and restaurant industries.
Drought and high temperatures
Orange production is estimated at 2,53 million tons for 2019/2020. That is 45% less than previous estimates. It is also the lowest expected harvest since the early 90s. This estimate is based on grower data and discussions with sector representatives.
The persistent drought and high temperatures have had a more drastic effect on orange production that other citrus. That is because many of the orange groves are older and need more energy to produce fruit. Many small farmers also lack irrigation technology. They practice bad pest control too, which compounds cultivation issues. Large-scale growers mostly have several irrigation mechanisms. They use fertilizers and apply other mitigating measures too. These include leaving weeds growing around the tree trunks. This retains moisture.
There have been intense temperatures and lack of rain throughout the growing season. That has resulted in a widespread decline in the orange's quality. Most fruit in the orange-growing region are smaller and of lower quality. In the state of Veracruz, October and November 2019 were the hottest months.
It usually rains throughout the growing season. However, this season, it was concentrated in two months. That resulted in a shorter growing season. The last flowering cycle indicates the harvest's end. This was between December and March. In Veracruz, oranges can usually be harvested until June.
Mexico is typically the world's second-largest producer of limes, and the fruit is the second-largest planted citrus crop in Mexico after oranges. While drought has affected lemon and lime production throughout the country, they have not been as affected as oranges. This can be attributed to newer plants and more widely available irrigation infrastructure. Persian lime trees in Veracruz are newer and more efficient, with 12 blooms, or harvests per year.The Post planted area for all limes and lemons in MY 2019/20 is forecast at 208,000 hectares, similar to previous MY; however, harvested area is expected to decrease eight percent due drought and high temperatures that caused some producers to abandon harvest or replant trees.
Italian lemons (Eureka) are grown in the states of Tamaulipas, Yucatan, San Luis Potosi, Colima, and Nuevo Leon. According to producers, there are currently attempts to grow the Italian lemon in the state of Veracruz with very good results. According to official sources, for MY 2018/19, production of Italian lemons was 131,469 MT on about 9,264 hectares. Sources indicate that lemon supplies for MY 209/20 are tight, and prices are high.
HLB
As with other citrus-producing countries, Mexico is facing issues with citrus greening, or Huanglongbing (HLB). The disease, caused by bacteria introduced by psyllids, makes citrus trees produce misshapen, partially green fruit (taste is typically not affected, but has no marketability for fresh consumption). Mexico's first detection was in 2009, and since then, the National Service of Agricultural Food Safety and Quality (SENASICA) has implemented a monitoring program for the disease. HLB has been detected throughout Mexico in citrus production areas. Producing states, including Veracruz, Tamaulipas, San Luis Potosi, and Nuevo Leon, have had HLB detections. In 2019, Baja California had HLB positive detections along the California/Mexico border region
On the map, dark outlined areas are where citrus is grown and yellow shaded is drought area.
- Author: Ben Faber
A recent University of Florida-Institute of Food and Agriculture Sciences (UF-IFAS) blog has a review of the last 60 years of rootstock trials and the lessons learned from those trials. It also has links to the results of those trials and a summary of the results of those trials.
What's also interesting is the “Expert System” that can be used to select a rootstock based on the horticultural traits (height, fruit size, etc), soil properties (pH, salinity, wetness, etc) and/or disease resistance.
The data is based on 21 characteristics of 48 rootstocks. It encompasses both the UF and USDA rootstock trials in Florida. And this last word is a key to all the data. It's based on the Florida condition and on many rootstocks that have not be trialed in California and aren't available commercially here. It is, however, a wonderful resource (Bibliography also included), learning tool and good starting point for reviewing potential rootstocks before ordering trees and planting an orchard. It's best to learn of potential problems before planting than having to learn how to correct those problems once the trees are in the ground.
And here is more from the USDA on citrus rootstocks: https://citrusrootstocks.org/
For an overview of California rootstocks for lemon, check out the presentations here
- Author: Ben Faber
An Automated Delivery System for Therapeutic Materials to Treat HLB Infected Citrus
Ozgur Batuman1 and Louise Ferguson2
¹Southwest Florida Research and Education Center, University of Florida, Immokalee, FL; 2UC Davis, Department of Plant Sciences, University of California Davis, Davis CA
Why is this research needed?
In 2005, a disease called Huanglongbing (HLB, citrus greening, was identified in Florida's commercial citrus groves. The disease is caused by a bacterium that affects all citrus cultivars by disrupting the flow of nutrients from the source of production, to the site of use, causing tree decline. HLB weakens the root system, increases early fruit and leaf drop, lowers tree productivity and fruit quality and ultimately kills the tree. The disease has spread to all the major production regions in Florida. Economic losses have exceeded more than $4 billion dollars. Currently, more than 95% of Florida's trees are infected. There is currently no cure for the disease.
Efforts to control HLB have been unsuccessful as the bacterium cannot be cultured, literally grown, in a petri dish, and once in the plant it proliferates within the citrus phloem. Phloem is the system that transports sugars from their site of production, the leaves, to plant parts that use sugars, the roots or flowers.Phloem transport is generally downward but can be upward as well.
Once the HLB bacterium is in a tree's phloem it has the potential to infect the entire tree. It is exceedingly difficult to introduce any control agent into the phloem with the conventional control methods of foliar spraying or soil drenching.
Thus far, no treatment preventing HLB infection, or controlling the bacterium once within the tree, has been developed. Potential chemicals are being investigated, but in order to test them, direct or indirect phloem delivery, where the bacterium proliferates, is needed. Therefore, an effective method of delivering an effective volume of theraputics into the phloem is needed to evaluate potential treatments.
What is the focus of this project?
Our project focuses on developing a method of delivering therapeutic liquid materials, bactericides, microbial metabolites, RNAi, or biologicals, into the citrus vascular tissues, both the xylem which conducts water and nutrients upward from the roots and the phloem, which conducts sugars and other metabolic products downward from the leaves. We are investigating diffusion, trunk punctures with a surrounding liquid reservoir for passive uptake and infusion, low pressure active injections. We are focusing on these methods as foliar sprays and root drenches have not been successful phloem delivery methods.
Who will be doing the research?
The project is led by plant pathologist Dr. Ozgur Batuman with colleagues at the Southwest Florida Research and Education Center (SWFREC) at University of Florida in Immokalee. This four-year project will also study the citrus vascular system with a multidisciplinary research team including UF Plant Pathologists Drs. Nabil Killiny and Amit Levy at Lake Alfred, SWFREC UF Plant Physiologist Ute Albrecht, Citrus Horticulturist Fernando Alferez, Precision Ag. Engineer Yiannis Ampatzidis, Agricultural and Natural Resources Economist Tara Wade, University of California-Davis Extension Specialist Louise Ferguson and Texas A&M-Kingsville Citrus Center Plant Pathologist Veronica Ancona as well as number of graduate students, postdocs, and Florida, Texas and California citrus industry members.
How will this research be done?
Our earlier research involving comparisons of delivery methods including foliar sprays, soil drenching and trunk injection determined Needle-Assisted Trunk Infusion (NATI) was the best potential delivery method (Figure.1). In initial experiments, using NATI, 1 ml of rhodamine (1%) dye was injected into the trunks of one-year-old citrus seedlings. A visible red color, indicative of rhodamine uptake and movement, was detected in the upper-most leaves within 30-60 min and an increase in color intensity was observed within 24 hours. Similar results were observed in two-year-old grafted Valencia plants within 48 hours. If the NATI delivery method can be automated, large numbers of trees could be treated quickly. Once the delivery method has been developed, implementation will be tested with potential treatments developed within other research projects.
Our proposed automated delivery would consist of a robotic arm with several modules at the end of the arm, installed on an ATV or tractor. One module with needles would grip and puncture the trunk, a second module would wrap a reservoir around the trunk below the punctures and third module would fill the reservoir. (Figure 2). Hopefully, a robotic arm plus automated system will be inexpensive enough for growers to purchase and simple enough to use.
Another approach is disease prevention; application pf prophylactic chemicals that prevent infection. In this scenario our system would be used treat healthy young trees with bactericides or boost their immune system. When infected by the ACP the bacterium would either be killed or suppressed, perhaps below the level that harms tree growth and productivity. This option is analogous to the vaccinations that prevent diseases in humans and animals.
What are the greatest challenges and opportunities.
The greatest challenge is successful phloem delivery. The greatest opportunity is that, if successful, we will have developed a method that will allow much more precise deliver of theraputics to citrus trees. For example, if an effective phloem delivery method is developed, it could be used to control insects that feed on citrus plant parts. Or, it could be used to deliver growth regulators, perhaps nutrients and carbohydrates, to roots and fruits to increase growth, development and fruit quality; much like an intravenous injection functions in an animal.
Among the questions we hope to investigate are:
- When, what kind of, and what amount of therapeutics can be applied by NATI?
- At what frequency?
- What type of citrus tree: cultivar, age, infected, healthy is the best for treatment by NATI?
- Can we kill the bacterium? How and when to assess a change in bacteria titer after treatment?
- When will become available and be economically feasible for growers?
Figure 1. Distribution of rhodamine (red dye; 1%) applied by NATI in various tissues (left) of grafted and non-grafted young citrus plants grown in the greenhouse (right). Photos taken 2 weeks after the treatments. Treatments and tissues observed are indicated. Yo = year-old.
Figure 2. Projected automated delivery system (ADS); an ATV with extendable arm with NATI and the cover placement systems on the arm guided onto the tree trunk (upper panel), and closeup of NATI and cover placement system (panel below).
Acknowledgement
The United States Department of Agriculture National Institute of Food and Agriculture (USDA-NIFA) Grant # 2019-70016-29096.
For more information, please visit this project's dedicated website:
https://swfrec.ifas.ufl.edu/programs/citrus-path/automated-delivery/
- Author: Ben Faber
The calls have come in. We've gone from cool to hot and Dry Root Rot of Lemon has struck, It's shocking how fast the trees go down.
Dry Root Rot has menaced growers in Ventura County for many years. In the ‘50's and ‘60's it seemed most prevalent on older orange trees. A few years after the wet winter of 1968-69, dry root rot became an increasing problem among citrus trees of all ages. At that time, most of the damaged trees were on sweet rootstock (susceptible to Phytophthora), and growing in fine-textured soils or soils with poor drainage. A few years after another wet winter/spring (of 1983), dry root rot again reared its ugly head, but this time predominately on young lemons.
The disease is caused by the fungus, Fusarium solani. This fungus is most likely present in all citrus soils in California. It is a weak pathogen in that by itself it will not attack a healthy tree. However, experiments conducted in the early 1980's by Dr. Gary Bender, showed that when seedlings were girdled, root invasion occurred. In the field, the fungus can infect trees once gophers have girdled the roots or crown. A Phytophthora infection will also predispose trees to Fusarium, as will asphyxiation. Therefore, the mere presence of the fungus in the orchard soil will not lead to the disease.
Description
Fusarium is a soil borne fungus that invades the root system. Once infected, the entire root will turn reddish-purple to grayish-black. This is in contrast to a Phytophthora infection which, in many cases, will attack only the feeder roots, but when larger roots are infected, only the inner bark is decayed and it does not discolor the wood. In addition, when observing the cross section of a dry root rot infected trunk, a grayishbrown discoloration in the wood tissue can be observed.
Dry root rot is a root disease, but symptoms of the root decline are seen above ground. They are similar to any of the root and crown disorders such as Phytophthora root rot, oak root rot fungus (Armillaria) and gophers. The trees lack vigor, leaves begin to turn yellow and eventually drop (especially in hot weather) causing twig dieback. Finally, the foliage will become so sparse that one will be able to see through the canopy of the tree. A period of two to three years may pass from the time of invasion until noticeable wilt. Many times, the tree will collapse in the summer, after a period of prolonged heat. In the case of dry root rot, the collapse is so rapid that the tree dies with all the leaves still on the tree. When looking for symptoms of dry root rot, keep an eye out for symptoms of other maladies as well — Phytophthora, oak root rot fungus and gophers being the most prevalent.
As mentioned previously, in order for Fusarium to infect a tree, there must be a predisposing factor such as girdling from gopher feeding. However, since many trees collapse from dry root rot without any apparent predisposing factor, there are obviously other factors which we have yet to identify. Therefore, in 1998, a grower survey was developed, along with intensive soil and leaf sampling, to attempt to identify as many new predisposing factors as possible. They might be elements in the soil, either deficiencies or excesses, or specific cultural practices such as irrigation patterns or fertilizer practices. Twenty orchards were identified from which 20 soil and 20 leaf samples were taken in diseased areas and another 20 soil and 20 leaf samples were taken from adjacent healthy areas. The owners or managers of the properties were given a questionnaire to complete regarding a variety of cultural operations. The objective was to identify those factors that would correlate well to trees becoming infected with dry root rot.
Survey Results
Soil analysis - The following laboratory procedures were conducted to see if there was any correlation between the disease and either deficiencies or toxicities of these elements or
conditions: sodium, boron, salt level, pH and soil type (sand, loam, clay). For these elements or conditions, no correlation was found. It would appear that for our sampling sites, these conditions, whether favorable or not (toxic or deficient), did not play a major role in predisposing the tree to dry root rot.
Leaf analysis - The following elements were analyzed for their concentration within the leaf: nitrogen, potassium, phosphate, manganese, magnesium and zinc. Of these, three correlations were found. Zinc and manganese levels were substantially higher in diseased trees. The third correlation showed a potassium deficiency in diseased trees. However, we do not believe that dry root rot is caused by elevated levels of zinc or manganese, or by potassium deficiency, but rather are a result of the disease. Unfortunately, it seems that we have still not identified any elements in leaf analysis that truly correlates and points to a predisposing factor for disease development.
Control Measures – What Works and What Does Not
Early experiments conducted by Menge, Ohr and Sakovich showed that the following circumstances or operations do not influence the incidence of this disease: fungicidal treatments, wounding the tap root at time of planting, sandy versus clay textured soils, spring versus fall planting and soil mounding.
- In choosing your nursery tree, the choice of rootstock is not important in that, as far as we know, all rootstocks are susceptible to this disease. However, since Phytophthora is a major component in dry root rot development, choosing a rootstock like sweet orange would certainly put those trees in a high risk category. We recommend that growers use Phytophthora resistant rootstocks like C35 or Citrumelo.
Phytophthora. Publications written in the 1970's, and again noted by our survey, showed that Phytophthora is a major culprit in the dry root rot complex. To control dry root rot, it is essential that the Phytophthora, when present, be controlled. This can be accomplished by fungicidal treatments, and by the proper application and timing of irrigation water. Overwatering creates a favorable environment for the multiplication of the Phytophthora fungus.
Gophers. It is well known that gopher damage provides entry points for Fusarium. Controlling gophers is an important factor in reducing the potential of infection by Fusarium.
Control
We presently have no direct control for dry root rot. To control the disease, we must control the predisposing factors such as gophers, Phytophthora, poor drainage and over-watering. If the predisposing factor(s) cannot be identified for a given diseased orchard, it will indeed be difficult to control the disease. Two things are certain though: 1.) There are no chemicals to date which will control this disease; and 2.) Presently, there are no rootstocks resistant to the disease.
Listen to Akif Eskalen tell the Dry Root Rot story
https://www.youtube.com/watch?v=K2fyBcC1HXk&feature=youtu.be
- Author: Ben Faber
Citrus greening disease, also called huanglongbing (HLB), is a bacterial infection of citrus trees that results in small, misshapen and sour fruits that are unsuitable for consumption. The disease ultimately kills the tree.
Because there is no cure, HLB is a major threat to the $10 billion citrus industry in Florida, where it was first detected in 2005,and to the $7 billion industry in California, where it appeared last year.
Researchers from the Boyce Thompson Institute (BTI), the U.S. Department of Agriculture Agricultural Research Service (USDA-ARS) and the University of Washington investigated a seemingly unlikely source of biocontrols for HLB: neuropeptides found in Asian citrus psyllids, the insect that carries the disease-causing bacterium Candidatus Liberibacter asiaticus (CLas), which it spreads while feeding on a tree's leaves and stems.
The research team, led by BTI faculty member Michelle Heck, published its findings on Feb. 10 in the Journal of Proteome Research.
Laura Fleites, a research associate in Heck's group at BTI, focused on neuropeptides because they function as hormones in hemipteran insects – a class that includes psyllids, aphids, whiteflies, shield bugs and other crop-plaguing species – to regulate growth, development and other biological functions.
“If we could develop an insecticide that is specific for Asian citrus psyllids based on one of the insect's own neuropeptides, then we could protect citrus trees from the insect that spreads CLas,” said Heck, a USDA-ARS research molecular biologist and an adjunct associate professor in the School of Integrative Plant Science, in the College of Agriculture and Life Sciences. “Citrus greening disease is devastating our citrus industry, and we need to develop new ways for our citrus growers to control it.”
Fleites and the team characterized the full array of peptides found in the psyllids and identified 122 potential neuropeptides. While promising, the findings offer only potential starting points for combatting HLB, because unmodified insect-derived neuropeptides are not suited for use as insecticides in the citrus grove.
To turn the findings into a usable product, the team is now part of a collaboration aimed at identifying the best psyllid-derived neuropeptide for development. The team will then stabilize the peptide and decide the optimum method for delivering the insecticidal molecule to citrus trees – whether as a spray, by engineering trees to make the peptides themselves, or by some other method.
For the study, Fleites developed new extraction and analysis methods other researchers could use in their investigations of insect peptides.
“Thanks to USDA support, I was able to develop techniques that enable the identification of small, functional insect peptides separately from their larger, inactive precursors,” Fleites said. “Because these techniques aren't specific to psyllids, they may be useful for identifying neuropeptides in other hemipteran insects to protect crop plants.”
Heck said this work shows how USDA grant programs can be used to fund everything from discovery to product development. The neuropeptide discovery was done in a study funded by the National Institute of Food and Agriculture; the translational research is being done under a grant from the Animal and Plant Health Inspection Service.
Funding for this work came from a USDA Specialty Crops Grant and from the USDA-ARS.
Michael J. Haas is a freelance writer for the Boyce Thompson Institute.
https://news.cornell.edu/stories/2020/04/psyllid-peptides-could-fight-citrus-greening-disease
Asian citrus psyllids feed on a citrus tree. The psyllids deposit a bacterium in the sap that causes citrus greening disease, a scourge to the citrus industries in Florida and California, worth a combined $17 billion.