Xanthomonas fragariae
Xanthomonas fragariae | |
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Scientific classification | |
Domain: | Bacteria |
Phylum: | Pseudomonadota |
Class: | Gammaproteobacteria |
Order: | Xanthomonadales |
Family: | Xanthomonadaceae |
Genus: | Xanthomonas |
Species: | X. fragariae
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Binomial name | |
Xanthomonas fragariae Kennedy and King 1962
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Xanthomonas fragariae is a species of proteobacteria. It is a leaf spot disease found in strawberries (Fragaria spp.).[1]
Environment
Favorable environmental factors for Xanthomonas fragariae are not fully understood and need to be studied more. It has been noticed, however, that X. fragariae thrive in humid climates.[2] Xanthomonas fragariae are also most prevalent in climates with cool to moderate temperatures.[3]
Host & symptoms
Infection caused by the angular leaf spot pathogen first appears as water-soaked lesions found on the lower surface of strawberry leaves. These water-soaked lesions are the result of bacterial colonization within the plant leaf tissue. Lesions typically get larger as the infection worsens, and the enlarged lesions then form translucent spots. These angular spots typically exude an ooze of bacteria that appears as a white and flakey film once dry.[2] Lesions on the upper surface of leaves will also become visible with time. As the disease worsens, the angular spots grow larger and begin to combine. Severely affected leaves can tear away and become jagged, with a dry and reddish-brown appearance. Prolonged wetness on strawberry leaves can exacerbate this disease, so air circulation and sunlight exposure are important to protecting the host plants. These symptoms are similar to leaf scorch and common leaf spot so be careful when examining symptoms of diseased plants.[3] Dark purple spots scattered on the leaf surface are symptoms of leaf scorch and common leaf spot, but not angular leaf spot.[4]
Importance
X. fragariae was first reported on strawberries in 1960 in Minnesota.[3] It is now found throughout many American states, Europe, South America, Africa, Australia, and New Zealand.[5] X. fragariae does not have a large host range, it infects different strawberry varieties, including Fragaria virginiana and F. vesca, along with Potentilla fruticosa, and P. glandulosa.[6] Even though X. fragariae has a small host range, it is capable of causing major damage. Angular Leaf Spot, caused by X. fragariae, can cause up to 75% yield reduction of strawberries.[2] Angular Leaf Spot is currently an issue in strawberry nursery production, leading to problems in transporting strawberry plants throughout the U.S and over to Europe.[5] Xanthomonas fragariae is not only an issue transporting young plants, but infected fruits can lead to a symptom known as “black cap” that can reduce the quality and marketability of the fruit.[5]
Diagnosis
Place suspected diseased leaves up against a bright light to see the translucent spots associated with Xanthomonas fragariae.[4] By looking from the backside of infected leaves, light should pass through the angular shaped lesions and appear as lighter colored patches.
Pathogenesis
X. fragariae is a gram-negative bacterium, that is rod shaped ranging from 0.4-1.0µm wide and 0.7- 2.0µm long (Louws).[7] The primary host of X. fragariae are strawberry plants (F. virginiana and F. vesca).[6] X. fragariae are classified as an A2 level quarantine pathogen by the European Plant Protection Organization, meaning that this bacteria can be spread easily through the movement of strawberry plants.[5] X. fragariae will attack both the stock and the fruit of strawberries plants.[8] X. fragariae is often spread by infected transplants or systemically infected overwintered plants and dead leaves.[3] It can also be spread plant to plant through water droplets from rain or irrigation.[3] Once X. fragariae lands on a new host, it will enter into the strawberry plant through its open stomata.[8] X. fragariae produces many toxins that are key factors in pathogenesis, including Hemolytic and cytolytic RTX-toxins.[8] X. fragariae, also, uses T3SS to secrete T3E genes: xopN, xopR, xopV to suppress the innate immune response in strawberries.[8]
Disease cycle
The primary source of inoculum is previously infected debris and necrotic plant tissue, as the pathogen itself cannot freely survive in the soil.[5] Strawberry plants that suffer from systemic infection unfortunately have the bacteria in their vascular system. In spring, after the crowns of infected live plants overwinter, the vascularized bacteria become active and begin inducing symptoms. Bacteria oozes out of the leaf lesions, causing the disease to spread when rain splashes the bacteria onto other susceptible plants and enters through natural openings or wounds. [6]
Management
Chemical controls are ineffective against this disease, and the use of copper containing compounds can cause phytotoxicity in the plants. It is best to destroy infected leaves, plants, and debris immediately by burning or burying it.[9] Cultural controls can include choosing a growing site with adequate air circulation, low humidity, and moderate daytime temperatures to promote the drying of plant leaves. Also try to limit the surrounding weeds so that air circulation is not compromised, and use overhead irrigation if available. Avoid harvesting or moving equipment when fields are wet to limit wounding on susceptible plants. Although there are no completely resistant cultivars, using less susceptible cultivars can be a helpful preventative measure. Allstar, Annapolis, Cavendish, Honeoye, and Kent are the least resistant to the disease and should be planted with high caution.[10] Relatively recent studies by Turecheck et al.[5] have shown heat treatments to be successful in dealing with angular leaf spot. They found that the number of living Xanthomonas fragariae were reduced by a minimum of 105-106 CFU/ml after exposing infected plants to heat treatments of 44-48o C for 2–4 hours.[11] At temperatures this high, this bacterial pathogen can be killed on infected plants. It is still unclear how these treatments would be conducted on commercial scales however, so other modes of control are being investigated.
References
- ^ Garrity, George M. (2005). Bergey's manual of systematic bacteriology, Volume Two: The Proteobacteria, Part B: The Gammaproteobacteria. New York: Springer ISBN 0-387-24144-2.
- ^ a b "Angular Leaf Spot of Strawberry". Wisconsin Horticulture. Retrieved 2020-12-10.
- ^ a b c d Heidenreich, Cathy, and Bill Turechek. “Bacterial Angular Leaf Spot of Strawberry.” Cornell University, 1998. https://s3.amazonaws.com/assets.cce.cornell.edu/attachments/21537/strawberry-angularlfspotfs.pdf?1490125142
- ^ "Leaf Scorch of Strawberry | NC State Extension Publications". content.ces.ncsu.edu. Retrieved 2017-12-08.
- ^ a b c d e Turechek, William W.; Peres, Natalia A. "Heat Treatment Effects on Strawberry Plant Survival and Angular Leaf Spot, Caused byXanthomonas fragariae, in Nursery Production". Plant Disease. 93 (3): 299–308. doi:10.1094/pdis-93-3-0299.
- ^ a b "Xanthomonas fragariae (angular leaf spot)". www.cabi.org. Retrieved 2020-12-10.
- ^ "Angular Leafspot of Strawberry | NC State Extension Publications". content.ces.ncsu.edu. Retrieved 2020-12-10.
- ^ a b c d Gétaz, Michael; Puławska, Joanna; Smits, Theo H.M.; Pothier, Joël F. (2020-08-18). "Host–Pathogen Interactions between Xanthomonas fragariae and Its Host Fragaria × ananassa Investigated with a Dual RNA-Seq Analysis". Microorganisms. 8 (8). doi:10.3390/microorganisms8081253. ISSN 2076-2607. PMC 7465820. PMID 32824783.
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: CS1 maint: unflagged free DOI (link) - ^ "Angular Leaf Spot of Strawberry". Wisconsin Horticulture. Retrieved 2017-10-20.
- ^ "Angular Leaf Spot of Strawberry (Bacterial Blight) | Ohioline". ohioline.osu.edu. Retrieved 2017-10-21.
- ^ Turechek, William W.; Peres, Natalia A. "Heat Treatment Effects on Strawberry Plant Survival and Angular Leaf Spot, Caused byXanthomonas fragariae, in Nursery Production". Plant Disease. 93 (3): 299–308. doi:10.1094/pdis-93-3-0299.
- Peres, Natalia A. (2015-01-27). "Angular Leaf Spot of Strawberries". edis.ifas.ufl.edu. Retrieved 2017-10-19.