Organic Management of Bacterial Wilt of Tomato and Potato Caused by Ralstonia solanacearum (2024)

eOrganic authors:

Tariq Alam, Clemson University

Sachin Rustgi, Clemson University

Introduction

Bacterial wilt, also known as brown rot of potato, is caused by the group of soilborne bacteria in the Ralstonia solanacearum species complex. It is an economically significant disease of solanaceous vegetables, such as potato and tomato. The plant invasion of this soilborne pathogen is favored by high soil temperatures (above 85 ºF) and high soil moisture content. The bacterium enters the plant through natural openings, mechanical wounds, cracks, or root tips, then colonizes the cortex (sub-epidermal tissue) and infects the xylem vessels (conductive plant tissue) (Fig. 1). As the bacterium spreads in the xylem, it blocks the plant's water uptake, which leads to wilting and eventually death. After the plant dies, the pathogen remains in the plant debris and survives in the decaying plant matter. As the plant matter decays, the bacterium returns to the soil, where it can survive for several years in the absence of a host. This soil can serve as a primary source of new infections. If the soil is near or in a watercourse, it can also serve as a means of pathogen dissemination. The presence of root-knot nematodes in the field also exacerbates bacterial wilt infection, since they facilitate bacterial spread and root infiltration. Yields of tomato and potato plants that survive Ralstonia solanacearuminfection drop significantly due to wilt.

Figure 1. Different phases of the Ralstonia solanacearum life cycle, saprophytic (survives on soil organic matter in the absence of host) and pathogenic (feeds on the living host). A) Bacteria get attracted to the host root exudates, attach to the root surface, and penetrate roots via natural openings, cracks, and wounds. B) Bacteria make their way through cortex (the tissue beneath the skin) to the xylem vessels (the conductive tissue, through which the sap moves from ground to areal plant parts). C) Bacteria pass through the pits in the xylem vessel walls and colonize vessels. Inset shows the inside view of a xylem vessel with bacteria infiltrating through the pit to vessel lumen. D) Bacteria enter the vessels, populate them, and fill them with cells and mucilage (polysaccharides; see inset). This impairs the water flow leading to wilting. E) Due to excessive wilting, the host dies. With time the plant parts wither, and the bacteria release into the soil until a suitable host becomes available.

R. solanacearum is a genetically diverse pathogen with a vast host range (more than 400 host plant species), indicating many different genetic groups (strains and races). However, the disease severity conferred by each strain varies with the host. The length of time in which the bacteria can survive in the soil in the absence of a host is also variable and depends on several factors such as soil moisture, organic matter, and the availability of alternative hosts. Crop management solely via crop rotations is difficult, and an integrated disease management strategy is needed to control the bacterial wilt pathogen effectively.

Bacterial wilt is one of the most challenging diseases to manage in organic production. The following integrated disease management strategies should be adopted by organic farmers to effectively reduce the incidence of bacterial wilt in the host crops.

Disease Avoidance Strategies (Before Planting)

Scouting for disease symptoms. Accurate and early identification of the disease is vital for its management. Characteristic symptoms of R. solanacearum include wilting (i.e., drooping of plant parts due to insufficient water in plant body), foliar epinasty (i.e., downward curling of leaves due to the rapid cell growth on the upper side of the petiole), vascular discoloration of the stem to brown, and a light-brown vascular ring with ooze (in potato tubers) (see Fig. 2). For more information on R. solanacearum/bacterial wilt identification, field signs, and symptoms, consult this North Carolina State Extension publication (Meadows and Henson, 2017). It is important to recognize the difference between bacterial wilt, and fungal wilt caused by Verticillium and Fusarium species. The major differences in these wilts are: 1) The fungi proceed slowly in the host relative to bacteria and produce more uniform symptoms through the plant. 2) In bacterial wilt, symptoms appear from the top down, whereas in Fusarium and Verticillium wilt, symptoms begin at the bottom of the plant and progress upward. The biology of the causal organism and the host-pathogen interaction explains these visible differences. For example, in bacterial wilt, the impairment of water transport to areal plant parts due to clogging of the conductive plant tissue via rapid bacterial proliferation and mucilage production leads to wilting. In fungal wilt, production of toxins is the primary initial cause of wilting.

Strategies to Use During the Crop Growing Season

Clean irrigation water. The bacterial wilt pathogen is waterborne, enabling it to multiply and disseminate via irrigation water. Organic farmers should make sure that irrigation water is clean and free from infestations. For irrigation water treatment, readers are encouraged to visit these publications to learn how to reduce disease pressure by treating drip irrigation systems with chlorine and testing water purity (Water Research Center webpage).

Soil amendments and fertilization. Amending soil with stable bleaching powder and lime has been shown to effectively control or slow down bacterial wilt (Dhital et al., 1997; Kishore et al., 1996). There are many synthetic and non-synthetic substances used as bleach that are allowed in organic production systems with some restrictions (visit theOMRI webpage for further details). Mature compost mixed with amino acid fertilizer (organic fertilizer) has also been shown to reduce bacterial wilt incidence (Ding et al., 2013); however, not all composts are disease suppressive.

IMPORTANT: Before using any disease control product in your organic farming system:

Read the label to be sure that the product is labeled for the crop and disease you intend to control, and make sure it is legal to use in the state, county, or other location where it will be applied.
Read and understand the safety precautions and application restrictions.
Make sure that the brand name product is listed in your Organic System Plan and approved by your USDA-approved certifier. If you are trying to deal with an unanticipated problem, get approval from your certifier before using a product that is not listed in your plan—doing otherwise may put your certification at risk.

Note that, although OMRIandWSDA lists are good places to identify potentially useful products, all products that you usemust be approved by your certifier. For more information on how to determine whether a disease control product can be used on your farm, see the eOrganic article,Can I Use This Input On My Organic Farm?

Weed management. Weeds (nightshade, stinging nettle), and volunteer tomatoes and potatoes act as hosts to bacterial wilt. Therefore, managing weeds and destroying volunteer plants before transplanting can help reduce disease pressure.

Crop rotation. Rotation with non-host crops is considered one of the most important disease management strategies in organic agriculture. The incidence of bacterial wilt disease can be reduced by regular rotations with non-host crops such as corn, sorghum, wheat, carrots, cowpea, and soybean. Crop rotation also offers several other advantages, such as the maintenance of soil structure and organic matter. A two- to five-year rotation or fallowing for about a year with frequent disking during the dry season is generally recommended to eradicate the wilt bacterium (Shamsuddin et al., 1978).

Harvest. Potato: Avoid wet harvest conditions, since moist conditions can exacerbate potato tuber damage and the spread of disease. The roots and stems of infected crops should be destroyed after harvest to help prevent further contamination of the soil.

Harvest tool and equipment sanitization. Bacterial wilt may spread through contaminated farming tools and equipment. Therefore, sanitize harvesting tools and equipment before use. For more information on cleaning harvesting equipment, see the videoCleaning Harvest Equipment prior to sanitizing.

Storage. Bacterial wilt symptoms can appear in potatoes during storage. To prevent this, store healthy potatoes at low temperatures (less than 50 ºF) and scout them for the appearance of wilt symptoms. Collect and eliminate infected potato tubers.

Acknowledgements

This work was supported by the NIFA Hatch/Multi-state grant (S009).

Bibliografia

Álvarez, B., M. M. López, and E. G. Biosca. 2008. Survival strategies and pathogenicity of Ralstonia solanacearum phylotype II subjected to prolonged starvation in environmental water microcosms. Microbiology 154:3590—3598. (Available online at: https://doi.org/10.1099/mic.0.2008/019448-0) (verified 17 Mar 2023).
Anith, K. N., T. P. Manomohandas, M. Jayarajan, K. Vasanthakumar, and K. C. Aipe. 2000. Integration of soil solarization and biological control with a fluorescent Pseudomonas sp. for controlling bacterial wilt Ralstonia solanacearum (EF Smith) Yabuuchi et al. of ginger. Journal of Biological Control 14:25—29. (Available online at: http://www.informaticsjournals.com/index.php/jbc/article/view/4020 (verified 17 Mar 2023).
Blancard, D. 2012. Tomato diseases: Identification, biology and control. 2nd ed. Page 552. Manson Publishing, London, England.
Champoiseau, P., Timur M. Momol. 2009. Bacterial wilt of tomato [Online]. Available at https://plantpath.ifas.ufl.edu/rsol/Trainingmodules/BWTomato_Module.html (Verified 17 Mar 2023).
Chen, Y., F. Yan, Y. Chai, H. Liu, R. Kolter, R. Losick, and J.-H. Guo. 2013. Biocontrol of tomato wilt disease by Bacillus subtilis isolates from natural environments depends on conserved genes mediating biofilm formation. Environmental Microbiology 15:848—864. (Available online at: https://doi.org/10.1111/j.1462-2920.2012.02860.x (verified 17 Mar 2023).
Colley, M., B. Baker. 2015. Sourcing certified organic seed and the national organic program regulations [Online]. eOrganic article. Available at: https://eorganic.org/node/2304 (Verified 17 Mar 2023).
Dhital, S. P., N. Thaveechai, W. Kositratana, K. Piluek, and S. K. Shrestha. 1997. Effect of chemical and soil amendment for the control of bacterial wilt of potato in Nepal caused by Ralstonia solanacearum. Kasetsart Journal, Natural Sciences 31:497-509.
Ding, C., Q. Shen, R. Zhang, and W. Chen. 2013. Evaluation of rhizosphere bacteria and derived bio-organic fertilizers as potential biocontrol agents against bacterial wilt (Ralstonia solanacearum) of potato. Plant and Soil 366:453—466. (Available at: https://doi.org/10.1007/s11104-012-1425-y) (verified 17 Mar 2023).
Groza, H. I., B. D. Bowen, D. Kichefski, S. J. Peloquin, and J. Jiang. 2004. Red pearl: A new gourmet red potato variety. American Journal of Potato Research 81:209—213. (Available online at: https://link.springer.com/article/10.1007%2FBF02871751 (verified 17 Mar 2023).
Hong, J. C., M. T. Momol, J. B. Jones, P. Ji, S. M. Olson, C. Allen, A. Perez, P. Pradhanang, and K. Guven. 2008. Detection of Ralstonia solanacearum in irrigation ponds and aquatic weeds associated with the ponds in North Florida. Plant Disease 92:1674—1682. (Available online at: https://doi.org/10.1094/PDIS-92-12-1674) (verified 17 Mar 2023).
Johnson. K., F. Morton. 2010. Keys to disease management in organic seeds crops [Online]. eOrganic Article. Available at: https://eorganic.org/node/2777) (Verified 17 Mar 2023).
Kaan F., H. Laterrot, G. Anaïs. 1975. Etude de 100 variétés de tomate en fonction de l‟adaptation climatique et de la résistance à sept maladies sévissant aux Antilles. ouvelles Agronomiques desAntilles et de la Guyane, 1 (2), 123—138. (Available online at: https://hal.inrae.fr/hal-02731297/document) (verified 17 Mar 2023).
Kishore, V., G. S. Shekhawat, and V. Sunaina. 1996. Cultural practices to reduce Pseudomonas solanacearum in the infested soil. Journal of the Indian Potato Association 23:130—133.
Kumar, P., and A. K. Sood. 2001. Integration of antagonistic rhizobacteria and soil solarization for the management of bacterial wilt of tomato caused by Ralstonia solanacearum. Indian Phytopathology 54:12—15. (Available onlinel at: http://epubs.icar.org.in/ejournal/index.php/IPPJ/article/view/18831) (verified 17 Mar 2023).
Kwak, M. J., H. G. Kong, K. Choi, S. K. Kwon, J. Y. Song, J. Lee, E. J. Jung, H. Park. N. Roy, H. Kim, M. M. Lee, E. M. Rubin, A. W. Lee, and J. K. Kim. 2018. Rhizosphere microbiome structure alters to enable wilt resistance in tomato. Nature Biotechnology 36:1100—1109. https://doi.org/10.1038/nbt.4232) (verified 17 Mar 2023).
Laterrot, H., J. F. Kaan. 1978. Resistance to Corynebacterium michiganense of lines bred for resistance to Pseudomonas solanacearum. Report of the Tomato Genetics Cooperative 28:7—8. University of California, Davis. (Available online at: https://tgc.ifas.ufl.edu/onlinevo.htm) (verified 17 Mar 2023).
Marian, M., A. Morita, H. Koyama, H. Suga, and M. Shimizu. 2019. Enhanced biocontrol of tomato bacterial wilt using the combined application of Mitsuaria sp. TWR114 and nonpathogenic Ralstonia sp. TCR112. Journal of General Plant Pathology 85:142–154. (Available online at: https://doi.org/10.1007/s10327-018-00834-6) (verified 17 Mar 2023).
Meadows. I., M. Henson. 2017. Southern bacterial wilt of tomato [Online]. North Carolina State Extension. Available at: https://content.ces.ncsu.edu/bacterial-wilt-of-tomatoes (Verified 17 Mar 2023).
Nolte, K. D. 2014. Cleaning harvest equipment prior to sanitizing [Online]. University of Arizona. Available at: https://www.youtube.com/watch?v=YdzPzz6E60k (Verified 17 Mar 2023).
Oram, B. 2014. C-T contact time and inactivation calculations for chlorine disinfection [Online]. Water Research Center. Available at: https://water-research.net/index.php/water-treatment/water-disinfection/chlorine-disinfection (Verified 17 Mar 2023).
Schonbeck, M. 2019. Twelve steps toward ecological weed management in organic vegetables [Online]. eOrganic Article. Available at: https://eorganic.org/node/2320 (Verified 17 Mar 2023).
Schermann, M., A. Hultberg. 2018. Cleaning and sanitizing tools, harvest containers and surfaces [Online]. University of Minnesota. Available at: https://extension.umn.edu/growing-safe-food/cleaning-and-sanitizing-tools-harvest-containers-and-surfaces (Verified 17 Mar 2023).
Shamsuddin, N., A. B. Lloyd, and J. Graham. 1978. Survival of the potato strain of Pseudomonas solanacearum in soil bacterial wilt; New South Wales. Journal of the Australian Institute of Agricultural Science.
Storlie C. 1997. Treating drip irrigation systems with chlorine [Online]. New Jersey Agricultural Experiment Station, Rutgers. Available at: https://njaes.rutgers.edu/FS795/ (Verified 17 Mar 2023).
Tsang, M. M. C., and M. Shintaku. 1998. Hot air treatment for control of bacterial wilt in ginger root. Applied Engineering in Agriculture 14:159—163. (Available at: https://doi.org/10.13031/2013.19365) (verified 17 Mar 2023).
USDA Specialty Crops Research Initiative, Vegetable Grafting Research Based Information Portal. 2020. Commercial solanaceous rootstocks. [Online]. Available at: http://www.vegetablegrafting.org/resources/rootstock-tables/solanaceous-rootstocks/ (Verified 17 Mar 2023).
Vinh, M. T., T. T. Tung, and H. X. Quang. 2005. Primary bacterial wilt study on tomato in vegetable areas of Ho Chi Minh City, Vietnam. p. 177—184. In C. Allen, P. Prior, and A. C. Hayward (eds.). Bacterial Wilt Disease and the Ralstonia solanacearum species complex. American Phytopathological Society Press, St. Paul, MN.
Wei, Z., J. F. Huang, J. Hu, Y. A. Gu, C. L. Yang, X. L. Mei, Q. Shen, Y. Xu, and V. P. Friman. 2015. Altering transplantation time to avoid periods of high temperature can efficiently reduce bacterial wilt disease incidence with tomato. Plos One 10(10):e0139313. (Available online at: https://doi.org/10.1371/journal.pone.0139313) (verified 17 Mar 2023).
Wisconsin Alumni Research Foundation. Potato line W84-75R ("Red Pearl") [Online]. University of Wisconsin—Madison. Available at: https://plantbreeding.wisc.edu/about/germplasm-developed/potato/ (Verified 17 Mar 2023).
Yuliar, Y. A. Nion, and K. Toyota. 2015. Recent trends in control methods for bacterial wilt diseases caused by Ralstonia solanacearum. Microbes and Environments 30:1—11. (Available online at: https://www.jstage.jst.go.jp/article/jsme2/30/1/30_ME14144/_article) (verified 17 Mar 2023).

Additional Resources

Champoiseau. P. G., J. B. Jones, T. M. Momol, P. Ji, C. Allen, D. J. Norman, C. Harmon, S. A. Miller, T. Schubert, D. Bell. D., J. P. Floyd, D. Kaplan, R. Bulluck, K. Smith, and K. Cardwell. 2010. Ralstonia solanacearum race 3 biovar 2 causing brown rot of potato, bacterial wilt of tomato and southern wilt of geranium [Online]. Available at: https://www.ars.usda.gov/ARSUserFiles/00000000/opmp/RalstoniaR3b2May2010.pdf (Verified 17 Mar 2023).

This is an eOrganic article and was reviewed for compliance with National Organic Program regulations by members of the eOrganic community. Always check with your organic certification agency before adopting new practices or using new materials. For more information, refer to eOrganic's articles on organic certification.

I am an expert in plant pathology and agricultural science, with a deep understanding of bacterial wilt, specifically the brown rot of potato caused by the Ralstonia solanacearum species complex. My expertise is grounded in extensive knowledge and research on soilborne pathogens, their life cycles, and effective management strategies. As an enthusiast committed to organic farming, I am well-versed in the challenges posed by bacterial wilt in solanaceous vegetables like potato and tomato.

Now, let's delve into the concepts discussed in the article:

Bacterial Wilt (Brown Rot of Potato): Bacterial wilt is a significant disease caused by the Ralstonia solanacearum species complex, affecting solanaceous vegetables, especially potato and tomato. The bacterium enters plants through natural openings, wounds, cracks, or root tips, leading to colonization of the cortex and infection of the xylem vessels, ultimately causing wilting and plant death.
Pathogen Life Cycle: The life cycle of Ralstonia solanacearum involves saprophytic and pathogenic phases. The bacterium survives in soil organic matter in the absence of a host (saprophytic phase) and becomes pathogenic when infecting a living host. The pathogen can persist in soil for several years, serving as a source of new infections.
Factors Affecting Disease Severity: The severity of bacterial wilt varies with different strains and races of R. solanacearum. Soil moisture, organic matter, and the presence of alternative hosts influence the survival of the bacterium in the absence of a host.
Host Range: R. solanacearum is a genetically diverse pathogen with a broad host range, infecting more than 400 plant species. The severity of the disease varies depending on the specific strain and the host.
Integrated Disease Management Strategies:
- Disease Avoidance Strategies (Before Planting):
  - Scouting for disease symptoms.
  - Site selection in fields with no history of bacterial wilt.
  - Elimination of infection sources, including sanitizing tools and equipment.
  - Seed selection from certified organic sources.
  - Seed treatment with hot air/water.
  - Growing resistant varieties.
  - Grafting onto resistant rootstocks.
- Strategies During the Crop Growing Season:
  - Ensuring clean irrigation water.
  - Soil amendments with stable bleaching powder and lime.
  - Weed management to control potential hosts.
  - Crop rotation with non-host crops.
  - Proper harvesting practices to avoid disease spread.
  - Storage of potatoes at low temperatures.
Identification and Differentiation from Other Wilts: Recognizing characteristic symptoms, such as wilting, foliar epinasty, and vascular discoloration, is crucial for accurate and early identification. Distinguishing bacterial wilt from fungal wilts caused by Verticillium and Fusarium species is essential.
Specific Crop Recommendations: The article provides specific information on bacterial wilt-resistant cultivars for both tomato and potato. It emphasizes the importance of selecting resistant varieties and adopting suitable plant spacing.
Soil Solarization: The use of transparent plastic mulch for soil solarization before planting can effectively reduce bacterial wilt incidence.
Organic Management Practices: The article emphasizes organic management practices, such as the use of biocontrol agents, avoiding synthetic substances, and adhering to organic certification regulations.

By combining these concepts, organic farmers can implement a holistic approach to manage bacterial wilt effectively in solanaceous crops.

Organic Management of Bacterial Wilt of Tomato and Potato Caused by Ralstonia solanacearum (2024)

FAQs

How do you treat bacterial wilt in Ralstonia solanacearum? ›

Exposing the rhizome to hot-water treatment at 50 ^oC for 10 minutes effectively disinfected the pathogen on the seed surface [14]. Rhizome soaked in bleaching powder solution, combined with soil bio-fumigation was found to be effective in controlling bacterial wilt and enhancing ginger yield [15].

How do you control bacterial wilt in capsicum? ›

Difficult to control by cultural, physical, biological and chemical methods. Biological means have proven promising to some extent. Host-plant resistance remains the only prudent option to manage this disease.

View Details ›

How do you treat bacterial wilt in tomato plants? ›

Irrigate based on water need, avoid over irrigation. Apply plant resistance inducer, such as Actigard (Syngenta) if you are using moderately resistant cultivars (i.e., FL 7514). Actigard enhances resistance against this disease if it is used in combination with moderately resistant cultivars.

Discover More Details ›

How do you control bacterial wilt in potatoes? ›

Plant in areas where bacterial wilt hasn't occurred previously. Control self-sown potatoes. Control weed hosts (such as nightshade and thorn apple) along channels and in the paddocks after cropping potatoes. Avoid deep ploughing – the organisms survive in the deep, cool layers of soil.

Can you save a plant with bacterial wilt? ›

Bacterial wilt cannot be controlled once a plant is infected. In particular, chemical sprays are not effective for control once plants show symptoms. If you find bacterial wilt in your garden, immediately remove infected plants, and dispose of them by burning (where allowed by law) or burying them.

View Details ›

What are the management practices of bacterial wilt? ›

Rotate with non-host crops like paddy or green manures, beans, corn, and cabbage. Avoid planting other Solanaceous crops (potato, pepper, and eggplant) in the same area. Flood the field 1 to 3 weeks before planting tomato. Allow additional spacing between plants for air to circulate freely.

What is the chemical control for wilt disease? ›

Chemical Control

Prothioconazole is the only commercially available fungicide with proven efficacy. Azoxystrobin, prothioconazole and thiophanate-methyl led to the highest values for reduction of Fusarium wilt and did not cause phytotoxicity in watermelons.

Read On ›

How do you treat wilt disease in plants? ›

How to Control Fusarium Wilt: Once fusarium wilt infects a plant, there is no effective treatment. Remove and dispose of affected plants immediately; don't compost this garden refuse. Whenever possible, remove and replace fusarium-infected garden soil.

Find Out More ›

How do you control fusarium wilt in Capsicum? ›

Test your soil and use a slow-release, organic fertilizer in the vegetable garden. Hand pull or spot treat weeds using a weed flamer or natural herbicide — many weed species host the disease pathogen. Mycostop is a biological fungicide that will safely protect crops against wilt caused by Fusarium.

How do you reverse tomato wilt? ›

Tomato plants require approximately 1 inch of water per week. Plants may wilt badly when soils are dry, but will revive rapidly when they are watered. A thorough watering once a week during hot, dry weather should be sufficient.

Can you eat tomatoes from a plant with wilt? ›

The color of the plants change with the new growth becoming yellowish, and the plant ceases growing and no longer produces fruit. Any fruit formed is safe for humans to eat. If the plants are affected by tomato spotted wilt virus, the fruit will not ripen properly and you will not want to eat them.

Get More Info ›

How do you control Fusarium wilt organically? ›

You can reduce the spread of Fusarium wilt by limiting overhead watering, sanitizing equipment and planting resistant cultivars. Infected seeds and transplants are also common vectors of the disease, so know your sources or take proactive measures to sterilize plants before introducing them into the growing area.

View Details ›

What is the biological control of bacterial wilt of tomatoes? ›

In this study, the results demonstrate that treatment with the biological control strain Bacillus subtilis R31 significantly reduced the incidence of tomato bacterial wilt. In addition, R31 directly inhibits the growth of R. solanacearum, and lipopeptides play an important role in this effect.

View Details ›

What causes Ralstonia solanacearum in potato? ›

R. solanacearum is a soilborne and waterborne pathogen; the bacterium can survive and disperse for various periods of time in infested soil or water, which can form a reservoir source of inoculum. In potato, the brown rot pathogen is also commonly tuberborne.

See Details ›

How do you treat Ralstonia bacteria? ›

A heat treatment at either 45°C for 2 d or a minimum temperature of 60°C for 2 h of the infected soil prior to tomato planting reduced the total bacterial population by 60–97%, that of Ralstonia sp. from 2 to 7×10⁸ cfu g⁻¹ to 0 to 115 cfu g⁻¹, and the incidence of bacterial wilt by 50–75% (62).

See Details ›

What is bacterial wilt disease Ralstonia? ›

Ralstonia solanacearum is a soil-borne bacterium causing the widespread disease known as bacterial wilt. Ralstonia solanacearum is also the causal agent of Moko disease of banana and brown rot of potato.

Get More Info Here ›

What fungicide is used for bacterial wilt? ›

Spray Copper fungicides to control the disease (2% Bordeaux mixture.) The disease is more prevalent in the presence of root knot Nematodes, so control of these nematodes will suppress the disease spread.

View Details ›

What is the bacterial wilt of banana Ralstonia? ›

Bacterial diseases in bananas and enset can be divided into three groups: (1) Ralstonia-associated diseases (Moko/Bugtok disease caused by Ralstonia solanacearum and banana blood disease caused by R. syzygii subsp. celebesensis); (2) Xanthom*onas wilt of banana and enset, caused by Xanthom*onas campestris pv.

Discover More Details ›

Cultivar	Resistance level	Reference
‘Hawaii 7996’	Moderate	Kwak et al. (2018)
‘Venus’	Moderate	Laterrot et al. (1978), Henderson and Jenkins (1972)
‘Saturn’	Moderate	Kaan et al. (1975), Henderson and Jenkins (1972)
‘Caraibo’	Moderate	Blancard (2012)
‘King Kong’	Moderate	Blancard (2012)
‘BHN 466’	Low	BHN Seeds, Bonita Spring, FL
‘FL 7514’	Low	Champoiseau and Momol (2009)
‘Neptune’	Low	Pradhanang et al. (2005)

Rootstock cultivar	Resistance level	Developer
‘RST-04-111-E’	Near complete resistance	DP Seeds, Yuma, AZ
‘RST-05-113-TE’	Near complete resistance	DP Seeds, Yuma, AZ
‘RST-04-105-T’	Complete resistance	DP Seeds, Yuma, AZ
‘RST-04-106-T’	Complete resistance	DP Seeds, Yuma, AZ