Peach (Prunus persica)-Bacterial Canker

Latest revision: 
March 2024

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Cause Pseudomonas syringae pv. syringae, a bacterium. This disease can be the limiting factor against establishing a peach orchard anywhere in the Pacific Northwest. Although the bacteria survive on the outside of the plant they must get inside and multiply in the space between plant cells (apoplast) to cause disease. These pathogenic bacteria inject several proteins and small-molecule toxins to get past host immune mechanisms. Once inside, the bacteria induce a watery, nutrient rich environment between the plant cells where they can multiply and continue colonization of the plant tissues. Bacteria also produce a protein that acts as an ice nucleus, increasing frost wounds that bacteria easily colonize and expand. Factors that weaken or injure the tree predispose it to developing cankers. These factors include wounds, frost damage, early dormant season pruning, heading cuts, incorrect soil pH, and poor nutrition. Important avenues of infection leading to tree death include natural leaf scars in the fall and heading cuts made in the spring after planting a new orchard. Infection by other pathogens including Cytospora, Verticillium, and Nectria can lead to more bacterial canker. Ring nematodes have also been associated with increased susceptibility to bacteria canker in both cherry and peach. Sources of bacteria include old cankers, healthy buds, systemic infections within trees (with or without cankers), as epiphytes on leaf surfaces, weeds, grasses, and even soil. Wind, rain, insects, infected bud wood, and infected nursery stock can spread bacteria. Pruning through cankered and then through susceptible, healthy tissue does not spread the disease.

Although bacterial canker is more serious on sweet cherry trees, it also affects almonds, apricots, peaches, plums, and prunes. The peach cultivar Rochester is very susceptible to canker. The same bacterium also can cause a blight of many other fruit, vegetable, and ornamental crops.

Symptoms The most conspicuous symptoms are cankers, gum exudation, and dieback of girdled branches. Dead buds and leaf spots also can occur. In most cases, heavy gumming is associated with bacterial canker formation on branches and twigs. Gumming occurs at the cankers' margins, however, other problems can also lead to gumming.

Cankers caused by the bacteria may be on the trunk, limbs, and twigs. Typical cankers are much longer than broad, but a canker may girdle the infected limb or trunk. The cambium at the canker will be discolored and necrotic. Use a pocket knife to reveal this discolored tissue. Cankers develop in winter and early spring. As the tree begins growth in spring, the bacteria population declines and a callus layer forms around the canker's edge. During spring and summer, girdled and nearly girdled limbs may leaf out. Normally, leaves turn yellow, then the limbs usually die. In some instances, these symptoms may not appear until late summer when the leaves' water requirement is high.

Cultural control Bacterial canker is best managed through the use of many different tactics.

  • Plant resistant cultivars and/or rootstocks.
  • Do not interplant new trees with old trees, which are a major source of the bacteria.
  • Locate orchard in an area less likely to be affected by frost. If planting in the spring, plant orchards after date that frost is likely to have occurred. Prevent winter injury by painting trunks white and avoiding late season fertility.
  • Test soil for ring nematodes before planting. Also test for pH and other physical characteristics that can be corrected prior to planting.
  • Provide optimal soil conditions for growing peaches including attention to pH and nutrition. Annually monitor for adequate nutrient levels such as nitrogen. Keep irrigation off above ground parts for the first few years.
  • Control weeds.
  • Delay dormant pruning until January or February. Summer pruning is even better and should be after harvest, when weather is dry. Make heading cuts after planting only during dry weather when rain will not occur for at least a week after pruning. Make heading cuts close to a lateral bud.
  • Completely remove infected trees or branches girdled and killed by cankers. Do not allow trees to regrow from roots or trunks left after a major trunk canker has been removed.
  • In summer, small cankers may be cut out using the following method. Cut away bark above and around the edges of the infected area. Use sharp tools, and leave wound margins smooth and neat. Wounds should be left uncovered to dry out during the summer. Try not to have sprinkler irrigation soak the wounds. Sterilize all pruning tools between cuts with an appropriate disinfectant.
  • Cauterizing cankers using a hand-held propane burner has been used with some success in New Zealand.

Chemical control Copper-based products have not worked well under conditions favorable for disease development. Bacteria resistant to copper products have been detected throughout our peach growing regions, which compromises chemical control tactics. In small plot disease control trials it is not unusual to find copper-treated trees with more disease than trees without any treatment. Heavy use of copper products is not recommended as concentrations in the soil can build up to toxic levels after several decades of use. Resistance to antibiotic can develop quickly even with minimal use. Minimize the use of Kasumin by using it to protect trees after planting when making heading cuts and once during early flowering.

Focus on cultural control tactics first and supplement with chemical control. Traditional recommendations encourage the first spray to occur in October before fall rains followed by another application in early January. Growers should consider adjusting the timing of sprays to coincide with leaf fall. Thorough coverage is needed. Protecting heading cuts made after planting a new orchard is also important. Protect both orchard and nursery trees (sweet cherry, prune, and plum). Some growers use low rates of copper-based products during bud break to reduce symptoms of dead bud.

  • Copper-based products have not worked well and are discouraged due to the prevalence of resistant bacteria and at times increased disease.
    • Badge X2 at 3.5 to 14 lb/A. Group M1 fungicide. 48-hr reentry. O
    • Bonide Liquid Copper Fungicide at 0.5 to 2 fl oz/gal. H
    • Champ WG at 8 to 16 lb/A. Group M1 fungicide. 48-hr reentry.
    • C-O-C-S WDG at 8 to 15.5 lb/A plus dormant spray oil. Group M1 fungicide. 48-hr reentry.
    • CS 2005 at 51.2 to 64 oz/A. Group M1 fungicide. 48-hr reentry.
    • Cueva at 0.5 to 2 gal/100 gal water/A. Group M1 fungicide. 4-hr reentry. O
    • Cuprofix Ultra 40 Disperss at 5 to 8 lb/A. Group M1 fungicide. 48-hr reentry.
    • Kocide 50 DF at 8 to 16 lb/A plus 1 pint superior-type oil/100 gal water. Group M1 fungicide. 48-hr reentry.
    • Monterey Liqui-Cop at 1.5 teaspoons/gal water. H
    • Nordox 75 WG at 5 to 13 lb/A. Group M1 fungicide 12-hr reentry. O
    • Nu-Cop 50 DF at 8 to 16 lb/A. Group M1 fungicide. 48-hr reentry. O
  • Dart at 64 fl oz/100 gal water during late dormancy. Spray with continuous agitation. 24-hr reentry. O
  • Rex Lime Sulfur Solution (28%) at 6 to 12 gal/100 gal water delayed dormant may have some utility. 48-hr reentry. O
  • Vacciplant at 14 to 60 fl oz/A plus an effective bactericide. Can be used day of harvest. Unknown efficacy in the PNW. Group P4 fungicide. 4-hr reentry.
  • Surface disinfectants such as OxiDate 2.0 at 0.25 to 2.5 gal gal/100 gal water are registered but have very short residual activity. Efficacy of these products has not been extensively tested in the PNW. Frequent use (every few days) is on the label, which still may not be effective during conditions favorable for bacterial growth and infection.

Biological control Although registered, the few that have been tested on similar diseases in the Willamette Valley have had none to poor efficacy.

  • Aviv (Bacillus subtilis strain IAB/BS03) at 10 to 30 fl oz/100 gal water. Unknown efficacy. Preharvest interval not specified. 4-hr reentry. O
  • Double Nickel 55 (Bacillus amyloliquefaciens strain D747) at 0.25 to 3 lb/A. Unknown efficacy. Group BM02 fungicide. 4-hr reentry. O
  • Serenade OPTI (Bacillus subtilis strain QST 713) at 14 to 20 oz /A. Active ingredient is a small protein. Unknown effectiveness in the PNW. 4-hr reentry. O
  • Serenade Garden Disease Control Concentrate at 2 to 4 fl oz/gal water. Unknown effectiveness in the PNW. H O

Reference Cao, T., McKenry, M.V., Duncan, R.A., DeJong, T.M., Kirkpatrick, B.C., and Shackel, K.A. 2006. Influence of ring nematode infestation and calcium, nitrogen, and indoleacetic acid applications on peach susceptibility to Pseudomonas syringae pv. syringae. Phytopathology 96:608-615.