Everything about Sudden Oak Death totally explained
Sudden Oak Death is the common name of a disease caused by the
oomycete plant pathogen Phytothphora ramorum. The disease kills
oak and other species of tree and has had devastating effects on the oak populations in
California and
Oregon as well as also being present in
Europe. Symptoms include bleeding cankers on the tree’s
trunk and dieback of the
foliage, in many cases eventually leading the death of the tree.
P. ramorum also infects a great number of other plant species, significantly
rhododendrons, causing a non-fatal foliage disease known as ramorum dieback. Such plants can act as a source of the
inoculum for the disease, with the pathogen producing
spores that can be transmitted by
wind and
rainwater.
P. ramorum was first reported in
1995, and the origins of the pathogen are still unclear but most evidence suggests it was introduced as an exotic species. Very little control mechanisms exist for the disease, and they rely upon early detection and proper disposal of infected plant material.
Presence
The disease is known to exist in California's coastal region between
Big Sur (in
Monterey County) and southern
Humboldt County. It is confirmed to exist in all coastal counties in this range, as well as in all immediately inland counties from
Santa Clara County north to
Lake County. It hasn't been found east of the
California Coast Ranges, however. It was reported in
Curry County, Oregon (just north of the California border) in 2002.
(External Link
) About the same time, a similar disease in continental
Europe and the
UK was identified as
Phytophthora ramorum.
Hosts and symptoms
It was first discovered in
California in
1995 when large numbers of
tan oaks (
Lithocarpus densiflorus) died mysteriously, and was described as a new species of
Phytophthora in
2000. It has subsequently been found in many other areas including
Britain,
Germany, and some other
U.S. states, either accidentally introduced in nursery stock, or already present undetected.
In tan oaks, the disease may be recognized by
wilting new
shoots, older leaves becoming pale green, and after a period of two to three weeks, foliage turns brown while clinging to the branches. Dark brown
sap may stain the lower trunk's bark. Bark may split and exude gum, with visible discoloration. After the tree dies, suckers will sprout next year, but their tips soon bend and die.
Ambrosia beetles (
Monarthrum scutellare) will most likely infest a dying tree during midsummer, producing piles of fine white dust near tiny holes. Later,
bark beetles (
Pseudopityophthorus pubipennis) produce fine red boring dust. Small black domes, the fruiting bodies of the
Hypoxylon fungus, may also be present on the
bark. Leaf death may occur more than a year after the initial infection and months after the tree has been girdled by beetles.
In
Coast Live Oaks and
Black Oaks, the first symptom is a burgundy-red to tar-black thick sap bleeding from the bark surface. These are often referred to as bleeding
cankers.
In addition to oaks, many other forest species may be hosts for the disease, in fact it was observed in the USA that nearly all woody plants in some
Californian forests were susceptible to
P. ramorum. including
rhododendron,
Madrone (
Arbutus menziesii), Evergreen
Huckleberry (
Vaccinium ovatum),
California Bay Laurel (
Umbellularia californica),
Buckeye (
Aesculus californica),
Bigleaf Maple (
Acer macrophyllum),
Toyon (
Heteromeles arbutifolia),
manzanita (
Arctostaphylos spp.),
Coast Redwood (
Sequoia sempervirens),
Douglas Fir (
Pseudotsuga menziesii),
Coffeeberry (
Rhamnus californica),
Honeysuckle (
Lonicera hispidula) and
Shreve's Oak (
Quercus parvula v.
shrevei).
P. ramorum more commonly causes a less severe disease known as Ramorum dieback/leaf blight on these
hosts. Characteristic symptoms are dark spots on
foliage and in some hosts the dieback of the stems and twigs. The disease is capable of killing some hosts, such as Rhododendron, but most survive. Disease progression on these species isn't well documented but hikers have observed dead Douglas Firs with massive quantities of red frass surrounding their base. Redwoods exhibit needle discoloration and cankers on small branches, with purple lesions on sprouts that may lead to sprout mortality.
Transmission
P. ramorum produces both resting
spores (chlamydospores) and
zoospores, which have
flagella enabling
swimming.
P. ramorum is spread by air; one of the major mechanisms of
dispersal is
rainwater splashing spores onto other susceptible plants, and into
watercourses to be carried for greater distances.
Chlamydospores can withstand harsh conditions and are able to overwinter.
As mentioned above,
P. ramorum doesn't kill every plant that can be used as a
host, and it's these plants that are most important in the
epidemiology of the disease as they act as sources of
inoculum. In the USA
bay laurel seems to be the main source of inoculum in forests. Green waste, such as leaf litter and tree stumps are also capable of supporting
P. ramorum as a
saprotroph and acting as a source of inoculum. Because
P. ramorum is able to infect many
ornamental plants, it can be transmitted by ornamental plant movement.
Hikers,
mountain bikers,
equestrians, and other people engaged in various outdoor activities may also unwittingly move the pathogen into areas where it wasn't previously present. If you're travelling in an area known to be infested with SOD, you can help prevent the spread of the disease by cleaning your (and your animal's) feet, tires, tools, camping equipment, etc. before returning home or entering another uninfected area, especially if you've been in muddy soil.
The two mating types
P. ramorum is
heterothallic and has two
mating types identified: A1 and A2. Interestingly A1 is found almost exclusively in
Europe and A2 in
North America. Genetics of the two isolates indicate that they're reproductively
isolated. On average the A1 mating type is more virulent than the A2 mating type but there's more variation in the pathogenicity of A2 isolates. Because of the genetic and pathological differences it's believed that if the two mating types remain reproductively isolated then two
sub-species will be formed.
Possible origins
P. ramorum is a relatively new disease, and there have been several debates about where it may have originated or how it evolved.
Introduction as an exotic species
Evidence exists that suggests
P. ramorum may be an introduced
exotic species, and that these introductions occurred separately for the European and NA populations, hence why only one mating type exists on each continent – this is called a
founder effect. The differences between the two populations are thus caused by adaptation to separate climates. Evidence includes little genetic variability, as
Phytophthora ramorum hasn't had time to diversify since being recently introduced. What variability there's may be explained by multiple introductions with a few individuals adapting best to their respective environments. The behavior of the pathogen in California is also indicative of being introduced; it's assumed that such a high mortality rate of trees would have been noticed sooner if
P. ramorum was
native.
Where
Phytophthora ramorum did originate remains unclear but most researchers feel
Asia is the most likely, since many of the hosts of
P. ramorum originated there. Since certain climates are best suited to
P. ramorum, the most likely sources are the Southern
Himalayas,
Tibet or
Yunnan province.
Hybridization events
Species of
Phytophthora have been shown to have evolved by the
interspecific hybridization of two different species from the
genus. When a species is introduced into a new
environment it causes
episodic selection. The invading species is exposed to other resident
taxa, and hybridization may occur to produce a new species. If these hybrids are successful, they may out compete their parent species. Thus it's possible that
Phytophthora ramorum is a hybrid between two species. Its unique
morphology does support this. Also, 3 sequences that were studied to establish the phylogeny of
Phytophthora: ITS, cox II and nad 5, were identical supporting
Phytophthora ramorum having recently evolved.
A native organism
It is possible that
Phytophthora ramorum is a native organism. Infection rates could have previously been at a low level, but changes in the environment caused a change to the
population structure. Alternatively, the symptoms of
Phytophthora ramorum may have been mistaken for that of other pathogens. When SOD first appeared in the USA, many other pathogens and conditions were blamed before
P. ramorum was found to be the causal agent. With many of the most seriously affected plants being in the forest, the likelihood of seeing diseased trees is also low.
Control
Early detection
Early detection of
P. ramorum is essential for its control, as most studies have shown that treatments work best if applied preventively to stop infection. Techniques were developed to detect
P. ramorum even before it becomes symptomatic. One of the most successful techniques uses a real time
polymerase chain reaction assay. Researchers developed PCR
primers specific to the
ITS region of the
genome so that
DNA is only amplified if it belongs to
P. ramorum. The method is more sensitive than direct
culturing, the classical method of pathogen identification. Because
fluorescence occurs every time the DNA is replicated, it also allows an accurate
quantification of the level of infection. A Pocket Diagnostic on-site test (
lateral flow device) is available that can detect any members of the genus
Phytophthora and this is useful for field situations. This test is used by plant health inspectors worldwide at the point of inspection. Researchers are investigating
microsatellite markers in the pathogens genome, that can be used to detect the pathogen and establish the mating type.
Researchers have built computer models that
predict areas at high risk of epidemic
P. ramorum based on the preferred
climate and hosts of the pathogen. The models predict infections before they emerge, and areas at high risk can be closely monitored and given preventative treatment.
Chemical control
Several compounds have been identified that are effective against
P. ramorum. The most successful compound to be tested was
metalaxyl, but at least one
resistant strain of
P. ramorum has emerged. Because of this it's recommended metalaxyl isn't used. One of the most effective treatments involves injecting
phosphonate into the
trunk of the plant. This works best preventively, but also is able to reduce canker size and prolong the life of the tree if applied soon after the symptoms develop. Injection or application directly to the bark when coupled with an
organosilicate is the only known viable way to deliver the
fungicide.
Copper compounds may also be used for a preventative coating of the trunk.
Disposal of infected plant material
In general, when plants are found to be infected with
P. ramorum they're cut and burned, along with any surrounding host plants regardless of infection status. This technique has its problems, as the pathogen can survive in the tree stumps, soil, and water as well as re-infecting any sprouts. One solution involves spraying stumps with
herbicides to prevent such sprouting. Another way to deal with infected plant material, more specifically
green waste, utilizes
composting. Because
P. ramorum is a cool climate pathogen, the high heat involved in the incubation of compost kills the pathogen after two weeks, including the resting spores.
Further Information
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