Bursaphelenchus xylophilus

Pine wood nematode
This Austrian pine has pine wilt, caused by the pine wood nematode.
Scientific classification
Kingdom: Animalia
Phylum: Nematoda
Class: Secernentea
Subclass: Tylenchia
Order: Aphelenchida
Superfamily: Aphelenchoidoidea
Family: Parasitaphelenchidae
Subfamily: Bursaphelenchinae
Genus: Bursaphelenchus
Species: B. xylophilus
Binomial name
Bursaphelenchus xylophilus

Bursaphelenchus xylophilus, commonly known as pine wood nematode or pine wilt nematode (PWN), is a nematode (worm) that infects pine trees and causes pine wilt.[1][2][3] It originates from North America, but has now spread to Europe and East Asia and has become a worldwide quarantine pest.

It is particularly damaging to matsutake mushroom cultivation, given as how the worms damage and kill the mushrooms' host trees.

This parasite is a tree killer, and it does serious damage to pine trees. Once trees are detected with this disease, they will die in a couple weeks or a couple of months.

Contents

Distribution

Originally thought to be native to North America, the PWN has now spread overseas to countries such as Japan, China, Vietnam, and Portugal, where it has caused severe damage in certain species of pine. Perhaps the most notable PWN epidemic has occurred in Japan, where pine wilt is credited with the destruction of some 26 million cubic meters of timber since WWII.[4][5][6][7]

Pine wilt, as a disease, was first identified in Japan in 1905. Recent research has now indicated it may have originated from Japan and Asia.and been transferred via shipping. It was found in the United States in Missouri in 1931. PWN was identified as the pathogen responsible for pine wilt in 1979.[8]

Morphology

Distinguishing PWN from other non-pathogenic species within the same genus (Bursaphelenchus) is challenging due to highly similar morphological features, but a positive ID can be achieved using molecular analyses such as RFLP.[4][9]

B. xylophilus is distinguished by three characteristics: The spicules are flattened into a disc-like structure, also known as the cuculus, at the distal end. Their anterior vulval lip has a distinct overlapping flap and the posterior end of the female body is rounded in nearly all of the individuals. [10]

Life Cycle/ reproduction

The basic propagative lifecycle of the PWN is typical of most nematode species, having four vermiform juvenile stages (J1-J4), followed by an amphimictic (male and female) adult stage.This basic life cycle takes place in dead or dying wood when the nematodes are said to be in there “mycophagous” phase, feeding on fungus within the wood and NOT on the wood itself. The PWN is unable to travel outside of the wood by itself, and in order to reach another host tree (living or dead) it must be carried by an insect vector. B xylophilus has the shortest life cycle compared to any parasitic nematode. One generation is completed within four days after the nematode is cultured on fungi at it optimum. During the summer, the parasite reproduces very rapidly to very high numbers resulting in the spread throughout the resin canal system of susceptible pines, into the trunk and therefore all of its branches (even into the roots). If living tree cells are no longer available the parasite feeds and reproduces on the fungal hyphae that is growing through the resin canals. In the fall and winter the parasite becomes inactive but then resumes activity in the spring.[4][9][11]

Vector

Though the PWN is known to be vectored by a number of bark beetles and wood borers, it seems to be most often associated with species in the genus Monochamus, widely referred to as “pine sawyers”. Pine sawyers lay their eggs in the bark of dead timber. The growing larva feeds on the wood, and within the resulting cavity develops into an adult pupa. The J3 stage of the PWN congregate in the cavity around the pine sawyer pupa, molt into J4 (dauer stage) juveniles, and then migrate into the trachea of the adult beetle through its spiracles. During this “dispersive stage” the beetle may transport the PWN in one of two ways. In “secondary transmission” during vector oviposition, the nematode is transported to another dead tree and continues in the mycophagous phase.[4][9]

Host parasite relationship

In “primary transmission” when the beetle feeds on susceptible host pines, the PWN will enter the tree and feed on the epithelial cells which line the resin ducts. This is referred to as the “phytophagous” phase of the PWN, and will result in pine wilt. When the host is infected, the transmission of water within the plant is restraining; under peak conditions, pine wilt can become apparent within a few weeks after infection, the needles turn brown, and the leaves turn yellow, and eventual death of the tree. From the time of infection to the death of the plant/tree/host, it only takes two to three months. Though the susceptibility of many species of pine is still a matter of contention, susceptibility has been proven (using Koch’s postulates) in a few species, which includes Scotch, Slash, Japanese red, and Japanese black pines. The Slash pine is the only susceptible species native to North America, and its susceptibility has been shown to be relatively weak compared to foreign pines. Because of this the direct economic impact due to pine wilt, in this part of the world, is limited to predominantly landscaping settings.[4][9] [11]

Management

Protective embargoes placed by the EU on untreated lumber transported from the U.S. and Canada have resulted in more indirect economic losses (2,3). Because there is no cure for pine wilt, management practices have concentrated on preventing the spread of the PWN. Infected trees are cut and either burned or chipped, soft wood timber is stripped of its bark to prevent oviposition by vectors, and all lumber shipped overseas is either fumigated or kiln dried. Despite these preventative measures the PWN has recently made in appearance in Portugal, and threatens to spread to other countries in Europe.[4][5][6][7][9]

Diagnosis

There is a way to find out if plants have this disease or not. One way to do it is to cut a cross section of the limb and soak it in water and look at it under a microscope. Another way to do it is to drill some holes in the trees to detect if this parasite is present.

Prevalence

Only known to affect trees. Japan has a wide spread of wilting and death to pine trees.

Research

A study was done on the genome of this wood nematode B. xylophilus to observe how this nematode finds its host. One of the most important component of the plant is the cellulase because the cellulase is an enzyme that helps break cellulose structure and lets them explore inside the host once they get inside.

References

  1. ^ UNL.edu
  2. ^ UC Davis
  3. ^ Online Gardener
  4. ^ a b c d e f Dwinell L.D., Nickle W.R. 2004. An Overview of the Pine Wood Nematode Ban in North America. USDA www.forestpests.org
  5. ^ a b Mota M.M., Vieira P.C. 2008. Pine Wilt Disease in Portugal. NemaLab-ICAM, Department of Biology, University of Evora. Evora, Portugal
  6. ^ a b Mota M.M., et al. 2008. Pine Wilt Disease: A Worldwide Threat to Forest Ecosystems. Springer ISBN 978-1-4020-8454-6
  7. ^ a b Suzuki K. 2002. Pine Wilt Disease: a threat to pine forest in Europe. Dendrobiology, Vol. 48. 71-74
  8. ^ How to Identify and Manage Pine Wilt Disease and Treat Wood Products Infested by the Pinewood Nematodes
  9. ^ a b c d e Cram M., Hanson J. How to Identify and Manage Pine Wilt Disease and Treat Wood Products Infested by the Pinewood Nematodes. USDA http://www.na.fs.fed.us/spfo/pubs/howtos/ht_pinewilt/pinewilt.htm
  10. ^ http://plpnemweb.ucdavis.edu/nemaplex/Taxadata/G145S1.HTM
  11. ^ a b Bursaphelenchus xylophilus (nematode)

http://www.apsnet.org/edcenter/intropp/lessons/Nematodes/Pages/PineWilt.aspx