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Resistance mechanisms of Port-Orford-cedar to Phytophthora lateralisOh, Eunsung 30 November 2004 (has links)
Breeding Port-Orford-cedar for resistance to Phytophthora lateralis, a causal
agent of root disease, begins by screening, through artificial inoculation,
phenotypically resistant trees selected from natural stands. The successful program
selected tolerant or resistant POC parent trees for the purpose of disease management.
Candidate resistant POCs were used in my dissertation to: 1. validate screening
methods such as stem- and root-dip inoculation; 2. test for increased virulence of P.
lateralis; and 3. evaluate detection techniques. The results showed that the established
screening methods were appropriate, and no evidence of changed virulence was found.
A PCR technique was more reliable than other techniques for detection of P. lateralis
in seedlings. An additional test for foliar infection showed that initial penetration
through wounds and natural openings was possible.
POC seedlings and rooted cuttings from resistant and susceptible families were
used to demonstrate resistance mechanisms. In order to explain the mechanisms at the
cellular level, the susceptible response of POC seedlings to P. lateralis was first
observed with light microscopy. Zoospores encysted on lateral roots, germinated, and
penetrated by means of appressoria. Direct penetration between epidermal cells was
common but penetration through epidermal cell walls was also observed. The hyphae
colonized the root cortex inter- and intracellularly. Wound inoculation on stems
resulted in inter- and intra cellular hyphal growth in cambial, sieve, and parenchyma
cells in the secondary phloem.
Several resistance mechanisms were observed: 1) there was a difference in
zoospore attraction between susceptible and certain resistant POCs revealed by
microscopic observation, direct count of encysted zoospores, and quantitative real-time
PCR; 2) the frequency of encystment, penetration, and colonization of resistant
seedlings was much lower than susceptible seedlings, but no differences in infection
pathway were observed by means of light or electron microscopy; 3) collapsed cell
walls were present in resistant POCs showing increased cell wall thickness, wall
appositions, and electron dense materials. / Graduation date: 2005
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Susceptibility of Pacific yew (Taxus brevifolia Nutt.) to Phytophthora lateralisMurray, Marion S. 10 April 1995 (has links)
In 1991 Pacific yew (Taxus brevifolia Nutt.) was reported as a new host for
Phytophthora lateralis Tucker and Milbrath which is an aggressive root rot pathogen
thought previously to be specific to Port-Orford-cedar. This study was designed to
compare the pathogenicity of P. lateralis on the two hosts, and to characterize sites
where Pacific yew mortality occurs. The specific objectives were: 1) compare root
colonization and mortality of Pacific yew and Port-Orford-cedar seedlings and
rooted cuttings; 2) compare lesion length on inoculated Pacific yew and Port-Orford-cedar
branches and stems; 3) compare zoospore attraction to freshly cut Pacific yew
and Port-Orford-cedar rootlets; 4) compare amount of mortality of Pacific yew and
Port-Orford-cedar in infested drainages and determine extent of yew mortality; and
5) characterize sites where P. lateralis causes Pacific yew mortality.
Root colonization of P. lateralis was significantly greater in cedar than in yew.
Seedling mortality averaged 58% for cedar and 4% for yew. Lesion length on the
cedar seedling stems was twice the lesion length on yew stems, and cedar branches
had lesions four times longer than yew branches. Abundant zoospore aggregation
occurred on cedar rootlets along the zone of elongation and the region of maturation.
In comparison, far fewer zoospores encysted along the yew rootlets, and were
concentrated on the root hairs. The stream survey of three infested drainages in
southwest Oregon and northwest California revealed a total of 1199 dead Port-Orford-cedar (46% mortality), and 86 dead Pacific yew (10% mortality). At sites
where P. lateralis-induced mortality occurred, the interaction of slope and distance
from the stream was negatively correlated with tree death.
Based on results of this study, we conclude that Pacific yew is less susceptible
to P. lateralis than Port-Orford-cedar, but that mortality of Pacific yew in the field
is greater than previously reported. In addition, Pacific yew mortality was observed
most often on level to nearly-level sites close to the stream's edge where root
exposure to P. lateralis-infested water was frequent in scope and duration. / Graduation date: 1995
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Developing techniques for evaluating the susceptibility of root-disease resistant Port-Orford-Cedar to foliar and stem canker diseases /Martin, Danielle K. H. January 1900 (has links)
Thesis (M.S.)--Oregon State University, 2009. / Printout. Includes bibliographical references (leaves 128-132). Also available on the World Wide Web.
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Port-Orford-cedar and Phytophthora lateralis : grafting and heritability of resistance in the host, and variation in the pathogenMcWilliams, Michael G. 06 June 2000 (has links)
Port-Orford-cedar (Chamaecyparis lawsoniana) is a forest tree native to
a small area of Oregon and California. A root disease caused by
Phytophthora lateralis causes widespread mortality of Port-Orford-cedar.
This dissertation examines three important elements of the Port-Orford-cedar
P. lateralis pathosystem related to breeding for disease resistance:
use of resistant rootstocks to maintain genotypes of Port-Orford-cedar for
breeding; the heritability and genetic basis of disease resistance; and
variability in virulence and DNA fingerprint among a sample of P. lateralis
isolates.
Port-Orford-cedar was reciprocally grafted to western redcedar (Thuja
plicata), incense cedar (Calocedrus decurrens), and Alaska yellow-cedar
(Chamaecyparis nootkatensis). Port-Orford-cedar scion graft success was
moderate with western redcedar and incense cedar, but extreme
overgrowth of the rootstock by the scion indicated incompatibility. Xylem
union was good, but phloem union was incomplete or lacking. Nearly all
Port-Orford-cedar rootstocks and seedlings exposed to P. lateralis died of
root disease. Four percent of the Alaska yellow-cedar exposed also died,
confirming this tree as a host for P. lateralis.
Resistance of Port-Orford-cedar to P. lateralis is rare. A small number
of trees have been identified exhibiting resistance. A number of families
were tested to determine the genetic basis for resistance. Estimates of
narrow-sense and family mean heritability of resistance, as exhibited by
restriction of lesion length after inoculation, were determined. Both narrow-sense
and family mean heritabilities were between 0.61 and 0.98 in most
tests. Between 21% and 32% of the variance was due to differences
among families.
Thirteen isolates of P. lateralis were collected from three hosts
throughout the geographic range of the fungus. Variation in growth rate on
artificial media at three temperatures, virulence when used to inoculate
Port-Orford-cedar, and DNA fingerprint were compared. There were
significant differences in growth rate among isolates at 24C, but fewer
differences at lower temperatures and on a rich medium. One isolate
produced significantly shorter lesions in three different inoculation tests.
Isolates differed at only two of 189 bands produced by Inter Simple
Sequence Repeat (ISSR) DNA primers, indicating very little genetic
variation among isolates. / Graduation date: 2001
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Road networks, timber harvest, and the spread of Phytophthora root rot infestations of Port-Orford-cedar in southwest OregonClark, William C. 01 September 2011 (has links)
Phytophthora lateralis is the causal agent of cedar root rot, a fatal forest pathogen whose principal host is Chamaecyparis lawsoniana (Port-Orford-cedar), a predominantly riparian-restricted endemic tree species of ecological, economical, and cultural importance to coastal Oregon and California. Local scale distribution of P. lateralis is thought to be associated with timber harvest and road-building disturbances. However, knowledge of the landscape-scale factors that contribute to successful invasions of P. lateralis is also important for effective land management of Port-Orford-cedar. P. lateralis is able to infest in wet conditions via stream networks (zoospore) and dry conditions via road networks (resting spore). This study tested the hypothesis that vehicles spread P. lateralis by relating its distribution to traffic intensive, anthropogenic disturbances (i.e. a road network, timber harvest) over a 31-yr period in a 3,910-km² portion of the Rogue River-Siskiyou National Forest in the Siskiyou Mountains of Oregon. Indices of road disturbance (presence/absence, configuration, length, density, road-stream network connectivity) and timber harvest (presence/absence, area, density, frequency) were related to locations of infested cedar populations from a USFS survey dataset using a geographic information system (GIS). About 40% of 934 7th-field catchments were infested with the pathogen. Total road length of the study site was 5,070 km; maximum road density was 8.2 km/km2 and averaged 1.6 km/km² in roaded catchments (n = 766). Timber activities extracted 17,370 ha (2,338 cutting units) of forest across 509 catchments; 345 catchments were cut ≥ twice. Maximum harvest density was 0.92 km²/km² ([mean] = 0.04). Both road networks and timber harvest patchworks were significantly
related to cedar root rot heterogeneity. Chi-squared contingency tables showed that infestation rates were 2.2 times higher in catchments with roads compared to roadless catchments and 1.4 times higher in catchments with road-stream intersections compared to those that were unconnected. Infestation was twice as likely in catchments with both harvest and road presence than road presence alone. Single-variable logistic regression showed that a one percent increase in harvest density increased infestation odds 25% and a one-unit (km/km²) increase in road density increased infestation odds 80%. Road and stream network configuration was also important to pathogen distribution: 1) uninfested catchments are most likely to be spatially removed from infested, roaded catchments, 2) only 11% of 287 roaded catchments downstream of infested, roaded catchments were uninfested, and 3) only 12% of 319 catchments downstream of infested catchments were uninfested. Road networks and timber harvest patchworks appear to reduce landscape heterogeneity by providing up-catchment and down-catchment access to host populations by linking pathogenic materials to the stream network. Timber harvest data suggest that while infestation risk to Port-Orford-cedar populations remains high, management policies may have curbed infestation risk in timber-harvested catchments; if this is a result of specific P. lateralis mitigation policies adopted in the late 1980's or broader, region-wide conservation policies (i.e. the Northwest Forest Plan) is yet unclear. / Graduation date: 2012
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