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Posts Tagged: pathogen
Fungi that causes pine ghost canker detected in Southern California trees
Pathogen native to U.S. but had not infected pines until recently
Fungal pathogens that cause die-back in grape, avocado, citrus, nut and other crops has found a new host and is infecting conifer trees causing pine ghost canker in urban forest areas of Southern California.
The canker can be deadly to trees.
Scientists from University of California, Davis, first spotted evidence that the pathogens had moved to pines during a routine examination of trees in Orange County. Over four years, they found that more than 30 mature pines had been infected in an area of nearly 100 acres, according to a report in the journal Plant Disease.
Akif Eskalen, a professor of Cooperative Extension in the Department of Plant Pathology at UC Davis, suspects drought and other stress conditions brought on by climate change weakened the tree species, making it more susceptible to new threats.
“We have been seeing this on pine trees for the last several years,” he said. “Our common crop pathogens are finding new hosts.”
Pine ghost canker – caused by the fungal pathogens Neofusicoccum mediterraneum and Neofusicoccum parvum – usually infects the lower part of a tree's canopy, killing branches before moving on to the trunks. This dieback in some cases can be deadly.
Points of entry
The pathogens infect a tree by entering through wounds caused by either insects such as red-haired pine bark beetles or pruning – meaning trees in managed or landscaped areas could be at risk. Another route is via tiny natural openings known as lenticels that fungi can make their way through, said Marcelo Bustamante, a Ph.D. candidate in Eskalen's lab who is first author on the paper.
Spores from the fungi can disperse and the higher the prevalence means an increased chance of transmission. Rain, irrigation water and humidity by fog can trigger the right circumstances for the spores to spread, he said.
“The detection of these pathogens in urban forests raises concerns of potential spillover events to other forest and agricultural hosts in Southern California,” Bustamante and others wrote in the report.
Dead branches can indicate a canker. Detecting the fungi is not an emergency but “people should keep an eye on their plants when they see abnormalities,” Eskalen said.
Cankers are localized areas on stems, branches and tree trunks that are usually dead, discolored and sunken. On bark, the spores can look like strings of discolored dots.
The lab has posted a brochure bout how to best manage wood canker diseases.
Tips include:
* Keep your trees healthy: Proper irrigation and maintenance will keep trees strong.
* Prune dead branches to reduce sources of infestation.
* Avoid unnecessary pruning; perform structural pruning only.
Karina Elfar, Molly Arreguin, Carissa Chiang, Samuel Wells and Karen Alarcon from the Department of Plant Pathology contributed to the paper, as did experts from Disneyland Resort Horticulture Department, State University of New York's College of Environmental Science and Forestry, UC Irvine and UC Los Angeles.
/h3>/h3>Use Caution with Disinfectants
With Respiratory Syncytial Virus Infection (RSV) on the rise, and Covid-19 and the flu remaining...
Researchers pinpoint which bird species pose food safety risk to crops
E. coli and Salmonella are rare in wild birds, Campylobacter more common
Concerns over foodborne risk from birds may not be as severe as once thought by produce farmers, according to research from the University of California, Davis, that found low instances of E. coli and Salmonella prevalence.
While the research found that the risk is often low, it varies depending on species. Birds like starlings that flock in large numbers and forage on the ground near cattle are more likely to spread pathogenic bacteria to crops like lettuce, spinach and broccoli, according to a study of food safety risk and bird pathogens from the University of California Davis. In contrast, insect-eating species were less likely to carry pathogens.
The findings, published in the journal Ecological Applications, suggest that current practice of removing bird habitats around produce growers' farms over concerns the animals could bring foodborne pathogens into their fields may not solve the problem.
“Farmers are increasingly concerned that birds may be spreading foodborne diseases to their crops,” said Daniel Karp, the senior author on the study and an assistant professor in the UC Davis Department of Wildlife, Fish and Conservation Biology. “Yet not all bird species are equally risky.”
Only one foodborne disease outbreak in produce has been conclusively traced to birds: a Campylobacter outbreak in peas from Alaska. While the bacteria can cause diarrhea and other foodborne illness in humans, it's less of a concern to growers than E. coli and Salmonella, which have been responsible for multiple outbreaks across the nation.
In this study, researchers compiled more than 11,000 bacteria tests of wild bird feces and found that Campylobacter was detected in 8 percent of samples. But pathogenic E. Coli and Salmonella were only found in very rare cases (less than 0.5%).
In addition to the bacteria tests, researchers conducted roughly 1,500 bird surveys across 350 fresh produce fields in Western states and collected more than 1,200 fecal samples from fields. They then modeled the prevalence of pathogens in feces, interactions with crops, and the likelihood of different bird species to defecate on crops to determine risk.
Insect-eating birds pose lower risk
Based on the data, insect-eating birds, such as swallows, present a lower risk, while birds that flock near livestock, such as blackbirds and starlings, are more likely to transmit pathogens.
The data can help the agricultural industry determine risk and take action, such as separating produce crops from cattle lands. They also don't need to treat all birds the same.
“Maybe farmers don't need to be quite as concerned about all types of birds,” Karp said. “Our data suggest that some of the pest-eating birds that can really benefit crop production may not be so risky from a food-safety perspective.”
Removing habitat can backfire
This study and the authors' prior work indicate that removing habitat around farms may actually benefit the species that pose more risk and harm the beneficial, pest-eating ones that are less risky to food safety. This is because many prolific insect-eaters may visit crop fields to eat pests but need nearby natural habitats to survive. In contrast, many of the bird species that most commonly carry foodborne pathogens readily thrive on both cattle farms and produce farms without natural habitat nearby.
Other findings
Insect-eating birds that forage in the tree canopy pose minimal threat because they are less likely to carry foodborne pathogens and come into direct contact with produce. They can also be valuable parts of the ecosystem, particularly if they eat pests that can harm crops. Installing bird boxes could attract the pest-eaters, as well as help with conservation efforts.
“We basically didn't know which birds were problematic,” said lead author Olivia Smith, a postdoctoral researcher at Michigan State University who was at University of Georgia when the paper was written. “I think this is a good step forward for the field.”
Additional co-authoring institutions include James Cook University, UC Berkeley, UC Riverside, University of Kentucky, University of Texas, Virginia Polytechnic Institute and State University, Washington State University, BioEpAr, The Nature Conservancy and Van Andel Institute.
The research was funded by the United States Department of Agriculture and the National Science Foundation.
/h3>/h3>/h3>/h2>Exploring the Idea of Disease Suppressive Soils for Advances in Crop Health
One idea that is getting some play lately in the local scientific community is that of a disease suppressive soil. A disease suppressive soil is one in which specific soil pathogens no longer inflict accustomed levels of crop damage due to the inhibitory activities of other soil microbes.
Of note is that many of these microbes, generally bacteria and bacteria-like organisms, can be actively managed by the plant, which provide them, through the roots, with photosynthates thus influencing microbial activity and diversity. The net result is that this soil, very close around the roots in most cases, inhibits fungal pathogen invasion of the plant and is said to be a disease suppressive soil.
The question then to further understand this marvel of nature is what are the key species and genetic mechanisms of these microbes which result in the suppressive property of a soil? In other words, can we identify what makes a soil suppressive?
A few key points from "Deciphering the Rhizosphere Microbiome for Disease-Suppressive Bacteria", the ground-breaking paper in this field from the journal “Science” (attached below):
1. The soil investigated in this study was suppressive, but this only came about after years of being severely affected by the fungal pathogen, Rhizoctonia solani. Consistent with previous research, disease outbreaks are essential to get a suppressive soil – to gain immunity you have to get sick first.
2. Most suppressive soils lose their disease suppressive capability when pasteurized (in other words exposed to high temperatures; 80oC in this paper). Disease suppressiveness is transferable from a suppressive soil to a disease-conducive (non-suppressive) soil by mixing them together. These results indicate the microbial nature of the suppressiveness of the soil in this study.
3. An eye-popping 32,346 taxonomic units (classification groups) of bacteria and bacteria-like organisms were isolated from the soil associated with plant roots in this study. No significant differences in numbers of taxonomic units were noted between suppressive and conducive soils, nor were any differences noted in any of the blended mixes of the two.
4. However, and this is the key point, the study found that abundance of several bacterial taxa corresponded to suppressiveness of a soil. In other words, it's not so much the species of bacteria present which confers suppressiveness to a soil, it's actually the numbers of individuals of specific bacterial populations which confer suppressiveness or lack thereof to soil.
The findings in this paper are quite illuminating in that they state soil suppressiveness cannot be attributed to the presence or absence of a taxonomic group of bacteria, but can rather be attributed to the combined effect of a number of microbial groups working together in differing abundances.
Because of the tremendous potential such a technology could offer to agriculture, soil suppressiveness has been a bit of a holy grail for scientists. However, in my mind, the sort of interactive complexity described in this paper between possibly hundreds of microbial species, soil environment, plant roots and the pathogen needed to obtain satisfactory disease suppression will confound all but the most determined attempts at comprehension.
Hat tip to Stefanie Bourcier of Farm Fuel, Inc. for this paper, provided below:
Suppressive Soil Paper
Central Coast Alert: Fusarium Wilt Occurring in a Number of Strawberry Fields
2014 strawberry alert: Statewide, the California strawberry industry is grappling with two soilborne diseases that are spreading throughout the state: charcoal rot and Fusarium wilt. Both problems have been found in the Monterey-Santa Cruz region, and until recently most outbreaks were caused by the charcoal rot pathogen, Macrophomina phaseolina. However, in 2014 a number of new plant collapse cases were confirmed to be Fusarium wilt; overall, more Fusarium has been detected in 2014 than Macrophomina, a switch from previous seasons.
Symptoms: Symptoms of Fusarium wilt in strawberry consist of wilting of older foliage, plant stunting, and eventual collapse of the plant (Figures 1, 2, and 3). When plant crowns are cut open, internal vascular and cortical tissues are dark to orange brown (Figure 4). Disease is often most severe if the infected plant is subject to stresses such as weather extremes, water stress (excess or shortage of water), poor soil conditions, or heavy fruit loads. It is important to note that Fusarium wilt symptoms are virtually identical to those caused by charcoal rot.
Biology: Fusarium wilt is caused by the fungus Fusarium oxysporum f. sp. fragariae.This pathogen is host specific to strawberry and apparently can only infect this crop. The fungus survives in soil for long periods by producing resilient, microscopic structures called chlamydospores. The development of Fusarium wilt has been associated with changes in the practices of pre-plant soil fumigation. The fungus is spread within and between fields mostly by the transport of contaminated soil during soil tillage and preparation operations.
Current year management: For planted fields currently in production, there are no reliable control options for this disease. Because Fusarium wilt is more severe and develops more rapidly if strawberry plants are stressed, growers should manage the field so as to reduce stress; such steps include proper irrigation scheduling and the controlling of mites and other pests. Applying extra water will not help symptomatic plants. Even in the absence of stress, plants showing collapse symptoms eventually become non-productive.
Long term strategies: Integrated disease management strategies for subsequent crops involve the following: (1) Crop rotation. Do not plant strawberry in fields having a known history of the problem and avoid back-to-back strawberry plantings in infested locations. (2) Pre-plant fumigation. Such applications remain a useful tool for managing Fusarium and the other soilborne pests, even though most currently available fumigants are not completely effective. If fumigants are bed-applied, the level of control may be further reduced because of incomplete treatment of the soil. Measures that improve distribution of fumigants such as increasing the number of drip tapes may be beneficial. (3) Avoid stressing the plants. Stress will hasten the development and increase the severity of symptoms, so use appropriate growing and irrigation practices to reduce stress. (4) Sanitation. Growers with Fusarium infested fields need to be concerned with limiting the spread of the fungus from infested to clean fields. Being a soilborne pathogen, F. oxysporum can readily be spread by mud and dirt adhering to equipment and tires. Note that the pathogen may be resident in a field for several years before any plants show symptoms. Therefore limiting movement of soil between fields is a good practice even where no disease is evident. (5) Resistant or tolerant cultivars. UC cultivars show significant differences in susceptibility to Fusarium wilt, although none are completely resistant. San Andreas, Ventana, and Portola appear relatively resistant but reaction to the pathogen may differ year-to-year, which may be due to the variable effects of stress. Camarosa and Albion are both highly susceptible to Fusarium wilt.
Diagnosis and disease trends: Because Fusarium wilt symptoms are identical to charcoal rot symptoms and are similar to those caused by Verticillium wilt and Phytophthora root & crown rot, field diagnosis is impossible to accurately achieve. Submit strawberry collapse samples to the UC Cooperative Extension diagnostic lab in Salinas, which is supported jointly by UC and the California Strawberry Commission. Our research and extension team is closely following these disease developments; contact us if you see new outbreaks of these important problems.
Figure 1. Weak spots in the field, consisting of collapsing plants, indicate possible problems with soilborne pathogens such as Fusarium. Photo Steven Koike, UCCE
Figure 2. For plants infected with Fusarium wilt, the older leaves are the first to collapse and dry up. Photo Steven Koike, UCCE.
Figure 3. Strawberry plants with Fusarium wilt will eventually die. Photo Steven Koike, UCCE.
Figure 4. Internal crown tissue of strawberry infected with Fusarium will show a dark to orange brown discoloration. Photo Steven Koike, UCCE.