Fusarium patch

Last updated

Monographella nivalis var. nivalis
Monographella nivalis-close-up-2.jpg
Pink snow mold in a lawn in Brno Komín, Czech Republic
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Fungi
Division: Ascomycota
Class: Sordariomycetes
Order: Amphisphaeriales
Family: Amphisphaeriaceae
Genus: Monographella
Species:
M. nivalis

Variety:
M. n. var. nivalis
Trinomial name
Monographella nivalis var. nivalis
Synonyms

Fusarium patch is a disease in turf grass settings also called pink snow mold or Microdochium patch. In many cool season grass species in North America, it is caused by the fungus Microdochium nivale . [1] The white-pink mycelium on infected leaf blades is a distinguishing characteristic of the Microdochium nivale pathogen. [2] Fusarium patch is considered economically important in the turf grass industry because of its tendency to cause significant injury to golf greens, thereby decreasing putting surface quality. [3] Dissimilar from other snow molds, such as gray snow mold, Microdochium nivale does not need snow cover to cause widespread infection.

Contents

Hosts and symptoms

M. nivale can infect all cool-season turf grass species. [4] Annual bluegrass ( Poa annua ), perennial ryegrass ( Lolium perenne ) and creeping bentgrass ( Agrostis stolonifera ) are more susceptible. In the fall, M.nivale infection begins as small, orange to red-brown spots, circular and only a few centimeters in diameter. During the winter and into the spring seasons, well-defined, clustered, circular patches 10–20 cm in diameter, of necrotic leaf tissues form on mown turf. Microdochium nivale is mostly seen on grasses mown at heights of three inches or greater. [5] On taller grass, patches often lack a circular pattern that is seen in shorter mown grass. [6] Pink snow mold patches usually follow drainage patterns since conidia spores are readily dislodged and transported by rainfall and water flowage. [7] Under prolonged cool and wet conditions, white-pink mycelium can be observed along the circumference of diseased patches. [8]

Disease cycle

M. nivale begins by oversummering (surviving the summer) in thatch or soil as haploid mycelium or spores. When cool, wet weather arrives in the fall or winter the mycelium grows from thatch or soil and infects leaves. These environmental conditions also favor the development of asexual spores called conidia on conidiophores. These conidia infect leaf sheaths and blades near the soil. Wind and surface water will help aid in the spread of this disease as it will allow for the spores to contact near by healthy plant. The disease becomes very severe if allowed to spread from the leaf blades to the crown of the plant. [9] This usually only happens under extreme circumstances, particularly if snowfall covers unfrozen ground. [10]

Environment

Microdochium nivale becomes problematic when turf experiences lengthy periods of cool, wet weather typical of fall or spring and into early summer in the Northern Hemisphere. The name is somewhat confusing because the presence of snow is not necessary for this pathogen to develop. The disease can thrive under snow cover, however, if it falls on unfrozen soil with thriving turf. In general this disease tends to develop proficiently when grass is growing at a slower than normal rate. Limiting fall nitrogen applications in an attempt to decrease the growth of grass and promote dormancy can help decrease the incidence of Pink Snow Mold. In regions of high humidity and temperatures ranging between 32 and 46 degrees Fahrenheit or 0 to 8 degrees Celsius, pink snow mold will develop rapidly. [11]

Management

There are a number of different ways to manage diseases including cultural, chemical, and biological controls. Some of these controls are more effective than others, however, the best approach to a managing any disease, including Microdochium Patch, is an integrated approach called Integrated Pest Management or IPM. IPM uses a combination of chemical, cultural and biological controls to reduce spending on pesticides and to decrease pesticide resistance. The following are some of the most important cultural controls used in managing Microdochium Patch.

Cultural controls

Raising the mowing height is an easy way to reduce stress on a turfgrass plant and make the plant less susceptible to attack by disease, but there is a fine line. Turf mowed, less than 2.5 inches (64 mm) and above 3 inches (76 mm) makes the plant more susceptible to disease. Managing the moisture available to the plant is another way to help reduce the incidence of disease. The pathogen that causes Microdochium Patch requires and thrives in moist, cool conditions, therefore making sure that you aren't overwatering the turf when conditions are right for infection is very important. Giving the plant only enough water for normal plant function is the best way to ensure disease pressure is reduced as much as possible. Also, starving the turf of moisture can be damaging as this increases susceptibility to infection. Managing the amount of nitrogen available to the plant is another key to decreasing incidence of this disease. Avoiding excess fall nitrogen application will greatly reduce disease pressure of Microdochium nivale. On top of that excess nitrogen available to plant produces rapid growth of above ground tissue. This tissue often has thin cell walls and is prone to attack by disease. Managing thatch and soil drainage are two other important ways of controlling this disease as both of these affect the amount of moisture that is available to create a favorable environment to the disease, [12] giving the plant only enough water for normal plant function is the best way to ensure disease pressure is reduced as much as possible. Despite the fact that the above cultural controls cannot completely control Microdochium Patch, when they are all used to reduce disease pressure, they can have a noticeable impact and will help to reduce the amount of chemical control that is required.

Chemical controls

Chemical controls (i.e. the use of fungicides) to specifically control turf grass diseases have been around since 1891. Over the years better controls have been developed, all of which tend to be less toxic to animals and the environment when used properly.

There is a wide variety of chemical groups that are labeled for control of Microdochium Patch. They include, but are not limited to the methyl benzimidazole carbamates (MBCs) such as thiophanate methyl, the dicarboximides such as iprodione and vinclozolin, the DMIs such as fenarimol and propiconazole, the QoIs such as azoxystrobin, pyraclostrobin, and trifloxystrobin, the phenylpyrroles such as fludioxonil, certain aromatic hydrocarbons such as PCNB, and the cholronitriles such as chlorothalonil. [13]

These chemical classes should be rotated so that selection pressure on the disease in limited as to avoid resistant strains of this disease. The applicator should read and follow all label rates and directions. Breaking these directions and misuse of any labeled product is breaking the law. Remember that the label is the law. The best way to control Microdochium Patch especially going into winter is to use a three way spray right before the first snow fall. A combination of a dicarboximides such as iprodione, a chloronitrile such as chlorothalonil, and a DMI such as propiconazole will give sufficient control over the span of an average winter.

Importance

Microdochium Patch is a significant problem in the turfgrass management industry. Sports fields, sod farms and home lawns and golf courses can all be damaged by this the disease. The pathogen can be found in the Northern United States and all the way up into Canada, meaning that there is a large area where this pathogen can cause serious disease. The highest incidence of this disease in these areas occurs on golf courses due to the highly managed areas of susceptible turfgrass species such as Creeping Bentgrass ( Agrostis stolonifera ) and Annual Bluegrass ( Poa annua ). It is of particular concern because turf on golf courses is considered a high value crop. Diseases such a Microdochium Patch lower the value of the crop by decreasing its aesthetic value, affecting the playability, and decreasing the overall health of the turf. Because golf course budgets are often quite tight, the reduction of fungicide applications required in a season for snow mold will result in more money elsewhere in the budget. Being that the fungicide budget can be 10% of the maintenance budget, reductions in the use of fungicides can cause a significant increase in the amount of money to do other things. On top of that, reducing fungicide inputs helps keep the environment safe and reduces the chances of fungicide resistance development.

See also

Related Research Articles

<span class="mw-page-title-main">Damping off</span> Horticultural disease or condition

Damping off is a horticultural disease or condition, caused by several different pathogens that kill or weaken seeds or seedlings before or after they germinate. It is most prevalent in wet and cool conditions.

<i>Gibberella zeae</i> Species of fungus

Gibberella zeae, also known by the name of its anamorph Fusarium graminearum, is a fungal plant pathogen which causes fusarium head blight (FHB), a devastating disease on wheat and barley. The pathogen is responsible for billions of dollars in economic losses worldwide each year. Infection causes shifts in the amino acid composition of wheat, resulting in shriveled kernels and contaminating the remaining grain with mycotoxins, mainly deoxynivalenol (DON), which inhibits protein biosynthesis; and zearalenone, an estrogenic mycotoxin. These toxins cause vomiting, liver damage, and reproductive defects in livestock, and are harmful to humans through contaminated food. Despite great efforts to find resistance genes against F. graminearum, no completely resistant variety is currently available. Research on the biology of F. graminearum is directed towards gaining insight into more details about the infection process and reveal weak spots in the life cycle of this pathogen to develop fungicides that can protect wheat from scab infection.

Pythium aristosporum is a species of pythium under the class oomycota that causes root dysfunction in creeping bentgrass.

Pythium volutum is a plant pathogen infecting wheat, barley, and turfgrass. It is known to be sensitive to some of the compounds typically present in selective media commonly used for isolating Pythium spp., so isolation may require alternative methods.

<i>Typhula incarnata</i> Species of fungus

Typhula incarnata is a fungal plant pathogen in the family Typhulaceae.

<i>Ascochyta</i> Genus of fungi

Ascochyta is a genus of ascomycete fungi, containing several species that are pathogenic to plants, particularly cereal crops. The taxonomy of this genus is still incomplete. The genus was first described in 1830 by Marie-Anne Libert, who regarded the spores as minute asci and the cell contents as spherical spores. Numerous revisions to the members of the genus and its description were made for the next several years. Species that are plant pathogenic on cereals include, A. hordei, A. graminea, A. sorghi, A. tritici. Symptoms are usually elliptical spots that are initially chlorotic and later become a necrotic brown. Management includes fungicide applications and sanitation of diseased plant tissue debris.

Colletotrichum cereale is a plant disease (fungus) that has been found to cause crown rot anthracnose of turf grass most commonly occurring on golf courses. Anthracnose can occur as both a foliar blight and basal rot. This disease attacks the crowns of plants, which is different than other anthracnose diseases. Anthracnose of turfgrass can be a foliar disease or in this case a basal rot of the lower portion of the plant. It attacks different species of turfgrass throughout the world most commonly annual bluegrass and creeping bentgrass.

Magnaporthe poae is an ascomycete fungus which causes the turfgrass disease commonly known as summer patch, or Poa patch. The disease occurs mostly on Kentucky bluegrass (Poa pratensis), Fescues (Festuca sp.), and on Annual bluegrass (Poa annua). Bentgrass may also become infected but shows very few symptoms and quickly recovers. Summer Patch will usually become noticeable between June and September, although small signs can appear at any time but are not noticeable because the turfgrass can recover quickly.

<span class="mw-page-title-main">Brown patch</span> Fungal disease affecting turfgrasses

Brown patch is a common turfgrass fungal disease that is caused by species in the genus Rhizoctonia, usually Rhizoctonia solani. Brown patch can be found in all of the cool season turfgrasses found in the United States. Brown patch is most devastating to: Bentgrass, ryegrass, Annual bluegrass, and Tall fescue. Brown patch is also found in Kentucky bluegrass and Fine fescue but this is rare or does minimal damage. Brown patch is known as a foliar disease, so it does not have any effect on the crown or roots of the turf plant.

Pythiumdisease, also known as "Pythiumblight," "cottony blight," or "grease spot," is a highly destructive turfgrass disease caused by several different Pythium species. All naturally cultivated cool-season turfgrasses are susceptible to Pythium and if conditions are favorable to Pythium it can destroy a whole turfgrass stand in a few days or less. Pythium favors hot and very humid weather and will usually develop in low areas or swales in the turfgrass.

Red thread disease is a fungal infection found on lawns and other turfed areas. It is caused by the corticioid fungus Laetisaria fuciformis and has two separate stages. The stage that gives the infection its name is characterised by very thin, red, needle-like strands extending from the grass blade. These are stromata, which can remain viable in soil for two years. After germinating, the stromata infect grass leaf blades through their stomata. The other stage is visible as small, pink, cotton wool-like mycelium, found where the blades meet. It is common when both warmth and humidity are high.

Dollar spot is a fungal disease of turfgrass caused by the four species in the genus Clarireedia, in the family Rutstroemiaceae. The pathogen blights leaf tissues but does not affect turf grass roots or crowns. There is evidence that a fungal mycotoxin produced by the pathogen may cause root damage, including necrosis of the apical meristem in creeping bentgrass. However, the importance of this toxin is unknown and its effects are not considered a direct symptom of dollar spot. The disease is a common concern on golf courses on intensely managed putting greens, fairways and bowling greens. It is also common on less rigorously maintained lawns and recreational fields. Disease symptoms commonly result in poor turf quality and appearance. The disease occurs from late spring through late fall, but is most active under conditions of high humidity and warm daytime temperatures 59–86 °F (15–30 °C) and cool nights in the spring, early summer and fall. The disease infects by producing a mycelium, which can be spread mechanically from one area to another.

Typhula blight is most commonly known as a turf disease, but can also be a problem with wheat. Typhula blight is caused by a Typhula fungus, either Typhula incarnata or T. ishikariensis. Typhula incarnata is the causal agent for gray snow mold and T. ishikariensis causes speckled snow mold. Snow molds are caused by cold tolerant fungi that require snow cover or prolonged periods of cold, wet conditions. Typhula blight is most notably found in the turf industry, affecting a wide range of turfgrasses. Upon the snow melt, gray circular patches of mycelium are found. These mycelia produce a survival structure called a sclerotia that survives the warm summer months. Typhula blight is commonly controlled with fungicide applications in the late fall and by other cultural practices. If unchecked, snow molds can cause severe turf loss.

Snow mold is a type of fungus and a turf disease that damages or kills grass after snow melts, typically in late winter. Its damage is usually concentrated in circles three to twelve inches in diameter, although yards may have many of these circles, sometimes to the point at which it becomes hard to differentiate between different circles. Snow mold comes in two varieties: pink or gray. While it can affect all types of grasses, Kentucky bluegrass and fescue lawns are least affected by snow mold.

<span class="mw-page-title-main">Turf melting out</span> Turfgrass disease caused by the pathogen Dreshlera poae

Turf melting out is caused by the fungal pathogen Dreschlera poae, in the family Pleosporaceae. It is a common problem on turfgrass and affects many different species. The disease infects all parts of the plant most commonly on golf course roughs, sports fields, and home lawns. There are two stages of the disease: the leaf blade infection and the crown and root infection Melting out occurs during the cool weather of April and May and is encouraged by high nitrogen fertility. The disease is spread by wind-blown or water splashed spores and survive in thatch.

<span class="mw-page-title-main">Brown ring patch</span> Fungal disease of turf grass

Brown ring patch is a recently described Rhizoctonia-like disease of turf grass caused by the fungus Waitea circinata var. circinata. The disease primarily affects putting greens and causes yellow or brown rings up to 1 metre (3.3 ft) in diameter. Brown ring patch was first observed in Japan and has since spread to the United States and China (2011).

Bacterial wilt of turfgrass is the only known bacterial disease of turf. The causal agent is the Gram negative bacterium Xanthomonas campestris pv. graminis. The first case of bacterial wilt of turf was reported in a cultivar of creeping bentgrass known as Toronto or C-15, which is found throughout the midwestern United States. Until the causal agent was identified in 1984, the disease was referred to simply as C-15 decline. This disease is almost exclusively found on putting greens at golf courses where extensive mowing creates wounds in the grass which the pathogen uses in order to enter the host and cause disease.

Necrotic ring spot is a common disease of turf caused by soil borne fungi that mainly infects roots (4). It is an important disease as it destroys the appearance of turfgrasses on park, playing fields and golf courses. Necrotic Ring Spot is caused by a fungal pathogen that is an ascomycete that produces ascospores in an ascocarp (6). They survive over winter, or any unfavorable condition as sclerotia. Most infection occurs in spring and fall when the temperature is about 13 to 28 °C (5). The primary hosts of this disease are cool-season grasses such as Kentucky bluegrass and annual bluegrass (6). Once turf is infected with O. korrae, it kills turf roots and crowns. Symptoms of the disease are quite noticeable since they appear as large yellow ring-shaped patches of dead turf. Management of the disease is often uneasy and requires application of multiple controls. The disease can be controlled by many different kind of controls including chemicals and cultural.

Gray leaf spot (GLS) is a foliar fungal disease that affects grasses. In grasses other than maize it is caused by Pyricularia grisea, which only infects perennial ryegrass, tall fescue, and St. Augustine grass in places with warm and rainy climates.

The annual bluegrass weevil, scientific name Listronotus maculicollis, is a turfgrass insect pest which feeds mainly on annual bluegrass. They prefer to feed on very low mown grass, and are thus found mostly on golf courses or grass tennis courts. ABWs, as they are often referred to, were only found in the Northeastern United States until the 2000s when sightings began to expand. In recent years they have been found as far north as Ontario and Quebec, as far west as Ohio, and as far south as North Carolina. Their choice of hosts has also expanded, and they have been reported feeding on perennial ryegrass and creeping bentgrass.

References

  1. Chang, T., Chang, S., & Jung, G. (2011). Response of bentgrass cultivars to microdochium nivale isolates collected from golf courses. Plant Pathology Journal, 27(3), 232-241
  2. Archived 2011-06-17 at the Wayback Machine Latin, R. (2007) Pink snow mold and Microdochium patch. Turfgrass Disease Profiles. Purdue Extension, Purdue University
  3. Bertrand, A., Castonguay, Y., Azaiez, A., and Dionne, J. (2011). "Cold-induced responses in annual bluegrass genotypes with differential resistance to pink snow mold (Microdochium nivale).", Plant Science, 180(1), pp. 111-119. doi : 10.1016/j.plantsci.2010.08.008
  4. Archived 2011-06-17 at the Wayback Machine Latin, R. (2007) Pink snow mold and Microdochium patch. Turfgrass Disease Profiles. Purdue Extension, Purdue University
  5. Archived 2011-06-17 at the Wayback Machine Latin, R. (2007) Pink snow mold and Microdochium patch. Turfgrass Disease Profiles. Purdue Extension, Purdue University
  6. Archived 2011-06-17 at the Wayback Machine Latin, R. (2007) Pink snow mold and Microdochium patch. Turfgrass Disease Profiles. Purdue Extension, Purdue University
  7. Archived 2011-06-17 at the Wayback Machine Latin, R. (2007) Pink snow mold and Microdochium patch. Turfgrass Disease Profiles. Purdue Extension, Purdue University
  8. Hsiang T. 2007. All you ever wanted to know about Fusarium Patch. AGSA Turf News, June 2007, pp. 13-16.
  9. Hsiang, Tom, and Pam Charbonneau. Controlling Fusarium Patch Disease. GreenMaster 2nd ser. 28.April/May (1994): 16+. Turfgrass Information File. Web. 23 Oct. 2011.
  10. Pink Snow Mold (Turfgrass) (Microdochium nivale) - Hort Answers - University of Illinois Extension. University of Illinois Extension-Urban Programs Resource Network - University of Illinois at Urbana-Champaign. Web. 23 Oct. 2011.
  11. Pink Snow Mold (Turfgrass) (Microdochium nivale) - Hort Answers - University of Illinois Extension. University of Illinois Extension-Urban Programs Resource Network - University of Illinois at Urbana-Champaign. Web. 23 Oct. 2011.
  12. Nick Christians.2007. Fundamentals of Turf grass Management. Wiley and Sons.Hoboken, NJ
  13. [Nick Christians.2007. Fundamentals of Turfgrass Management. Wiley and Sons.Hoboken, NJ]
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.