What is Fusarium head blight? 

Fusarium head blight (FHB) or scab is a fungal disease that affects wheat, barley, oats, and many grasses.  FHB is important, not only because it reduces yield, but because it reduces the quality and feeding value of grain.  In addition, the FHB fungus may produce mycotoxins, including deoxynivalenol (also known as DON or vomitoxin) that, when ingested, can adversely affect livestock and human health.  Maximum allowable levels of DON in feed for various animals (as set by the U.S. Food and Drug Administration) are ≤ 10 parts per million (ppm) for beef and feedlot cattle, ≤ 10 ppm for poultry, and ≤ 5 ppm for swine and all other animals.

What does Fusarium head blight look like? 

Diseased spikelets on an infected grain head die and bleach prematurely.  Healthy spikelets on the same head retain their normal green color.  Over time, premature bleaching of spikelets may progress throughout the entire grain head.  If infections occur on the stem immediately below the head, the entire head may die.  As symptoms progress, developing grains are colonized by the FHB fungus causing them to shrink and wrinkle.  Often, infected kernels have a rough, sunken appearance, and range in color from pink or soft gray, to light brown.

Where does Fusarium head blight come from? 

FHB is caused by the fungus Fusarium graminearum, which is not only a pathogen of wheat, but also of corn.  The fungus can overwinter in infested stubble and straw of cereals and weed grasses, and on stalks and rotted ears of corn.  The severity of FHB varies greatly from year to year.  Infection is favored by extended periods of high moisture or high (>90%) relative humidity, and moderately warm temperatures (59 to 86°F), particularly when these conditions occur just before or during wheat flowering (Feekes 10.5).  If favorable weather conditions persist, infections can continue to occur through the early dough stage (Feekes 11.2).  Extended periods of infection can be especially problematic in wheat stands where plants have varying levels of maturity.

How can I save a small grain crop with Fusarium head blight? 

Fungicides are available for FHB control.  Triazole fungicides [Fungicide Resistance Action Committee (FRAC) class 3] are recommended.  In particular, fungicides containing prothioconazole and tebuconazole, or a mix of these two compounds, have provided the best control of FHB in university research trials.  Avoid using strobilurin fungicides (FRAC class 11) as research indicates that use of these products can result in an increase in DON levels in harvested grain.  A web-based FHB risk assessment tool (http://www.wheatscab.psu.edu) is available to help make decisions about fungicide applications.  The tool also provides real-time, local commentary by extension personnel about the status of diseases in wheat.  When using fungicides for FHB control, be sure to read and follow all label instructions to ensure that you use the product in the safest and most effective manner possible.

How can I avoid problems with Fusarium head blight in the future?  

DO NOT plant small grains into small grain or corn residue.  Also, avoid planting grain crops near areas where there are large amounts of small grain or corn residue on the soil surface.  When possible, plant small grains following a legume crop (e.g., soybeans), and maintain a rotation with two to three years between small grain crops.  Deep plow all infested plant debris, where feasible.  DO NOT apply manure containing infested straw or corn stalks onto fields planted to small grains.  Certain grain varieties have moderate levels of resistance to FHB.  Consider using these varieties as a means to reduce disease severity and increase grain quality.  Finally, plant several varieties of a small grain that vary in flowering date.  This will decrease the risk that an entire crop will be vulnerable to FHB when weather conditions favor the disease.

For more information on Fusarium head blight:  

Contact the University of Wisconsin Plant Disease Diagnostics Clinic (PDDC) at (608) 262-2863 or pddc@wisc.edu.

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What is ergot? 

Ergot is a fungal disease of worldwide distribution that is common in the northern two-thirds of North America.  Ergot affects wild and cultivated grasses, as well as small grain crops such as wheat, oats, barley and especially rye.  The ergot pathogen produces alkaloid toxins, many of which reduce blood flow in animals (e.g., cattle, sheep, swine, horses and even humans) that eat ergot-contaminated grain.  Ergot poisoning is cumulative.  Symptoms can develop rapidly if animals eat large quantities of ergot or more slowly if they eat small quantities of ergot on a regular basis.  In many animals (e.g., cattle), the first symptom of ergot poisoning is lameness that occurs two to four weeks after ergot is first eaten.  Gangrene in extremities (e.g., hooves and ears) follows.  Dairy cows that eat ergot-contaminated grain typically have a marked reduction in milk yield.  Other symptoms of ergot poisoning can include convulsions, hallucinations and death.  Symptom development is often more severe in very hot or very cold weather.  Interestingly, some ergot toxins, when purified and used at low dosages, have pharmaceutical applications (e.g., inducing labor and treating migraine headaches).

What does ergot look like? 

Signs of ergot first appear as droplets of a sticky exudate (called honeydew) on immature grain heads.  Honeydew contains asexual spores of the ergot fungus.  Over 40 species of insects are attracted to honeydew and can carry spores from infected to healthy plants.  After approximately two weeks, infected grains are replaced by dark (often purplish), compact fungal structures called sclerotia.  Sclerotia range in size from ¹/₁₆ to ¾ inches in length, and often look like seeds, rodent droppings, or insect parts.

Where does ergot come from? 

Ergot is caused by several species of the fungus Claviceps, most commonly Claviceps purpurea.  Sclerotia of these fungi survive in soil and harvested grain.  Sclerotia require a one to two month period of cold temperatures (32 to 50°F), after which they germinate to form small, mushroom-like structures that produce sexual spores (different from those produced in honeydew).  Germination occurs most commonly in cool (57 to 84°F), damp weather and is inhibited at higher temperatures.  Sexual spores are blown to developing grain heads where infection occurs.  Humid weather (> 90% relative humidity) contributes to honeydew production.  Ergot is also often more severe if frosts occur at the time of spore production.

How can I save a small grain crop with ergot? 

Fungicide treatments are not recommended to control ergot.  When ergot is a problem, you can attempt to remove sclerotia from grain using commercial seed-cleaning equipment.  However, if sclerotia are broken or are the same size as the grain itself, this may be difficult and costly, and may still result in grain that has a contamination level that is above marketable thresholds (tolerance for ergot sclerotia in harvested grain can be as low as 0.05% by weight).  Ultimately destroying the contaminated grain may be the best course of action.  Be sure to also destroy the hay from the affected field.  DO NOT use the hay as feed or for animal bedding.

How can I avoid problems with ergot in the future?  

Maintain a rotation with at least one year between small grain crops.  Use crops that are not susceptible to ergot (e.g., soybeans, alfalfa, corn) in years when small grains are not grown.  Plant grain seed that is free of ergot sclerotia.  Ergot-resistant varieties are not available, but avoid longer-flowering varieties as they tend to be more susceptible to infection.  Keep weed grasses under control.  Also, mow areas adjacent to small grain fields to prevent grasses from flowering and developing ergot.  In fields where ergot becomes a problem, consider clean, deep plowing that will bury ergot sclerotia to at least three to four inches, thus preventing sclerotia from germinating.  Mow, remove and destroy ergot-infected grasses from pastures and hayfields.  DO NOT allow animals to graze in these areas and DO NOT use the harvested material for feed or as bedding material.

For more information on ergot:  

Contact the University of Wisconsin Plant Disease Diagnostics Clinic (PDDC) at (608) 262-2863 or pddc@wisc.edu.

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What is charcoal rot? 

Charcoal rot, also known as summer wilt or dry weather wilt, is a fungal disease of soybean that most commonly occurs in plants that are under heat and water stress.  Charcoal rot is most prevalent in the southern United States, but can occur in the North Central region when weather is hot and dry.  In Wisconsin, charcoal rot is observed most often in fields with sandy soils.

What does charcoal rot look like? 

Plants suffering from charcoal rot may display premature yellowing of their top leaves, as well as premature leaf drop that may be mistaken for normal plant maturity.  Plants with charcoal rot often initially wilt in the midday heat and then recover at night.  Eventually permanent wilting will occur.  In some cases, the upper third of a plant may have unfilled, flat seedpods.  At flowering, a light gray discoloration develops in the surface tissues of both tap and secondary roots, as well as lowers stems.  These tissues will appear as if they have been dipped in charcoal dust, hence the name of the disease.  The dusty appearance is due to the presence of tiny survival structures (called microsclerotia) of the fungus that causes the disease.

Where does charcoal rot come from? 

Charcoal rot is caused by the fungus Macrophomina phaseolina which has an extensive distribution and is known to infect over 500 plant species including corn (where it causes charcoal stalk rot), alfalfa, and many ornamental and weed species.  M. phaseolina can survive for two or more years in dry soils as microsclerotia embedded in plant residue.  In wet soils however, microsclerotia do not survive for more than seven to eight weeks.  Hyphae (i.e., fungal threads) of the fungus typically do not survive in soil for more than seven days.  Infections of M. phaseolina primarily occur in the spring when soil moisture is high.  The fungus enters plants via roots and then grows very slowly until plants reach their reproductive stage (usually coinciding with the hottest, driest part of the growing season).  Then more extensive colonization of plant tissue occurs.  M. phaseolina is most active when soil temperatures are high (80 to 95°F), unlike many other soilborne, disease-causing fungi, which have reduced activity when soil temperatures are high.

How can I save a soybean crop with charcoal rot? 

By the time that typical symptoms of charcoal rot are evident, control of charcoal rot is difficult, and losses in yield are likely inevitable.  Foliar fungicides and fungicide seed treatments have no effect on charcoal rot.

How can I avoid problems with charcoal rot in the future?  

Plant high quality, pathogen-free seed to prevent introduction of the charcoal rot pathogen into fields that are not currently infested.  In fields where M. phaseolina is already present, any cultural practices that minimize plant stress will reduce the risk of charcoal rot.  Use tillage practices (e.g., no-till) that maintain soil moisture, and irrigate where possible during dry periods to reduce drought stress.  Lower plant populations and maintain good weed control to minimize stress from competition for soil nutrients.  In addition, optimize soil fertility levels, particularly phosphorus.  Rotations with wheat may provide some control of charcoal rot.  However, because M. phaseolina has a wide host range (including corn), crop rotation may not provide sufficient control of charcoal rot.  A moderate level of partial resistance is known in soybean varieties in maturity groups IV and higher.  Unfortunately these varieties are not suitable for production in Wisconsin.  Whether partial resistance is present in commercial varieties suitable to be grown in Wisconsin (maturity groups I and II) is not known.

For more information on charcoal rot of soybean:  

Contact the University of Wisconsin Plant Disease Diagnostics Clinic (PDDC) at (608) 262-2863 or pddc@wisc.edu.

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What is brown stem rot? 

Brown stem rot (BSR) is a disease of soybean that was first observed in central Illinois in 1944 and is now prevalent throughout the North Central States of the US, and Canada.  BSR has been identified as the third most important disease of soybeans in Wisconsin, attributable to the expansion of soybean acreage and shorter crop rotations used in the state.  The agronomic impact of BSR is greatest in high yield potential environments.  BSR negates the benefits of management practices intended to increase yield potential.

What does brown stem rot look like? 

Symptoms of BSR are usually not evident until late in the growing season and may be confused with signs of crop maturity or the effects of dry soils.  The most characteristic symptom of BSR is the brown discoloration of the pith especially at and between nodes near the soil line.  This symptom is best scouted for at full pod stage.  Foliar symptoms, although not always present, typically occur after air temperatures have been at to below normal during growth stages R3-R4, and often first appear at stage R5, peaking at stage R7.  Foliar symptoms include interveinal chlorosis and necrosis (i.e., yellowing and browning of tissue between leaf veins), followed by leaf wilting and curling.  Yield loss as a result of BSR is generally greatest when foliar symptoms develop.  The severity of BSR symptoms increases when soil moisture is near field capacity (i.e., when conditions are optimal for crop development).

Foliar symptoms of BSR can be confused with those of sudden death syndrome (see UW Plant Disease Facts D0107, Sudden Death Syndrome of Soybean).  However, in the case of sudden death syndrome (SDS), the pith of affected soybean plants will remain white or cream-colored.  In addition, roots and lower stems of plants suffering from SDS (but not those suffering from BSR) often have light blue patches indicative of spore masses of the fungus that causes SDS.

Where does brown stem rot come from? 

BSR is caused by the soilborne fungus Phialophora gregata.  There are two distinct types (or genotypes) of the fungus, denoted Type A and Type B.  Type A is the more aggressive strain and causes more internal damage and plant defoliation than Type B.  P. gregata Type A also is associated with higher yield loss.

P. gregata survives in soybean residue, with survival time directly related to the length of time that it takes for soybean residue to decay.  Thus, P. gregata survives longer when soybean residue is left on the soil surface (e.g., in no-till settings) where the rate of residue decay is slow.  P. gregata infects soybean roots early in the growing season.  It then moves up into the stems, invading the vascular system (i.e., the water-conducting tissue) and interfering with the movement of water and nutrients.

Several factors can influence BSR severity.  Research from the University of Wisconsin has shown that the incidence and severity of BSR is greatest in soils with low levels of phosphorus and potassium, and a soil pH below 6.3.  In addition, P. gregata and soybean cyst nematode (Heterodera glycines) frequently occur in fields together, and there is evidence that BSR is more severe in the presence of this nematode.

How can I save a soybean crop with brown stem rot? 

BSR cannot be controlled once plants have been infected.  Foliar fungicides and fungicide seed treatments have no effect on the disease.

How can I avoid problems with brown stem rot in the future?  

Use crop rotations of two to three years away from soybean with a non-host crop (e.g., small grains, corn, or vegetable crops), as well as tillage methods that incorporate plant residue into the soil.  Both of these techniques will help reduce BSR pathogen populations by promoting decomposition of soybean residue.  Also, make sure that soil fertility and pH are optimized for soybean production to avoid overly low phosphorus and potassium levels, as well as overly low soil pH.  Finally, grow soybean varieties with resistance to BSR.  Complete resistance to BSR is not available in commercial varieties.  However several sources of partial resistance that provide moderate to excellent BSR control are available.  Also, some, but not all, varieties of soybean cyst nematode (SCN) resistant soybeans also are resistant to BSR.  Most soybean varieties with SCN resistance derived from PI 88788 express resistance to BSR.  However, the same is not true of varieties with SCN resistance derived from Peking.  Therefore growers should consult seed company representatives about BSR resistance when selecting a variety with SCN resistance derived from this source.

For more information on brown stem rot of soybean: 

Contact the University of Wisconsin Plant Disease Diagnostics Clinic (PDDC) at (608) 262-2863 or pddc@wisc.edu.

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