Skip Navigation

1/17/2011 - 1/23/2011

New Soybean Disease Guide Now Available

By Daren Mueller, Department of Plant Pathology

A new publication from Iowa State University and the Iowa Soybean Association is designed to help farmers more effectively manage soybean diseases when they appear.

The publication, “Soybean Diseases” (CSI 0004), is a comprehensive compilation of soybean disease and management information. The 36-page guide includes information on 24 soybean diseases and features an overview of the major causes of plant disease; several photos of each disease; a glossary; and quick visual cues indicating which diseases are seed-transmitted.

Copies can be ordered online free of charge through the ISU Extension Online Store at www.extension.iastate.edu/store. There will be a charge for shipping and handling.

This is the first complete publication on soybean diseases Iowa State has produced. Iowa State has created other issue-specific publications, but this is the first to put all that information in one place. The new publication was developed to mesh with existing scouting resources.

The new publication offers more detailed disease information and outlines management options once the disease is identified using the scounting field guide.

The publication was written by Daren Mueller and ISU Extension colleagues Alison Robertson, plant pathologist; Greg Tylka, nematologist; and Adam Sisson with the ISU Corn and Soybean Initiative. Funding was supplied by the Iowa soybean checkoff, ISA and ISU Extension.

 

Daren Mueller is an extension specialist with responsibilities in the Corn and Soybean Initiative and ISU's IPM program. Mueller can be reached at (515) 460-8000 or by email at dsmuelle@iastate.edu.

Conference Looks at Using Climate Information to Assess Expected Yields

How did weather conditions in 2010 impact global corn yield and corn markets?  What weather impacts on global production are anticipated this spring?  These questions will be addressed at the 9th Annual NOAA Climate Prediction Applications Science Workshop to be held at the Des Moines Downtown Marriott on March 1 - 4. 

With increasing demands on U. S. agricultural production, NOAA is engaging in dialogue with producers and agribusiness to identify ways in which climate information may be delivered more efficiently through existing National Weather Service products and an emerging NOAA Climate Service. As a step in this process, a full day of presentations is scheduled for March 1 on the use of climate information in assessing expected yields, beginning with keynote presentations from USDA Undersecretary for REE Dr. Catherine Woteki and NOAA Administrator Dr. Jane Lubchenco. 

The day will be capped by a panel of agribusiness representatives who will discuss how climate information enters into their decisions and what additional information would enable them to better navigate market volatility. The panel will include representatives from Iowa Farm Bureau, Monsanto, Telvent DTN Ag Weather, Ag Resource, and ARMTech Insurance Services.


The full conference agenda and registration is available online. For more information, contact Christopher Anderson at cjames@iastate.edu.

 


Christopher Anderson is a research assistant professor and assistant director of the Iowa State University Climate Science Program. He can be reached at cjames@iastate.edu or by phone at 515-294-9948.

Spread of Glyphosate Resistant Weeds

by Bob Hartzler, Department of Agronomy

After more than a decade of discussions about glyphosate resistant (GR) weeds, three GR species (horseweed, waterhemp and giant ragweed) have been verified in Iowa.  Research conducted by Iowa State and others has confirmed glyphosate resistance in isolated fields across Iowa. Although GR weeds are found throughout the state, at this time it is estimated less than one percent of Iowa’s corn and soybean fields are infested with GR at levels of economic concern. This article will discuss how GR weeds can appear in fields where they currently are not problems.

Herbicide resistance can become a problem due to two distinct mechanisms. The first involves independent selection of a resistant biotype from the weed community already present in the field. The other involves movement of the resistant trait (gene flow) from a field with an existing resistance problem to fields without resistance. This spread can occur due to either pollen or seed movement.

waterhemp seedling

Waterhemp, shown here as a seedling, is one of three weed species verified to be glyphosate resistant in Iowa.
 

Independent selection 
Herbicide resistant biotypes are present at low frequencies within the weed community prior to the discovery and introduction of a herbicide. The initial frequency of resistance is the percentage of the weed population possessing the resistant trait at the time of herbicide introduction. Repeated use of an herbicide results in resistant biotypes becoming more prevalent, and eventually they may become the dominant biotype and thus the weed is no longer effectively controlled by the herbicide. Evolution of resistance within a field is a direct result of the weed management program used within the field and the initial frequency.

The initial frequency of herbicide resistance varies among herbicide classes. With ALS inhibitors, resistance is present at a relatively high initial frequency and it was likely that resistant biotypes of certain weed species were present in most Iowa fields at the time of introduction of these herbicides (mid 1980s). It is believed that the spread of ALS resistant waterhemp across Iowa was largely due to selection of resistant biotypes from native infestations within individual fields.

Glyphosate resistance in plants is a rare trait, and thus it is likely that GR weeds were not present in most fields when we began to rely on glyphosate for weed control. Even though glyphosate has been used in a way favoring the selection of GR in the majority of fields across Iowa, GR weeds will only appear due to independent selection in those fields ‘unlucky’ enough to have one of the rare GR biotypes.

Gene flow 
Now that GR biotypes have evolved in isolated fields across the state, the risk of resistance appearing in ‘clean’ fields is probably as great due to movement from fields with existing GR problems as it is from independent selection. Gene flow may occur either from pollen or seed movement. The likelihood of these two mechanisms of gene flow varies with characteristics of the resistance trait, biology of the weed and the weed management systems used in adjacent fields.              

Although the inheritance of GR has not been characterized in all GR biotypes, where it has been identified, heritability is an incompletely dominant trait. Thus, cross-pollination between a resistant (R) and susceptible (S) weed biotype will result in increased resistance to glyphosate in the hybrid plant (S x R). Both waterhemp and giant ragweed produce large quantities of pollen that move long distances by wind currents – thus pollen movement is a threat to spread GR in these two species.
              
Researchers at the University of Illinois developed a model to help understand gene flow of GR in waterhemp via pollen movement (Liu et al. 2010). Their model predicted that GR could spread approximately three miles per year by wind dispersal of pollen, thus any field within a three mile radius of a field with GR waterhemp is at risk of resistance becoming established. 

It is important to understand that GR will not move into every field within this radius due to several factors. The GR trait can only become established in fields where receptive waterhemp plants are present to intercept the pollen. Also, the greater the distance from the source field, the less likely a pollen grain is to pollinate a susceptible waterhemp plant. Finally, in order for GR to become established in the field, the weed management program being used must rely heavily on glyphosate. If the weed management program includes herbicides having different mechanisms of action than glyphosate that are effective on waterhemp, there is no advantage for the GR trait and it is unlikely that the resistant biotype would become permanently established in the field.

Herbicide resistant traits can also spread via movement of seed from the source field to fields free of the resistant biotype. Neither waterhemp nor giant ragweed have seed possessing long distance dispersal mechanisms. However, the lack of dispersal mechanisms is not a limitation since seeds can easily be transported by machinery. GR waterhemp was found more than 25 miles from the source field two years after resistance was identified (Liu et al. 2010), thus it moved much farther than the pollen transfer model predicted. The researchers speculated that seed movement by farm machinery or independent selection was responsible for the appearance of GR a long distance from the source field.  

Summary 
Glyphosate has been heavily relied upon for weed management since the introduction of Roundup Ready soybeans in 1996. This widespread use has resulted in the selection of GR biotypes throughout Iowa. Now that resistant biotypes are present, the spread of GR across the landscape is probably greater due to gene flow rather than the independent selection of resistant biotypes. This is due to the low initial frequency of glyphosate resistance within weed populations.

Does the threat of resistance movement via gene flow mean it is futile for individual farmers to prevent GR from appearing in fields they manage? The answer is no, and in fact, it places greater emphasis on the value of diversified weed management systems.  A diverse herbicide program continually places different herbicide stresses on the weed community. This greatly reduces the benefit of the GR trait to weeds, and therefore reduces the likelihood of resistant biotypes becoming established in fields currently free of the resistant trait. Use of diverse management programs will maintain the value of glyphosate by reducing the spread of GR weeds.

Reference
Liu, J., P.J. Tranel and A.S. Davis.  2010.  Modeling the spread of glyphosate resistant waterhemp.  Proc. North Cent. Weed Sci. Soc.

 

Bob Hartzler is a professor of agronomy with extension, teaching and research responsibilities.



This article was published originally on 1/24/2011 The information contained within the article may or may not be up to date depending on when you are accessing the information.


Links to this material are strongly encouraged. This article may be republished without further permission if it is published as written and includes credit to the author, Integrated Crop Management News and Iowa State University Extension. Prior permission from the author is required if this article is republished in any other manner.