When planting soybeans in Kansas, it may be a good insurance policy to inoculate the seed. The Bradyrhizobium bacteria form nodules on soybean roots, and these nodules fix nitrogen from the atmosphere and supply it to the plants. Neither soybeans nor Bradyrhizobium japonicum are native to the United States, so there will be no Bradyrhizobium japonicum in the soil unless it was introduced at some time in the past by inoculated soybean seed.
Why do we need to inoculate soybeans?
- To promote good nodulation
- To improve nitrogen (N) fixation
- To help ensure a stable yield
Soybeans are big users of nitrogen. For example, a soybean yield of 60 bushels per acre requires 300 lbs N per acre in the plants, requiring about 3-4 lbs of N per bushel of seed (Figure 1). Most of the N required by a soybean plant is supplied via biological nitrogen fixation that takes place in nodules on the soybean roots. When well established, the N fixation process can provide 40-80 percent of the plant’s N needs for the season. The actual contribution of N fixation to the N requirement of soybeans can be influenced dramatically by the amount of residual or mineralized N available in the soil profile or by stress conditions affecting the plant such as drought and heat, inhibiting N fixation due to the cost of maintaining the N fixation process.
Figure 1. Soybean yield and plant nitrogen uptake relationship. Data reviewed and synthesized by Dr. Ciampitti, K-State Research and Extension – from Ciampitti and Salvagiotti, 2018, Agronomy Journal.
Yield responses to inoculation have been quite variable in Kansas and other surrounding states. However, the cost of buying pre-inoculated seed, or inoculating the seed or soil yourself, is low and the potential yield loss from poor inoculation can be significant unless available soil N levels are high.
Soybeans that are poorly nodulated will have to take up most of the N they need from the soil, just like corn, sorghum, wheat, or any non-legume crop. Because N fertilizer is generally not applied for soybeans, a poorly nodulated crop will quickly use up the available N in the soil and become chlorotic (yellow) from N deficiency. For poorly nodulated soybeans, N deficiency is usually evident later in the growing season as the nutrient demand increases (Figures 2, 3).
Figure 2. The soybeans in the part of the field at left in this photo had good nodulation. The area of the field on the right had poor nodulation and exhibited nitrogen deficiency symptoms. Photo by Tom Maxwell, K-State Research and Extension.
Figure 3. Well-nodulated soybean plants (left) compared to plants without nodulation. Photo by Kraig Roozeboom, K-State Research and Extension.
Why is the yield response to inoculation so variable?
There are several reasons for the variability in yield response to inoculation. For one thing, if soybeans have been grown on the field in previous years, there may be enough Bradyrhizobium bacteria in the soil to nodulate the soybeans adequately, in which case an inoculant may not benefit the crop. But if there is not enough Bradyrhizobium in the soil, the inoculant may increase yields by 2 bushels per acre or more on fields that have had soybeans in the recent past. On fields where soybeans have never been grown, the inoculant can often increase yields by 10 bushels per acre or more (Table 1).
Table 1. Effect of soybean inoculant on land with no prior history of soybeans
|
Kansas River Valley Experiment Field, Rossville |
Southwest Research-Extension Center, Garden City |
|
|
Treatment |
Soybean yield (bu/acre) |
|
|
None |
56.9 |
33.9 |
|
Seedbox inoculant |
57.8 |
39.6 |
|
Seed-applied inoculant |
66.4 |
43.5 |
|
LSD (.05) |
9.8 |
3.6 |
Source: C.W. Rice and L.D. Maddux, Kansas Fertilizer Research 1992, K-State Report of Progress 670; C.W. Rice and M. Witt, Kansas Fertilizer Research 1991, K-State Report of Progress 647.
Even on fields with no history of soybean production, inoculation may increase nodulation but still have no effect on yields – especially if the yield environment is low and soils have enough available N to supply the crop’s needs.
Yield response to inoculants can also depend on soil pH, environmental conditions, and other factors. For instance, if lack of precipitation limits yields to less than 30 bushels per acre, poor nodulation may not impact yield. However, if rainfall is favorable, and yield potential is high, poor nodulation could result in a substantial N deficit and reduced yield.
Based on previous information, inoculation is most likely to increase soybean yield when:
- Soybean has not been planted in the past 3 to 5 years or if it is only the second or third soybean crop on the field, regardless of time since the last soybean crop
- Soil pH is below 6.0
- Soil has a high sand content
- Field has been flooded for more than a week, creating anaerobic conditions, when nodulation was supposed to become established
- Early-season stress conditions (e.g. heat) affect plant-bacteria establishment
Producers should be aware that inorganic soil N will reduce nodulation and N fixation by Bradyrhizobium japonicum bacteria. Where soil N levels are 40-60 lbs per acre or more, soybean plants may look fine, yet have reduced nodulation. There may be little or no nodulation at very high N levels, such as where the field was fertilized for corn but the producer decided to plant soybeans instead. Depending on soybean yield and amount of residual N, this may be enough to carry the soybean crop for much of the season, but it may end up being N deficient during seed fill. In most cases, up to 40 lbs N per acre can be applied as a starter fertilizer to help get the soybeans started without having any detrimental effect on nodulation during the growing season (unless the upper layer of soil is already rich in inorganic N at planting time).
Soybean inoculation is basically “cheap insurance” against a potential N deficiency problem. Even if soybeans have been planted in the field recently, it doesn’t cost much to inoculate the seed.
Ignacio Ciampitti, Farming Systems
ciampitti@ksu.edu
Kraig Roozeboom, Crop Production Agronomist
kraig@ksu.edu
Chuck Rice, Soil Microbiologist
cwrice@ksu.edu