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IPI International Potash Institute
IPI International Potash Institute

Research Findings: e-ifc No. 29, December 2011

Role of Potassium Nutrition in Nitrogen Use Efficiency in Cereals

Brar, M.S.(1), Bijay-Singh(1), S.K. Bansal(2), and Ch. Srinivasarao(3)

(1)Punjab Agricultural University, Ludhiana 141 004, Punjab, India. (1)Potash Research Institute of India, Gurgaon 122 001, Punjab, India. (1)Central Research Institute for Dryland Agriculture, Santoshnagar, Saidabad Post, Hyderabad 500 059, India.

Abstract

Consumption of fertilizer nitrogen (N) is increasing quantitatively, but the corresponding yield increase per unit of N (N use efficiency, NUE) is substantially diminishing over the years. Improving NUE is of paramount importance both from an economic as well as an environmental point of view. Among several strategies to improve NUE, balanced nutrition, particularly balancing N and potassium (K) nutrition and tapping into the synergistic effect of N and K, is recently gaining importance. The efficiency of fertilizer N is only 30-40% in rice and 50-60% in other cereals. There are several reports indicating the positive effects of N and K interaction in terms of crop productivity and economics, but the balance of N and K application is not appropriately practiced in many parts of the world. Positive interaction of N and K has been reported in many rainfed cereals like sorghum, pearl millet, finger millet, maize, and minor millets. In a study based on 241 site-years of experiments in China, India, and North America, balanced fertilization with N, phosphorus (P), and K increased first-year recoveries by an average of 54% compared to recoveries of only 21% where N was applied alone. In several sorghum cultivars grown in Savannah regions, improved N content and N use efficiency with K application has been reported. It has also been demonstrated that with the application of PK, the agronomic efficiency of N (AEN) improved substantially (6.7 kg grain/kg N) in sorghum and (10.3 kg grain/kg N) in pearl millet. Balanced fertilization improved both AEN as well as partial factor productivity of fertilizer N at onfarm locations.

Introduction

Fig. 1. Fertiliser response of food grain crops in irrigated areas in India.

	Source: Biswas and Sharma, 2008a.

Fig. 1. Fertiliser response of food grain crops in irrigated areas in India.

Source: Biswas and Sharma, 2008a.
click to enlarge

Inadequate application of potassium (K) combined with over application of nitrogen (N) is a serious problem in modern intensive agricultural production systems. It leads to large N losses, environmental pollution and low nitrogen use efficiency (NUE). Although fertilizer consumption is increasing quantitatively, the corresponding yield increase per unit of nutrient has diminished over the years (Sharma and Sharma, 2011; Benbi and Brar, 2011). The response ratio (kg grain/ kg nutrient) in food grain crops in irrigated areas in India (Fig. 1) substantially declined between 1960 and 2008 (Biswas and Sharma, 2008a). The need to improve NUE is therefore of paramount importance both for economical as well as environmental reasons.

K application has been neglected in many developing countries, including India, which has resulted in soil K depletion in agricultural ecosystems and a decline in crop yields (Regmi et al., 2002; Panaullah et al., 2006; Ladha et al., 2003; Wang et al., 2007b; Lal et al., 2007). Higher yields and crop quality can be obtained at optimal N:K nutritional ratios. K is an essential macronutrient required for proper development of plants. In addition to activation of numerous enzymes, K plays an important role in the maintenance of electrical potential gradients across cell membranes and the generation of turgor. It is also essential for photosynthesis, protein synthesis, and regulation of stomatal movement, and is the major cation in the maintenance of cation-anion balances (Marschner, 1995).

N is probably the major agronomic stimulant to crop growth within the farmer’s armoury. But to exploit its maximum use efficiently for increasing crop production, the crop must have access to, and take up, an adequate amount of K from the plant-available (exchangeable K) pool of K in the soil. This is because there is a strong interaction between these two nutrients in crop growth. Crop response to applied fertilizer N decreases when the exchangeable K content of a soil is below a critical target level. Because of this interaction, there is little point in applying large amounts of N when soil is low in available K, because N is used inefficiently and causes financial losses to the grower. There is also the risk that any excess unused fertilizer N lost from the soil will have adverse effects on the environment.

Among several strategies to improve NUE, balanced nutrition, particularly balancing N and K nutrition and tapping into the synergistic effect between N and K, is important both in irrigated as well as rainfed production systems (Ganeshamurthy and Srinivasarao, 2001). NUE depends on several agronomic factors including tillage, time of sowing, appropriate crop variety, proper planting or seeding, sufficient irrigation, weed control, pest/disease management, and balanced and proper nutrient use (Srinivasarao, 2010). These factors largely influence NUE, either individually or collectively. For example, selection of proper planting material, population density, and balanced fertilization could collectively improve NUE by 25 to 50% (Srinivasarao et al., 2006). Multi-site field experiments conducted in North and Northeast China also indicate that the yield responses of maize to medium K supply are greater in high-yield cultivation practices (HP) than in current cultivation practices (CP; Zhang et al., 2011).

Fig. 2. Effect of K application on nitrogen uptake in three sorghum cultivars in Guntur district in Andhra Pradesh.

	Source: Pillai and Nookaraju, 1997.

Fig. 2. Effect of K application on nitrogen uptake in three sorghum cultivars in Guntur district in Andhra Pradesh.

Source: Pillai and Nookaraju, 1997.
click to enlarge

Soil degradation is occurring due to inadequate and imbalanced fertilization leading to nutrient mining and development of second generation problems in nutrient management. The estimated supply-demand gap will be about 1.8 million tonnes of N and 1.9 million tonnes of phosphorus (P) by 2011-12. The entire demand for K will continue to be met through imports. It is of concern that the partial factor productivity of fertilizers has been continuously declining. The efficiency of fertilizer N is only 30-40% in rice and 50-60% in other cereals. The efficiency of fertilizer P is 15-20% in most crops and that of K is 60-80%. Low nutrient recovery efficiency not only increases the cost of crop production but also causes environmental pollution.

The positive N-K interaction is also dependent on the form of nitrogen supplied. K depletion of the nutrient solution enhances the absorption of NH4+-N but in contrast suppresses the absorption, translocation, and assimilation of NO3--N, simultaneously lowering leaf nitrate reductase activity (NR). This behaviour suggests that plants require an adequate supply of K for absorbing NO3--N and maintaining high levels of NRA as compared with the assimilation of NH4+-N (Ali et al., 1991). K activates plant enzyme functioning in ammonium assimilation and transport of amino acids (Hagin et al., 1990). Therefore, an adequate supply of K enhances ammonium utilization and thus improves yield when both N forms are applied together (Hagin et al., 1990). There have been numerous studies on NH4+-K interactions in different crops. K+ may alleviate NH4+ toxicity by inhibiting NH4+ uptake and/or by stimulating carbon (C) and N assimilation in the roots (Roosta and Schjoerring, 2008). The chemical similarity and identical ionic status of the NH4+ and K+ ions suggest possible substrate competition via a transport system (Jarvis 1987; Guo et al., 2007). Optimal N and K application is essential for best nutrient management in agriculture. A N-K interaction generally exists in agricultural ecosystems (Gething, 1993; Johnston and Milford, 2009). In this paper we have reviewed the N-K interaction and its effect on NUE in cereals.

NUE is an aggregate efficiency index of contributions to crop yield derived from uptake of indigenous soil N, fertilizer N uptake efficiency and the efficiency with which N acquired by plants is converted to grain yield. Cereals use fertilizer N rather inefficiently. On the basis of a large number of experiments conducted on farmer’s fields, Cassman et al., 2002 observed that generally more than 50% of the applied N is not assimilated by plants (Table 1). Under favorable weather conditions the maximum recovery efficiency of nitrogen was nearly 50%. The global cereal N use efficiency was about 33%, and an increase in 1% NUE was calculated to be worth US$234 million (Magen and Nosov, 2008).

     
  Table. 1. NUE in rice and wheat.  
  Crop Region Number of farms Average N application Recovery efficiency of N  
    kg ha-1 %  
  Rice Asia - farmers practice 179 117 ± 39 31 ± 18  
    Asia - field specific management 179 112 ± 28 40 ± 18  
  Wheat India - unfavorable weather 23 145 ± 31 18 ± 11  
    India - favorable weather 21 123 ± 20 49 ± 10  
  Source: Cassman et al., 2002.  
     

Role of K in enhancing NUE

Adequate and balanced application of fertilizer nutrients is one of the most common practices for improving the efficiency of N fertilizer and is equally effective in both developing and developed countries. In a recent review based on 241 site-years of experiments in China, India, and North America, balanced fertilization with N, P, and K increased first-year recoveries with an average of 54% compared to recoveries of only 21% where N was applied alone (Fixen and West, 2002). Much higher nutrient efficiencies could be achieved simply by sacrificing yield, but that would not be economically effective or viable for the farmer, or the environment (Srinivasarao and Subbarao, 1999).

K application and N uptake

Enhancement in uptake of N through K application ultimately helps in increasing the NUE. Yield response to K application depends to a great extent on the level of N nutrition and the interaction is normally positive (Macleod, 1969; Blevins, 1978; Loué, 1978; Guo et al., 2004; Bruns and Ebellhar, 2006; Brennan and Bolland, 2007, 2009). When a moderate N fertilizer level was supplied to wheat (112.5 kg N ha-1), yield increments of wheat after K application were higher than when N or K fertilizer was applied singly. Response to yield and the utilization of nitrogen by maize was found to be accentuated when K application was supplemented with farmyard manure (Nakashgir, 1992). However, over-application of N and K does not lead to further yield increments.

The impact of K application on N uptake was studied in three sorghum genotypes in K deficient sandy soils of Guntur district in Andhra Pradesh. In all three sorghum genotypes, K application improved the dry matter yields as well as N uptake (Fig. 2) (Pillai and Nookaraju, 1997). Optimum N:K ratios favor healthy plant growth and development whereas imbalance of N and K supply is detrimental to plant growth (Xie, 2000; Wells and Wood, 2007).

K application and protein content in plants

Application of K facilitates the uptake and transport of nitrate towards aerial parts of the plant, which in turn enhances the activities of nitrate assimilating enzymes (Anjana et al., 2009). The parallel increase in activities of nitrogen assimilating enzymes with nitrate concentration indicates that these enzymes act in a coordinated manner in order to assimilate N in plants and thus improve the NUE.

     
  Table. 2. Direct and residual effect of K on protein content in grain of pearl millet and wheat in alluvial soils of Haryana, India.  
  Nutrient application   Pearl millet   Wheat  
  Pearl millet Wheat   Protein content Protein yield   Protein content Protein yield  
  kg ha-1   % kg ha-1   % kg ha-1  
  N90P60K0 N120P60K0   09.85 211   10.62 426  
  N90P60K30 N120P60K0   10.75 257   11.13 462  
  N90P60K60 N120P60K0   11.29 282   11.74 506  
  N120P60K0 N150P60K0   10.01 244   10.86 451  
  N120P60K30 N150P60K0   10.93 297   11.45 452  
  N120P60K60 N150P60K0   11.51 329   11.87 528  
  CD (5%)   0.79     0.81    
  Source: Yadav et al., 2007.  
     

In an experiment in which pearl millet was followed by wheat in rotation, the protein content of pearl millet and wheat grain increased due to K application (Table 2). The pearl millet grain protein content increased from 9.85 to 11.29% at 90 kg N ha-1, and from 10.01 to 11.51% at 120 kg N ha-1 with the increase in K level from 0 to 60 kg K2O ha-1 (Yadav et al., 2007). Similarly, the wheat grain protein content increased from 10.62 to 11.74% at 120 kg N ha-1, and from 10.86 to 11.87% at 150 kg N ha-1 due to the increase in residual K level from 0 to 60 kg K2O ha-1. Protein yield of grains was significantly increased as a result of K application regardless of the N level. These results show that K improves NUE by favouring protein formation.

Fig. 3. Impact of K application on protein content of pearl millet in Alluvial soils of Haryana, India. (N and P2O5 applied were 120 and 60 kg ha-1, respectively.)

	Source: Yadav et al., 2007.

Fig. 3. Impact of K application on protein content of pearl millet in Alluvial soils of Haryana, India. (N and P2O5 applied were 120 and 60 kg ha-1, respectively.)

Source: Yadav et al., 2007.
click to enlarge

Similarly, application of K in a pearl millet-mustard rotation also increased the grain protein content of pearl millet, which was significantly greater than the control at 40 kg K2O ha-1 (Fig. 3). Protein yield (grain yield X % protein) was significantly increased due to K application, probably via the effect of K promoting photosynthate mobility to increase the utilization of N. Protein yield of pearl millet was increased from 252 to 340 kg ha-1.

Application of K favours an increase in grain protein and amino acid contents (Yang et al., 2004; Venkatesan et al., 2004; Zou et al., 2006b), but responses vary among cultivars (Zou et al., 2006b). Compared with Ningmai 9 (a low-protein wheat cultivar), the role of K in improving the protein content of grain was greater in Yangmai 10 (a medium-protein wheat cultivar). Protein content in wheat grain showed a close positive correlation with N accumulation and translocation (Zou et al., 2006b).

K application and N recovery efficiency (REN)

     
  Table. 3. Effect of balance fertilization on yield and AEN.  
  Crop Yield   Agronomic efficiency (AEN)  
  Control N alone +PK   N +PK Increase  
    mt ha-1   kg grain kg N-1  
  Pearl millet 1.05 1.24 1.65   4.7 15.0 10.3  
  Maize 1.67 2.45 3.24   19.5 39.0 19.5  
  Sorghum 1.27 1.48 1.75   5.3 12.0 6.7  
  Source: Prasad, 2009.  
     

The large number of multi-location onfarm field experiments conducted in India shows the importance of balanced fertilization in increasing crop yield and improving NUE (Table 3). AEN improved from 6 to 20% in predominant rainfed crops. Based on several balanced nutrition experiments, it was reported that AEN improved with the application of P and K by 6.7 kg grain/kg N in sorghum, 10.3 in pearl millet, and 19.5 kg grain/kg N in maize (Prasad, 2009).

     
  Table. 4. REK and increase of NUE on maize.  
  Treatment* REK (%)**   NUE increase (%)***  
  Range Mean   Range Mean  
  N1K0 - -   - -  
  N1K1 26.7-39.5 33.8   9.4-22.3 14.8  
  N1K2 38.3-42.7 40.5   20.7-25.1 22.2  
  N1K3 39.2-43.6 38.3   20.7-36.7 29.7  
  N2K0 - -   - -  
  N2K3 29.0~38.2 29.3   12.2~25.1 18.3  
  Source: Xie et al., unpublished data; In: Zhang et al., 2011.  
  * These experiments were conducted in Suiping and Xiping County, Henan Province, and Feidong County, Anhui province. The N1 and N2 rates were 195-240 and 255-312 kg N ha-1. The K1, K2 and K3 rates were 105,150 and 195 kg K2O ha-1.
** Recovery efficiency of K (%) = Plant K uptake [(K fertilized – K unfertilized)/amount of K fertilizer] ×100.
*** Increase of use efficiency of N (%) = Plant N uptake [(K fertilized – K unfertilized)/amount of N fertilizer] ×100.
 

The highest biological yield of wheat was obtained by foliar application of KCl along with N as urea compared with other treatments, namely, the control (no spray), KNO3, KCl, and N as urea only (Khan et al., 2006). A positive N-K interaction has been reported in many long-term experiments (Belay et al., 2002; Cai and Qin, 2006; Wang et al., 2007a). Response to K applications in both rice and wheat increases with N application, indicating that higher K rates are required at higher N rates (Mondal, 1982). The recovery efficiencies of K (REK) and N fertilizer in maize increased at 105-150 kg K2O ha-1 and 195-240 kg N ha-1 (Table 4). Optimal N-K ratios favored crop growth and enhanced K and NUE. N-K interaction is not only positive for yields of rice and groundnut (Table 5) but it also improved the AEN.

     
  Table 5. N-K interaction effect on yield and AEN in rice and groundnut.  
  K rates N rates (kg ha-1)   N rates (kg ha-1)  
  60 80 60 80   60 80 60 80  
  Rice yield AEN   Groundnut pod yield AEN  
  kg ha-1 mt ha-1 kg ha-1   mt ha-1 kg ha-1  
  0 3.10 3.02       1.68 1.70      
  30 3.40 3.30 5.16 3.50   1.84 1.93 2.66 2.87  
  60 3.64 3.61 9.00 7.37   2.07 2.15 6.50 5.62  
  90 3.75 3.83 10.83 10.12   2.06 2.23 6.30 6.62  
  Mean 3.48 3.44       1.91 2.00      
  LSD (0.05): N=NS, K=0.10, N×K=0.12   N=0.05, K=0.08, N×K=NS  
  Source: Mitra et al., 2001.  
     

The interactions between N and K on crop growth and final yield seen at the agronomic level can be explained by their effects and interactions on the growth processes within the plant at the tissue and individual cell levels. Knowing how growth is controlled by these interactions within the plant makes it easier to understand why it is important to have sufficient exchangeable K in the soil. K has the property of high phloem mobility and, as a result, a high degree of reutilization by re-translocation via the phloem (Marschner, 1995; Marschner et al., 1997). K cycling and recycling play an important part in NO3- translocation from root to shoot as counter ion and assimilate loading in the phloem (Maathuis, 2007). The partitioning and the amount of phloem re-translocation of K+ from the shoot and cycling through the root are quite different depending on plant type and can be changed by stress (Jiang et al., 2001; Lu et al., 2005). Cycling and recycling of K+ increased with increasing shoot growth rate, which is in accordance with the suggested role of K+ for charge balance of NO3- in the xylem and organic acids in the phloem (Engels and Kirkby, 2001). The changes in K+ concentration in the cortex were related to the role of K+ in the transport of NO3- in the xylem and effects on recycling to the roots in the phloem (Jarvis et al., 1990). The effect of K in increasing agronomic efficiency may vary under different situations. With the application of 50 kg K2O ha-1 the AEN was much higher in sorghum fodder (f) as compared to wheat (Table 6).

     
  Table 6. Effect of N-K interaction on yield and AEN in wheat and sorghum.  
  K rates N rates (kg ha-1) AEN N rates (kg ha-1) AEN  
    0 120   0 80    
    Wheat yield   Sorghum (f) yield    
  kg ha-1 kg ha-1 kg kg-1 kg ha-1 kg kg-1  
  0 1.42 1.52 0.83 5.27 5.24 -  
  50 1.89 2.12 1.85 5.48 6.72 15.5  
  Mean 1.63 1.82   5.37 5.98    
  LSD(0.05): N=0.16, K=NS, N?K=NS N=0.42, K=NS, N?K=0.53  
  Source: Golakiya et al., 2001.  
     

K application and partial factor productivity of N (PFPN; kg yield per kg N applied)

Fig. 4. Effect of applied K on PFPN and yield of rice, wheat and pearl millet.

	Adapted from: Magen and Nosov, 2008; Yadav et al., 2007.

Fig. 4. Effect of applied K on PFPN and yield of rice, wheat and pearl millet.

Adapted from: Magen and Nosov, 2008; Yadav et al., 2007.
click to enlarge

In India, the PFPN is decreasing over time. An initial decline in PFPN is an expected consequence of the adoption of N fertilizers by farmers and is not necessarily a problem within the system contexts (Bijay-Singh and Yadvinder- Singh, 2008). However the low PFPN during the last decade is due to low fertilizer NUE and is of particular concern. The application of K not only improved the yield of rice, wheat and pearl millet but also improved the partial factor productivity of applied N (Fig. 4). The study carried out by Yadav et al. (2007) further revealed that application of K increased the partial factor productivity of N irrespective of the level of applied N (Table 7). The PFPN in pearl millet was increased at the application of 90 kg as well as 120 kg N ha-1 but the increase at the higher level of N was more the result of the combination with the high level of K.

     
  Table 7. Effect of K application on PFPN in pearl millet at two levels of applied N.  
  K rates (kg K ha-1) 90 kg N ha-1   120 kg N ha-1  
    PFPN Increase   PFPN Increase  
    kg kg-1 %   kg kg-1 %  
  20 23.8 -   20.3 -  
  40 26.6 11.7   22.6 11.3  
  60 27.8 16.8   23.8 17.3  
  N level 120 kg N ha-1  
  Source: Yadav et al., 2007.  
     

Application of K greatly influenced PFPN (kg grain/kg applied N) in maize. At different locations/years and with the application of K the PFPN varied from 21.1 to 53.3 kg grain/kg applied N (Table 8). Averaged over years and sites the PFPN was 32.7, 35.3, 38.0, and 39.0 kg grain/kg applied N at 0, 30, 60, and 90 kg of applied K2O ha-1. The graded levels of applied K increased PFPN by 7.9, 16.2 and 19.3%, over K0 application. Nitrogen recovery (kg N uptake/kg applied N) varied from 19 to 50% at different locations/years and on average increased from 32 to 41% in K0 and K90 treated plots, indicating the favorable effect of applied K on N utilization. The practical implication of this will be the improved utilization and a lower loss of applied N under balanced fertilization.

     
  Table 8. Effect of K on PFPN (kg grain kg-1 N) and apparent N recovery (%) in maize.  
  K level 2003 2004 2005 2006 2007 Average Increase
over K0
 
  kg K2O ha-1 PFPN (kg kg N-1) %  
  0 21.1 32.0 26.8 38.2 45.4 32.7 -  
  30 24.2 37.9 27.3 39.5 47.6 35.3 7.9  
  60 27.0 41.8 27.4 41.3 53.3 38.0 16.2  
  90 26.4 40.9 30.9 48.2 48.8 39.0 19.3  
    Apparent N recovery (%)    
  0 19 32 30 41 40 32 -  
  30 22 39 31 41 44 35 9.3  
  60 24 44 30 41 42 36 12.5  
  90 23 46 37 50 47 41 28.1  
  Source: Brar et al., unpublished data.  
     

 

K application and NUE

Fertilizer NUE is controlled by many factors such as crop demand for N, supply of N from the soil, fertilizer and manure application and losses of N from the soil-plant system. Imbalanced and inappropriate use of N and other nutrients such as K in agro-ecosystems can modify NUE. On-farm experiments carried out by IPI in Asia and Europe suggest that besides yield, the NUE, on average, can be increased from 15.5% in the Ukraine for maize to 26.3% for rice in Bangladesh with the application of appropriate amounts of K (Table 9). The NUE normally depends on the extent of deficiency of K. On K deficient alfisols in Bangalore, India, there was a spectacular increase in NUE with the application of K. In the absence of applied K the application of both N and P failed to improve the NUE. NUE increased from 10% to 90% with the application of K on red laterite K deficient soils (Vasuki et al., 2009, Srinivasarao 2010) (Fig. 5).

   
 Table 9. Increase in grain yield and NUE achieved at IPI on-farm experiments in Asia and Europe. 
 Crop Country N rates K rates Yield
increase
Increase in
NUE
 
  kg ha-1% 
 MaizeIndia12530-90200-130018 (6-29) 
  China15075-180200-180018 (5-29) 
  Ukraine303072015.5 
 RiceBangladesh10033-66690-90026.3 (23-30) 
 Wheat China 90 60-120 230-610 10-23  
 Range in brackets. 
 Source: Magen and Nosov, 2008. 
     

Conclusion

Fig. 5. NUE in finger millet with K application on K deficient Alfisols in Bangalore, India.

	Source: Vasuki et al., 2009.

Fig. 5. NUE in finger millet with K application on K deficient Alfisols in Bangalore, India.

Source: Vasuki et al., 2009.
click to enlarge

Balancing the fertilizer N application of different crops with fertilizer K is an urgent need to achieve higher NUE.

A gain of 20% in NUE can easily be achieved via balanced fertilization with K. A positive relationship between N and K exists for the uptake and utilization of N by plants to form protein and amino acids which ultimately affect the quality and yield of crops. Balanced use of N and K fertilizers in cereals and other crops will not only prove more profitable for farmers but also lead to reduced environmental degradation and climate change effects caused by dissipation of N originating from agricultural soils.

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The paper "Role of Potassium Nutrition in Nitrogen Use Efficiency in Cereals" appears also at: Regional Activities/India and N-K Interaction Center