Fertilizer-dependent efficiency of Mesorhizobium strain for improving growth, nutrient uptake and grain yield of durum wheat (Triticum turgidiumL.) variety
 Volume 61, Article 04 | [Volume 61, Article 04] | 359 kB |
I. HEMISSI1
R. HAMMAMI1
A. HACHANA1
H. ARFAOUI1
B. SIFI1
1 National Institute for Agricultural Research, Laboratory of Agricultural Science and Technology, Av. Hédi Karray 2080 Ariana, Tunis, Tunisia.
Abstract – The search for microorganisms that improve soil fertility and enhance plant nutrition has continued to attract attention due to the increasing cost of fertilizers and some of their negative environmental impacts. Acquisition of nutrients by plants is primarily dependent on root growth and bioavailability of nutrients in the rooting medium. Most of the beneficial bacteria enhance root growth, but their effectiveness could be influenced by the nutrient status around the roots. In this study we aimed to investigate the effects of plant-growth-promoting rhizobacteria (PGPR) on durum wheat variety. To achieve this goal, the inoculation of durum wheat seeds by Mesorhizobium strains carried out in order to assess the positive impact of PGPR on growth, nutrientuptake and grain yield under different conditions of N fertilization (at 0%, 25%, 50%, 75%, and 100% of recommended doses). Results of field trials revealed that the efficacy of these strains for improving growth and yield of wheat reduced with the increasing rates of N added to the soil. In most of the cases, significant negative linear correlations were recorded between percentage increases in growth and yield parameters of wheat caused by inoculation and increasing levels of applied N fertilizers. It is highly likely that under low fertilizer application, the inoculation of wheat durum seeds by Mesorhizobium strain might have caused reduction in the synthesis of stress (nutrient)-induced inhibitory levels of ethylene in the roots through ACC hydrolysis into NH3. The results showed also a synergetic effect of Mesorhizobium strain on nutrient uptake in wheat plant. The results of this study imply that these Mesorhizobium strains could be employed in combination with appropriate doses of fertilizers for better plant growth, better nutrient uptake and savings of fertilizers. The PGPR-based inoculants can be used as components of integrated nutrient management strategies.
Keywords: durum wheat, Mesorhizobium, PGPR, nutrient uptake, Nitrogen
1. Introduction
Durum wheat (Triticum turgidum L.var.durum, 2n=4x = 28; AABB), is the most extensively cultivated cereal in the Mediterranean area (Araus et al., 2003). It originated in the Fertile Crescent, and more particularly in the mountains regions that surround the fertile alluvial plains of the Tigris and Euphrates rivers (Braidwood, 1969). Durum wheat is the most produced crops, easily stored and transported, and an important nutritional source for humans (Arregui and Quemada, 2008). In Tunisia, wheat accounts for 60% of national cereal production and high yielding varieties need large and regulate supply of N to develop high photosynthetic capacity and maintain the proper nitrogen concentration in the leaves when N large rates are required for ear growth and grain filling period (Ayadi et al., 2012). In semi arid regions, fertilizer management is a key to successful durum wheat production. In Tunisia, nitrogen is the major limiting nutriment of durum wheat production because it affects plant growth, development and also grain yield. Several reports showed that N application increased significantly grain yield of wheat, number of fertile tiller per unit area, number of grain per spike and harvest index (Mandic et al., 2015). Dencic et al. (2011) and Flores et al. (2012) recorded increased grain yield and its components with increase in nitrogen level. The concern with having enough food with good quality has become widespread in the world. Therefore, healthy agriculture systems for food production without using agriculturalchemicals have become the main interest of the scientists to minimize the harmful effectsof intensive farming of fields (Turan, Ataoglu, and Sahin 2006; Savci 2012). It is admitted that over use of fertilizers can cause unanticipated environmental impacts (Kohler et al. 2009). Several studies reported that the biggest issue facing the use of chemical fertilizers is groundwater contamination (Yu et al. 2010; Yan et al. 2000; Sun et al 2012). Nitrogen fertilizers break down into nitrates and travel easily through the soil. Because it is water-soluble and can remain in groundwater for decades, the addition of more nitrogen over the years has an accumulative effect. One potential way to decrease negative environmental impacts resulting from continued use of chemical fertilizers is inoculation with plant growth promoting rhizobacteria (PGPR). These rhizobacteria significantly affect plant growth not only by increasing nutrient cycling, also by suppressing pathogens by producing antibiotics and siderophores or by bacterial and fungal antagonistic substances and / or by other plant hormones. A divers array of bacteria including Pseudomonas, Azospirillum, Azotobacter, Bacillus, Klebsilla, Entrobacter and Serratia have been shown to promote plant growth (Khalid et al., 2004). PGPR plays an important role in enhancing plant growth through a wide variety of mechanisms. The mode of action of PGPR that promotes plant growth includes (i) abiotic stress tolerance in plants;(ii) nutrient fixation for easy uptake by plant (iii) plant growth regulators; (iv) the production of siderophores; (v) the production of volatile organic compounds; and (vi) the production of protectio lytic-enzyme such as chitinase, glucanase and ACC-deaminase for the prevention of plant diseases (Choudhary et al. 2011; Garcia-Fraile et al. 2015).
Chemical fertilizers often have low use efficiency, meaning that only a portion of the applied nutrients are taken up by plants. For example, P is precipitated after addition to soil, thus becoming less available to plants (Gyaneshwar et al. 2002). In addition, applied N can be lost through nitrate leaching, resulting in contamination of groundwater. Microbial inoculants have shown some promise in increasing nutrient availability. For example, previous reports have suggested positive impacts of microbes on N uptake involving non-legume biological fixation (Aseri et al. 2008). Also, inoculation with some microbes, including Rhizobium, resulted in P solubilization or enhanced plant uptake of fixed soil P and applied phosphate resulting in higher crop yield (Hemissi et al 2015). The main mechanism resulting in increased availability of inorganic P appears to be through the action of organic acids synthesized by inoculants (Hemissi et al 2015). The use of PGPR for improving plant nutrition and thus partially compensating the need of chemical fertilizers is becoming a popular strategy for sustainable agriculture (Karlidag et al. 2007). Nevertheless, there is a great deal of inconsistent information on the effectiveness of PGPR (such as Azospirillum species) on plant growth in soil amended with various levels of fertilizers (Lucy et al.2004).The objectives in this study were to determine (1) ifreduced rates of inorganic fertilizer (N) coupled with microbialinoculants (Mesorhizobiumstrain) will produce plantgrowth, yield, and nutrient uptake levels (N, P and k) equivalent to thosewith full rates of the fertilizer and (2) the minimum level towhich fertilizer could be reduced when inoculants wereused. To achieve these objectives, experiments weredesigned using Mesorhizobium strain coupled with differentfertilizer regimes. TheMesorhizobium strain studied was previously reported to elicit significant effects on root development, plant growth, biocontrol, and/or induced systemic resistance (Hemissi et al. 2011, 2015).
2. Materials and Methods
2.1. Bacterial strain and growth conditions
Mesorhizobium strain Pch Beja was obtained from INRAT (Hemissi et al., 2013, 2015). This PGPR possess ACCdeaminase activity, auxins production, phosphorus solubilization and antifungal activity. This strain was grown at 28°C on yeast extract mannitol (YEM) medium containing 0.08% of yeast extract (w/v) and 1% of mannitol (w/v). The bacterial isolate derived from single colonies.
2.2. Production of bacterial inoculum
Bacterial inoculum was prepared in 250 ml flasks containing YEM. After inoculation with bacteria, the flasks were incubated on a rotator shaker at 120 rpm at 28°C for 72 h. Before use, bacterial concentration was adjusted to 108cells ml-1 (OD 620 0.8-0.9).100 ml of bacterial inoculum was added to each elementary plot.
2.3. Field trials
Field trials were conducted at El Marja station which belongs to theNational Institute of the field Crop (INGC) in northern Tunisia at late October to early julyduring the cropping season 2015–2016., the annual mean rainfall is about 560 mm with amedian air temperature of 19°C; the soil is a vertisol with an average content of available. P and total N of 32 and 2.77mg Kg-1. The durum wheat variety “Karim” and a Mesorhizobium strain previously tested in greenhouse were studied under field conditions. The field experiment consisted of 8 different treatments (Table1). The experiment was repeated 4 times in completely random block design. The surface of an experimental plot is 500 m2 devised into 40 elementary plots of 8 m2separated by 2 m. Seeds were hand sown on plots. Seed sowing density was 150 kg ha-1. At emergence of seedlings stage, the number of seedlings emerging per m2 was evaluated using a 1/2 m2 iron ring. Plants in plots were harvested 220 days after sowing. Yield parameters evaluated were: grain yield (kg ha-1), 1000-seed weight, number of spikes per m2, and number of grains per spike. These parameters were determined after creating clearances of 1 m at the edges of each plot, and 2 sowing lines at each side. Nitrogen, Phosphorus, and Potassium contents in grain and straw samples were determined using the procedure described by Ryan et al. (2001).
|
Table 1.The ten treatments conducted under field conditions. |
|
|
T1: |
unfertized soil (control plants) |
|
T2 |
N fertilizer was applied to soil at 25% of the recommended doses for durum wheat |
|
T3 |
N fertilizer was applied to soil at 50% of the recommended doses for durum wheat |
|
T4 |
N fertilizer was applied to soil at 75% of the recommended doses for durum wheat |
|
T5 |
N fertilizer was applied to soil at 100% of the recommended dose for durum wheat |
|
T6 |
unfertilized soil and plant inoculated with Mesorhizobium strain (100 ml of inoculants/ elementary plot) |
|
T7 |
Plant inoculated with Mesorhizobium strain (100 ml of inoculants/ elementary plot) plus 25% dose fertilized |
|
T8 |
Plant inoculated with Mesorhizobium strain (100 ml of inoculants/ elementary plot) plus 50% dose fertilized |
|
T9 |
Plant inoculated with Mesorhizobium strain (100 ml of inoculants/ elementary plot) plus 75% dose fertilized. |
|
T10 |
Plant inoculated with Mesorhizobium strain (100 ml of inoculants/ elementary plot) plus 100 % dose fertilized. |
2.4. Statistical Analysis
The experimental design was a randomized complete block. Statistical analyses were performed by SPSS 20.0 software (SPSS, Chicago, IL, USA). The data were analysed using ANOVAs and subsequent comparison ofmeanswas performed using the Fisher’s LSD test at 5% probability.
3. Results and Discussion
Developing crop cultivars with high grain yield has been the principal aim of durum wheat breeding programs worldwide. In this context, Garcia el Moral (2003) has mentioned that in the Mediterranean region, it is of special interest because of the low and erratic distribution of rainfall, which has explained as much as 75% of the variation in wheat yield (Blum and Pnuel, 1990). Under semi arid region, an optimal nutrient provision is an important factor to get high yield. Nitrogen is one of the most important elements of plant nutrition; It is also one of the most mobile plant nutrients in the soil. Today, Fertilizers are essential components of modern agriculture because they provide essential plant nutrients. However, overuse of fertilizers can cause unanticipated environmental impacts. In fact, applied N can be lost through nitrate leaching (Huang et al., 2018), resulting in contamination of groundwater. One potential way to decrease negative environmental impacts resulting from continued use of chemical fertilizers is inoculation with plant growth promoting rhizobacteria (PGPR). These bacteria exert beneficial effects on plant growth and development (Bakker et al. 2007). Recent studies have shown that some PGPR can be a great alternative to agrochemicals for increasing plant development (Sharma, 2013; Gupta, 2015) by increasing nutrient availability. The effectiveness of the bacterial inoculum is related to the characterization of multiple PGPR activities such as the production indole acetic acid (IAA), hydrogen cyanide (HCN), siderophores, of phosphate solubilization, as well as the antifungal activity. For example, previous reports have suggested positive impacts of microbes on N uptake involving non-legume biological fixation (Aseri et al. 2008). Therefore, this study was conducted to investigate the efficacy of Mesorhizobium strain Bj to promote root and shoot growth of wheat grown and to optimize nutrients uptake of wheat in soil amended with varied levels of N fertilizers. The results presented in this study support the hypothesis that PGPR can improve the nutrient use efficiency of fertilizers and the wheat growth. The performance of the plants was better in inoculated treatments in comparison to the control (Table 2).
|
Table2. Effect of inoculation with Mesorhizobium strain on fresh biomass and 1000 grain of wheat at different level of N fertilizers in field trial (Average of four replicates)
|
||||
|
Treatments |
Fresh biomass (t ha-1) |
1000 grain weight (g) |
||
|
N (kg ha-1) |
Uninoculated |
Mesorhizobium strain |
Uninoculated |
Mesorhizobium strain |
|
T0 (control) |
5.3 ± 0.58 |
6.9 ± 0.33 |
35.9 ± 1.41 |
40.9±0.70 |
|
25% of N fertilizer |
6.4 ± 0.53* |
8.3 ± 0.15* |
46.3 ± 0.43* |
49.4±2.30* |
|
50% of N fertilizer |
8.8 ± 0.23* |
12.5 ±0.44* |
48.7 ± 1.65* |
52.9±0.92* |
|
75% of N fertilizer |
12.7± 0.92* |
13.8 ±0.14* |
50.7 ± 0.44* |
54.8±0.71* |
|
100% of N fertilizer |
13.5± 0.28* |
14.6 ±0.06* |
55.1 ± 0.97* |
55.0±0.42* |
|
*Significantly different from the control at P < 0.05 |
||||
However, the efficiency of the inoculation decreased with increasing fertilizers doses (Table2). Under unfertlized conditions, Mesorhizobium strain was relatively more efficient, as it increased biomass by 25% over respective uninoculated control. Under fertilized conditions, Mesorhizobium strain was relatively effective as it caused 23%, 30%, 8% and 8 % increase in biomass over respective uninoculated controls in the presence of 25%, 50%, 75% and 100% of fertilizer doses, respectively. When the percentage of recommended fertilizer was reduced and inoculants were used, plant height, shoot dry weight, root dry weight, yield, and nutrient uptake were comparable to those with the full rate of fertilizer without inoculants (Table 2, 3 and 4). Results also show that 100% fertilizer produced plant growth that was greater than all other lower rates if inoculants were not added (Table 2). This agrees with Biswas et al. (2000)] who suggested an interdependence of fertilizer N inputs and inoculants for optimal gain in rice productivity.Furthermore, the PGPR used in this study possess ACC deaminase activity, auxins production, phosphorus solubilization and antifungal activity. Importantly, auxin production and ACC deaminase activity of rhizobacteria are considered as one of the main plant growth-promoting attributes (Belimov et al. 2009; Pilet and Saugy 1987). Lowering of ethylene (Saleem et al. 2007) levels in plants through the synthesis of the enzyme 1-amino-cyclopropane1-carboxylate (ACC) deaminase that hydrolyzes the ethylene precursor ACC is another well-reported mechanism for growth promotion by PGPR (Glick et al. 2007; Shaharoona et al. 2007).On the other hand, after testing different reduced fertilizer rates, under these experimental conditions, 75% fertilizer was the stable minimum to which fertilizer could be reduced if supplemented with PGPR to achieve growth equivalent to 100% fertilizer without PGPR. Results also show that 100% fertilizer produced plant growth that was greater than all other lower rates if inoculants were not added (Table 2). Similarly, 1000 grain weight was significantly increased in response to inoculation with Mesorhizobium strain, but with decreased efficacy at increasing fertilizer doses (Table 2). Under unfertilized conditions, once again, Mesorhizobium strain performed better and caused 23% increase in one thousand kernels weight over respective uninoculated control.Grain yield was also significantly increased in response to inoculation with both the Mesorhizobium strain caused maximum increase in grain yield (25%) over respective uninoculated control (Table 3). Concerning, the concentration of macronutrients in wheat grain which presented in Table 4, data showed that inoculation with Mesorhizobium strain caused significant increase in the concentration of N, P and K elements as compared with the control plant. These findings are in agreement with those of Shaharoona et al (2008) who found that pre-inoculation with Pseudomonas led to significant improve in growth, yield and nutrient uptake of wheat, although the efficacy of these strains for improving growth and yield of wheat reduced with the increasing rates of NPK added to the soil. Under nutrient-deficient conditions, an efficient root system is particularly very critical for sustaining overall plant growth. Therefore, increased root growth in response to inoculation proved more beneficial for improving growth and yield of plants under low-nutrient conditions than the effectiveness of inoculation under nutrient rich matrices. Many researchers have reported that inoculation with rhizobacteria-containing ACC-deaminase decreased the negative impact of stresses-induced ethylene (Burd et al. 1998; Mayak et al. 2004a; Grichko and Glick 2001; Saleem et al. 2007). Previously, we have also reported that inoculation with Mesorhizobium containing ACC-deaminase promoted growth and yield of chickpea (Hemissi et al. 2013; 2015). Results of this study revealed that Mesorhizobium strain were effective in increasing biomass, one thousand grain weight and grain yield in field trial, but their efficacy decreased with increasing levels of N. Moreover, the results of this study imply that excessive use of expensive chemical fertilizer could be avoided to a significant extent without compromising the crop yields by employing these Mesorhizobium strain. Additionally, the use of PGPR with lower fertilizer application is also an environment-friendly strategy. Although inoculation was effective at all the N fertilizer levels, its positive impact decreased with increasing rates of fertilizer application. It could be concluded that PGPR technology should be employed with appropriate doses of fertilizers to get maximum benefit in terms of fertilizer savings and better growth.
|
Table3. Effect of inoculation with Mesorhizobium strain on grain yield of wheat at different level of N fertilizers in field trial (Average of four replicates) |
||
|
Treatments |
Grain yield (t ha-1) |
|
|
N (kg ha-1) |
Uninoculated |
Mesorhizobium strain |
|
T0 (control) |
2.3 ± 0.58 |
3.1 ± 0.33 |
|
25% N fertilizer |
2.8 ± 0.53 |
3.8 ± 0.15 |
|
50% N fertilizer |
3.5 ± 0.23* |
5.5 ±0.44* |
|
75% N fertilizer |
4.7± 0.92* |
5.7±0.14* |
|
100% N fertilizer |
5.5± 0.28* |
5.8±0.06* |
|
*Significantly different from the control at P <0.05 |
||
|
Table 4. Effect of inoculation with Mesorhizobium strain on macronutrient concentration (%) ingrain of wheat plant at different level of N fertilizers in field trial (Average of four replicates)
|
||||||
|
9
|
N (%) |
P (%) |
K (%) |
|||
|
N (kg ha-1) |
Uninoculated |
Mesorhizobium strain |
Uninoculated |
Mesorhizobium strain |
Uninoculated |
Mesorhizobium strain |
|
T0 (control) |
1.32
|
1.52 |
0.032 |
0.041 |
0.055 |
0.068 |
|
25% N |
1.62 |
1.67 |
0.049 |
0.059* |
0.063 |
0.071 |
|
50% N |
1.71 |
1.82* |
0.041 |
0.064* |
0.067* |
0.078* |
|
75% N |
2.01 |
2.30* |
0.051* |
0.065* |
0.074* |
0.089* |
|
100% N |
2.41 |
2.88* |
0.055* |
0.069* |
0.073* |
0.092* |
|
*Significantly different from the control at P <0.05 |
||||||
4. Conclusion
Our results showed that pre-inoculation with Mesorhizobiu m strain Bj led to significant improve in growth, yield and nutrient uptake of wheat. The productive efficiency of a specific PGPR may be further enhanced with the optimization and acclimatization according to the prevailing soil conditions. In future, they are expected to replace the chemical fertilizers and artificial growth regulators which have numerous side-effects to sustainable agriculture. Further research and understanding of mechanisms of PGPR mediated-phyto-stimulation would pave the way to find out more competent rhizobacterial strains which may work under diverse agro-ecological conditions
Acknowledgements
This work was financially supported by the ministry of agriculture and the ministry of higher education and scientific research in Tunisia.
5. References
Araus L, Villegas D, Aparicio F, García del Moral S, El Hani S, Rharrabti Y (2003) Environmental factors determining carbon isotope discrimination and yield in durum wheat under Mediterranean conditions. Crop Sci10 (43): 170–180
Aseri K, Jain N, Panwar J, Rao AV, Meghwal PR(2008) Biofertilizers improve plant growth, fruit yield, nutrition, metabolism and rhizosphere enzyme activities of Pomegranate (Punicagranatum L.) in Indian Thar Desert. Sci Hortic (117): 130–135
Asif M, EudesF, Harpinder R, Amundsen E, Yanke J, Spaner D (2013)Cefotaxime prevents microbial contamination and improves microspore embryogenesis in wheat and triticale. Plant cell Reports (32): 1637-1646
Arregui M and Quemada M (2008)Strategies to Improve Nitrogen Use Efficiency in Winter Cereal Crops under Rainfed Conditions. Agronomy Journal (100): 277-284
Ayadi S, KarmousC, Hammami Z, TamaniN, TrifaY, EspositoS and Rezgui S (2012) Genetic variability of Nitrogen Use Efficiency components in Tunisian improved genotypes and landraces of durum wheat. Agricultural Science Research Journals 2 (11): 591-601
BakkerM, PieterseJ and van L (2007) Induced systemic resistance by fluorescent Pseudomonas spp. Phytopathology (97) : 239–243
Bakker P, Raaijmakers JM, Bloemberg GV, Hofte M, Lemanceau P, Cooke M (2007) New perspectives and approaches in plant growth-promoting rhizobacteria research. Eur J Plant Pathol 119:241–242
Belimov A, DoddC, Hontzeas N, Theobald C, Safronova I and Davies J (2009) Rhizosphere bacteria containing 1-aminocyclopropane-1-carboxylate deaminase increase yield of plants grown in drying soil via both local and systemic hormone signalling. New Phytologist (181) : 413–423
Biswas C, Ladha J and Dazzo B (2000) Rhizobia Inoculation Improves Nutrient Uptake and Growth of Lowland Rice.Soil Science Society of America Journal Abstract.64 (5): 1644-165
Braidwood, L. & Braidwood, R.J. (1969), ‘Current Thoughts on the Beginnings of Food Production in South-western Asia’, Mélanges Université St-Joseph, 45(48):149–155.
Blum A, Pnuel Y (1990) Physiological attributes associated with drought resistance of wheat cultivars in a Mediterranean environment. Australian Journal of Agricultural Research 41(5): 799 - 810
Burd I, Dixon G, Glick A (1998) Plant growth promoting bacterium that decreases nickel toxicity in plant seedlings. Appl Environ Microbiol (164) : 36-53
Bakker P, RaaijmakersM, Bloemberg GV, Hofte M, Lemanceau P, Cooke M (2007) New perspectives and approaches in plant growth-promoting rhizobacteria research. Eur J Plant Pathol (119):241–242
Biswas JC, Ladha JK, Dazzo FB (2000) Rhizobia inoculation improves nutrient uptake and growth of lowland rice. Soil SciSocAm J 64:1644–1650.
Choudhary HK. 2011. DH breeding and chromosome engineering innovations and implications in crop improvement. Proceeding of the National seminaron contemporary approchers to crop improvement, USA.Bangalore 34-35
Denčić S, Mladenov N, Kobiljski B (2011) Effects of genotype and environment on breadmaking quality in wheat. International Journal of Plant Production, 5 (1): 71–82
García-Fraile P, Menendez E, Rivas R (2015) Role of bacterial biofertilizers in agriculture and forestry. AIMS Bioeng. (2) :183–205.
Garcı´a del Moral, L.F., Rhrarrabti, Y., Villegas, D., Royo, C., (2003).
Evaluation of grain yield and its components in durum wheat under Mediterranean conditions: an ontogenic approach. Agron. J. 95, 266–274.
Glick BR (1995) The enhancement of plant growth by free-living bacteria. Can J Microbiol (41) 109-117
Glick BR, Cheng Z, Czarny J, Duan J (2007) Promotion of plant growth by ACC deaminase-producing soil bacteria. Eur J Plant Pathol (119):329–339
Grichko VP and Glick BR (2001) Amelioration of flooding stress by ACC-deaminase containing plant growth promoting bacteria.Plant Physiol Biochem (39): 11-17
Gyaneshwar P, Kumar G N, Parekh L J and Poole P S (2002) Role of soil microorganisms in improving P nutrition of plants. Plant Soil (245):83-93
Glick BR, Todorovic B, Czarny J, Cheng Z, Duan J, McConkey B(2007). Promotion of plant growth by bacterial ACC deaminase.Crit Rev Plant Sci 26:227–242.
Gupta G, Parihar SS, Ahirwar NK, Smehi SK, Singh V (2015). Plant growth Promoting Rhizobacteria (PGPR). Current and Future Prospects for development of sustainable Agriculture. J Microb Biochem Technol 7: 96-102.
Sharma SB, Sayyed RZ, Trivedi MH, Gobi TA (2013). Phosphate solubilizing microbes: sustainable approach for managing phosphorus deficiency in agricultural soils. Springerplus.2: 287.
Hemissi I, Mabrouk Y, Mejri S, Saidi M and Sifi B(2011). Rhizobium-induced defense responses in chickpea plants against Rhizoctoniasolani. Journal of phhytopathology (161):412-418.
Hemissi I, Mabrouk Y, Abdi N, Saidi M and Sifi B (2013). The potential of Rhizobium strains for biological control of Orobanche foetida. African.Jour Biotech 12 (12): 1371-1377.
Hmissi I, Abdi N, Bargaz A, Bouraoui M, Mabrouk Y, Saidi M, and Sifi B (2015) Inoculation with phosphate solubilizing mesorhizobium strains improves the performance of chickpea (cicerariteniuml.) under phosphorus deficiency. J P Nut, (38):1656–1671
Hall AM (Ed.) (1996) The Quaternary of Orkney. Quat. Res. Assoc, Cambridge
Huang S, Zhao C, Zhang Y and Wang C (2018). Nitrogen Use Efficiency in rice. Chapter from the book “Nitrogen in Agriculture”. 187-208.
Kohler J, Herna´ndez JA, Caravaca, F, Rolda´na A(2009) Induction of antioxidant enzymes is involved in the greater effectiveness of a PGPR versus AM fungi with respect to increasing the tolerance of lettuce to severe salt stress. Environ Exp Bot(65) 245–252
Khalid A, Arshad M, Zahir ZA (2004) Screening plant growth-promoting rhizobacteria for improving growth and yield of wheat. J Appl Microbiol (96):473–480
Karlidag H, Esitken A, Turan M, Sahin F (2007) Effects of root inoculation of plant growth promoting rhizobacteria (PGPR) on yield, growth and nutrient element contents of leaves of apple. Sci Hortic (114):16–20
Lucy M, Reed E and Glick BR (2004) Applications of free living plant growth-promoting rhizobacteria. Antonie van Leeuwenhoek (86): 1-25.
Mandic V, Krnjaja V, Tomic Z, Bijelic Z, Simic A, Muslic D.R, Gogic M. (2015) Nitrogen fertilizer influence on wheat yield and use efficiency under environmental conditions Chilean. Journal of Agricultural Research 75 (1): 92-97.
Mayak S, Tirosh T, Glick BR, (2004) Plant growth-promoting bacteria confer resistance in tomato plants to salt stress. Plant Physiol Biochem (42) 565–572.
Pilet PE, Saugy M (1987) Effect on root growth of endogenous and applied IAA and ABA. A critical reexamination. Plant Physiol 83: 33–38
Ryan J, Estefan G, and Rashid A (2001) Soil and Plant Analysis: Laboratory Manual, pp. 172. ICARDA, Aleppo. Syria
Savci S (2012) An agricultural pollutant: Chemical fertilizer. International Journal of Environmental Science and Development (3):77–80.
Saleem M, Arshad M, Hussain S and Bhatti A S (2007) Perspective of plant growth promoting rhizobacteria (PGPR) containing ACC deaminase in stress agriculture.J Ind Microbiol Biotechnol (34): 635-648
Shaharoona B, Jamro GM, Zahir ZA, Arshad M, Memon KS (2007) Effectiveness of various Pseudomonas spp. and Burkholderia caryophylli containing ACC-deaminase for improving growth and yield of wheat (Triticum aestivum L.). J Microbiol Biotechnol (17):1300–1307
Shaharoona, B., Naveed M, Arshad M, Zahir A (2008) Fertilizer-dependent efficiency of Pseudomonads for improving growth, yield, and nutrient use efficiency of wheat (Triticumaestivum L.). Applied Microbiology and Biotechnology 79: 147–155.
Sun Bo ,Zhang L , Yang L, Zhang F , Norse D, Zhu Z (2012)Agricultural Non-Point Source Pollution in China: Causes and Mitigation Measures.AMBIO (41): 370–379.
Turan M, Ataoglu N, Sahin F (2006). Evaluation of the capacity of phosphate solubilizing bacteria and fungi on different forms of phosphorus in liquid culture. J. sustain Agric (28):99-108
Violeta M, Vesna K, Zorica T, Zorica B, Aleksandar S, Dragana R M, and Marija G (2015) Nitrogen fertilizer influence on wheat yield and use efficiency under different environmental conditions. Chilean Journal of agricultural research.75.
Yu T, Meng W, Edwin O, Li Z, and Chen J (2010) Long-term variations and causal factors in nitrogen and phosphorus transport in the Yellow River, China. Estuarine, Coastal and Shelf Science (86): 345–351.
Yuan XY (2000). Primary appraisal of pollution for lakes of China. Volcanology and Mineral Resources (21):128–136