The present investigation aimed to quantify the difference in response of two Phaseolus mungo L. cultivars (i.e., UH-1 and IPU-94-1) to Glomus mosseae (G), that is, Funneliformis mosseae, Acaulospora laevis (A), and Trichoderma viride (T), in different combinations or alone. All the treatments were inoculated with Bradyrhizobium japonicum to ensure nodulation as soil used in the experiment was sterilized. After 120 days of inoculation, plants were analyzed for chlorophyll content, nodulation, mycorrhization, leaf area, and protein content. Results indicate variation in growth response of two cultivars with different treatments. Triple inoculation of plants with G + A + T proved to be the best treatment for growth followed by G + T in both cultivars. Our work allowed the selection of P. mungo L. cultivar UH-1 as highly mycorrhizal responsive as compared to IPU-94-1 and G. mosseae to be an efficient bioinoculant as compared to A. laevis for growth enhancement of P. mungo. Further characterization of P. mungo genotypes will enhance our knowledge of physiological and genetic mechanism behind increase in plant growth and yield due to AM symbiosis.
1. Introduction
Grain legumes are a vital source of protein-rich edible seeds, comprising the chief source of dietary protein for majority of population in developing countries. India is an agriculture dominated nation where a variety of legumes are grown. Phaseolus mungo L. an important legume crop is one of the heavily priced pulses of India. More than two-thirds of the world’s total production of P. mungo is contributed by India, which is largest in the world [1]. The legume is highly nutritional with about 60% carbohydrates, 24% proteins, and 1.3% fats. In addition to this, the legume has fair amount of minerals like calcium, phosphorus, potassium, and vitamins A, B, and C [2, 3]. Due to high nutritional qualities, this pulse is an ideal crop for achieving developmental goals of reducing poverty and hunger, improving human health and nutrition, and increasing ecosystem flexibility. In agricultural systems, the legumes are important rotation crops which help in supplying nitrogen to the cereal crop and reducing soil pathogens. In India, multiple crops are grown by farmers in a single growing season in order to fetch good profits. As a result of this, withdrawal of nutrients by the plants occurs faster than they are replenished. Soil becomes nutrient depleted which needs to be supplemented with chemical fertilizers but the extensive use of chemical fertilizers and indiscriminate use of pesticides in modern agriculture have resulted in disruption and degradation of agroecosystems. In order to secure environmental quality as well as healthy food demands of future, sustainable productivity of both agricultural and natural soil-plant systems is essential.
A variety of interactions occur among soil microbes and plants in the heterogeneous rhizosphere. Among these, it is predominantly the symbiotic interaction of arbuscular mycorrhizal fungi (AMF) with the roots of plants which determines soil fertility and plant health. The AM fungi amend the root architecture of host plant by enhancing lateral root formation [4]. The extra radical hyphal (ERH) network of fungus increases the volume of soil explored, resulting in increased water and nutrient uptake [5]. The fungi also produce glomalin protein helping in formation of stable soil aggregates, resulting in improvement of soil structure. Role of AMF in mineral nutrition has recently been reviewed by Azcón-Aguilar and Barea [6]. Nearly 80% of the plant phosphorus (P) and nitrogen (N) are now admitted to be provided by mycorrhizal fungi [7]. The effect of AMF on the growth enhancement of some legumes has been confirmed by Hassan and Abakeer [8] as well as by Ndoye et al. [9]. In addition to AMF, the role of Trichoderma species as phytostimulators and biocontrol agents in agricultural and horticultural systems has also been investigated [10, 11]. The exploitation of biocontrol agents requires consideration as they facilitate root colonization by AM fungi [12]. So keeping in mind the concept of sustainability and to enhance the productivity, the present investigation was aimed to find out the effect of different biofertilizers alone and in different combinations on growth enhancement of two cultivars of P. mungo.
2. Materials and Methods2.1. Mass Multiplication of Bioinoculants
In this study, the two dominant AM species Glomus mosseae (i.e., Funneliformis mosseae) and Acaulospora laevis were used. These species were isolated from the rhizospheric soil of P. mungo grown in botanical garden of Botany Department, Kurukshetra University, Kurukshetra. The AM species were propagated in association with maize as host under standard pot culture conditions after preparation of starter inoculum of each species by “Funnel Technique” of Menge and Timmer [13]. Trichoderma viride was mass multiplied on a modified wheat bran-saw dust medium [14], while Bradyrhizobium japonicum culture (procured from Department of Microbiology, CCS Haryana Agricultural University, India) was multiplied by using nutrient broth medium.
2.2. Preparation of Pot Mixture
The experiment was laid out in a randomized complete block design, with five replicates per treatment. Top soil (0–30 cm) consisting of 20.8% silt, 3.78% clay, with pH 8.05, total N, 0.0485%, and available P, 0.015%, was collected from Kurukshetra University, Kurukshetra. This soil was air-dried and sieved. The soil : sand mixture (3 : 1, v/v) autoclaved for 20 minutes at 121°C and 15 psi was used in the experiment. For AM treatment, 10% (w/w of soil) of the selected AM inoculum having 870–890 AM spores and chopped AM colonized root pieces with an infection level of 94% was added. Trichoderma viride inoculum with density 3.4×108 cfu gm−1 was added per the treatment.
Seeds of two varieties of P. mungo, namely, IPU-94-1 and UH-1, were acquired from Haryana Agriculture University Hisar, Haryana, India. Seeds were surface-sterilized with 10% solution of sodium hypochlorite for 1-2 minutes and then rinsed thoroughly with distilled water. Before the seeds were sown, 10 mL of a liquid suspension of bacteria with a density 108 cells/mL was applied to each pot to ensure nodulation as the soil used in experiment was sterilized. Nutrient solution [15] which contained half the recommended level of phosphorus without nitrogen was used to fertilize the pots after 15 days and plants were watered once every two days. Pots were treated either with single inoculum, combined inoculum, or no inoculums as summarized in the following:
Uninoculated, that is, autoclaved sterile sand : soil with no inoculum (control).
G. mosseae (G).
A. laevis (A).
Trichoderma viride (T).
G + A.
G + T.
A + T.
G + A + T.
2.3. Plant Harvest and Analysis
After 120 days, plants were harvested and some physiological parameters were analyzed. Chlorophyll content was estimated using the method of Arnon [16]. Leaf proteins were estimated according to Bradford method [17]. The number of nodules per plant and yield in terms of number of pods and weight of pods per plant was recorded. Leaf area was assessed by using leaf area meter (Systronics 21, Ahmedabad, India).
2.4. Identification and Quantification of the Number and Colonization by AM Spores
Isolation of AM spores was done by using “wet sieving and decanting technique” of Gerdemann and Nicolson [18]. Identification of AM spores (G. mosseae and A. laevis) was done by using the identification manual used by Walker [19], Schenck and Perez [20], Morton and Benny [21], and Mukerji [22]. Quantification of the number of AM spores was done using “Grid Line Intersect Method” of Adholeya and Gaur [23]. “Rapid Clearing and Staining Method” of Phillips and Hayman [24] was used to determine mycorrhizal root colonization. Percent AM colonization of roots was calculated as number of root segments colonized/number of root segments studied × 100.
2.5. Statistical Analysis
Data were subjected to analysis of variance and means separated using the least significant difference test in the Statistical Package for Social Sciences (ver. 11.5, Chicago, IL, USA).
3. Results
Inoculation of P. mungo plants with mycorrhizal fungi and Trichoderma significantly increased chlorophyll content, leaf proteins, leaf area, nodulation, and mycorrhization in both varieties (UH-1 and IPU-94-1) over control (Tables 1(a), 1(b), 2(a), and 2(b)).
(a) Interactive effect of AM fungi and T. viride on chlorophyll content and nodulation of Phaseolus mungo var. UH-1 after 120 days of inoculation. (b) Interactive effect of AM fungi and T. viride on chlorophyll content and nodulation of Phaseolus mungo var. IPU-94-1 after 120 days of inoculation.
S. number
Parameters→Treatments↓
Chlorophyll content (mg g−1 FM)
Number of nodules (per plant)
Chlorophyll a
Chlorophyll b
Total chlorophyll
(1)
Control
0.967 ± 0.004h
0.308 ± 0.006h
1.227 ± 0.004h
09.00 ± 2.73f
(2)
G
2.091 ± 0.003d
0.727 ± 0.007d
2.818 ± 0.005d
20.20 ± 2.38cd
(3)
A
1.607 ± 0.002f
0.554 ± 0.006f
2.162 ± 0.005f
15.20 ± 2.86ef
(4)
T
1.220 ± 0.003g
0.436 ± 0.006g
1.656 ± 0.008g
12.00 ± 2.54f
(5)
GA
2.435 ± 0.002c
0.755 ± 0.004c
3.091 ± 0.004c
22.60 ± 3.04bc
(6)
GT
2.675 ± 0.002a
1.148 ± 0.003a
3.824 ± 0.005a
25.80 ± 2.38ab
(7)
AT
1.822 ± 0.006e
0.632 ± 0.004e
2.455 ± 0.008e
17.40 ± 2.70de
(8)
GAT
2.564 ± 0.002b
1.104 ± 0.005b
3.667 ± 0.009b
29.20 ± 3.70a
LSD (P≤0.05)
0.0061
0.0092
0.0121
4.82
ANNOVA F(7,16)
124.121
125.941
659.041
22.294
S. number
Parameters→Treatments↓
Chlorophyll content (mg g−1 FM)
Number of nodules (per plant)
Chlorophyll a
Chlorophyll b
Total chlorophyll
(1)
Control
0.957 ± 0.003g
0.292 ± 0.006h
1.256 ± 0.014h
03.8 ± 2.863e
(2)
G
1.963 ± 0.004c
0.753 ± 0.005c
2.716 ± 0.010d
15.0 ± 4.123cd
(3)
A
1.475 ± 0.008e
0.575 ± 0.006e
2.050 ± 0.013f
12.0 ± 2.540d
(4)
T
1.082 ± 0.004f
0.429 ± 0.006g
1.511 ± 0.003g
06.8 ± 2.387e
(5)
GA
2.286 ± 0.004b
0.609 ± 0.006d
2.896 ± 0.002c
17.8 ± 2.387bc
(6)
GT
2.552 ± 0.137a
0.895 ± 0.035b
3.449 ± 0.101b
21.2 ± 3.033ab
(7)
AT
1.634 ± 0.004d
0.497 ± 0.004f
2.131 ± 0.008e
16.2 ± 2.387c
(8)
GAT
2.559 ± 0.152a
0.987 ± 0.036a
3.546 ± 0.116a
24.8 ± 2.387a
LSD (P≤0.05)
0.0938
0.0243
0.0713
3.6352
ANNOVA F(7,16)
372.350
779.971
1.173
30.924
G: Glomus mosseae; A: Acaulospora laevis; T: Trichoderma viride; ±: each value is a mean of five replicates; FW: fresh weight; FM: fresh matter; ±: standard deviation; AM: arbuscular mycorrhizae; values in columns followed by same letter are not significantly different (P≤0.05), least significant difference test.
(a) Interactive effect of AM fungi and T. viride on protein content, leaf area, and mycorrhization in Phaseolus mungo var. UH-1 after 120 days of inoculation. (b) Interactive effect of AM fungi and T. viride on protein content, leaf area, and mycorrhization of Phaseolus mungo var. IPU-94-1 after 120 days of inoculation.
S. number
Parameters→Treatments↓
Protein content (mg g−1 FW)
Leaf area (cm2)
AM spore number/10 g of soil
AM root colonization (%)
(1)
C
0.221 ± 0.017f
07.52 ± 1.733h
07.0 ± 2.23f
00.6 ± 0.29g
(2)
G
0.461 ± 0.017c
25.55 ± 2.037d
87.0 ± 3.16b
74.6 ± 4.15c
(3)
A
0.382 ± 0.019e
18.65 ± 2.095f
67.6 ± 3.64d
55.6 ± 4.39e
(4)
T
0.359 ± 0.022e
14.50 ± 1.818g
57.0 ± 3.16e
42.6 ± 3.36f
(5)
GA
0.475 ± 0.019c
29.27 ± 2.104c
86.2 ± 3.34b
80.4 ± 4.92b
(6)
GT
0.584 ± 0.028a
35.27 ± 2.182b
90.2 ± 4.43ab
84.0 ± 4.52ab
(7)
AT
0.422 ± 0.018d
22.38 ± 1.863e
74.6 ± 3.64c
64.8 ± 3.70d
(8)
GAT
0.519 ± 0.020b
40.24 ± 2.231a
94.8 ± 3.49a
89.4 ± 3.84a
LSD (P≤0.05)
0.0358
3.5949
6.03635
5.2888
ANNOVA F(7,16)
89.472
102.206
172.752
149.816
S. number
Parameters→Treatments↓
Protein content (mg g−1 FW)
Leaf area (cm2)
AM spore number/10 g of soil
AM root colonization (%)
(1)
C
0.187 ± 0.003h
05.88 ± 1.891g
00.00 ± 0.00g
00.00 ± 0.00f
(2)
G
0.435 ± 0.003d
35.50 ± 2.266a
81.40 ± 4.92c
72.40 ± 3.64b
(3)
A
0.365 ± 0.003f
15.22 ± 1.983e
57.80 ± 3.96e
45.80 ± 3.70d
(4)
T
0.360 ± 0.003g
10.60 ± 1.617f
49.20 ± 3.49f
30.80 ± 5.31e
(5)
GA
0.456 ± 0.002c
21.04 ± 1.939d
88.60 ± 4.15b
77.00 ± 3.67ab
(6)
GT
0.506 ± 0.002a
25.90 ± 2.003c
92.00 ± 3.80b
78.00 ± 5.91a
(7)
AT
0.402 ± 0.002e
19.24 ± 1.553d
66.20 ± 4.20d
58.60 ± 3.64c
(8)
GAT
0.485 ± 0.002b
30.27 ± 2.248b
96.80 ± 2.16a
82.00 ± 3.53a
LSD (P≤0.05)
0.0037
2.5158
4.698
5.183
ANNOVA F(7,16)
6.155
129.458
380.026
253.739
G: Glomus mosseae; A: Acaulospora laevis; T: Trichoderma viride; ±: each value is a mean of five replicates; FW: fresh weight; FM: fresh matter; ±: standard deviation; AM: arbuscular mycorrhizae; values in columns followed by same letter are not significantly different (P≤0.05), least significant difference test.
In variety UH-1, maximum protein content and chlorophyll content were recorded in the plants dually inoculated with G. mosseae + T. viride followed by triple inoculation of G + A + T (Table 1(a)). The mycorrhizal colonization of roots and number of AM spores recorded for the treated plants were also different (Table 2(a)). Maximum nodulation, leaf area, and number of spores and percentage colonization of roots were recorded for plants treated with G. mosseae + A. laevis and T. viride pursued by dual inoculation of G. mosseae and T. viride.
In variety IPU-94-1, the inoculation of plants with G. mosseae + A. laevis and T. viride induced maximum increase in chlorophyll content, mycorrhization (AM spore number and % root colonization), nodulation, and leaf area, while the dual combination of G. mosseae + T. viride increased protein content in leaves. Among the different dual inoculation treatments, the combination G + T performed best for all the parameters studied. Among the different treatments used, Trichoderma was found to be least effective (Tables 1(b) and 2(b)). The combined effect of the bioinoculants resulted in highest mycorrhization in the plants than single strain. G. mosseae alone or in combination with T. viride proved to be a compatible strain for growth enhancement of pulse legume as compared to A. laevis.
4. Discussion
The ability of AMF to improve growth of plants by increasing nutrient uptake and water absorption makes them especially important for sustainable farming systems. In the present study, a positive interaction was observed between the AM fungi and T. viride for growth improvement because of stimulatory role of the latter in mycorrhization. Our results confirm the findings of Shuab et al. [25] and Bagheri et al. [26], who also observed an improvement in growth of the plants treated with microbes. High concentration of photosynthetic pigments in the leaves of mycorrhizal plants is attributable to increased uptake of magnesium and phosphorus, increased transpiration, stomatal conductance, and carbon assimilation [27, 28]. High concentration of photosynthetic pigments results from higher nutritional uptake by plants and thus increased energy [29]. Another reason could be AM mediated increase in number and size of chloroplasts as reported by Arumugam et al. [28] and Krishna and Bagyaraj [30]. Mycorrhizal infection increases nitrogen and phosphorus content in the plants [6, 31] which contributes to increased protein synthesis. The higher shoot protein content observed in AMF treated plants may be due to stimulation of protein synthesis in host after infection [32]. Similar observations have been made by Mathur and Vyas [33], Sandhya et al. [34], and Lenin et al. [35]. The plants treated with AM fungi had higher nodulation than non-AM plants. It may be due to the ability of AMF to supply adequate amount of P required for nitrogen fixation by Rhizobia. Role of AM fungi in improving nodulation has been reviewed by Azcón-Aguilar and Barea [36]. Inoculation with biofertilizers caused leaf enlargement and improved total plant morphology. Our results are in agreement with the findings of Amerian and Stewart [37] and Lenin et al. [35].
5. Conclusion
The use of microbes improved physiological and morphological status of the plants; thus they could be used to economically replace the expensive chemical fertilizers. A combination of G. mosseae, A. laevis, and T. viride can be used for sustainable growth improvement of P. mungo. However, the field trails for testing the efficacy of bioinoculants are still to be performed so as to understand the plant establishment and development under these conditions. Results indicate variation in growth of the two cultivars with different treatments of bioinoculants. Our work allowed the selection of P. mungo L. cultivar UH-1 as highly mycorrhizal responsive as compared to IPU-94-1.
Competing Interests
The authors declare that they have no competing interests.
Acknowledgments
The authors are thankful to Kurukshetra University, Kurukshetra, for providing laboratory and infrastructural facilities to carry out the research work.
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