Index

Abstract

The present study was intended to investigate individual and interactive effects of Funneliformis mosseae (an arbuscular mycorrhizal fungus) and Rhizobium (a root nodulating bacterium) on growth and yield of groundnut growing under natural conditions. Plants growing in arbuscular mycorrhiza (AM) and/or Rhizobium inoculated soil exhibited superior growth, fitness and yield. Improvement in plant growth due to microbial inoculations had a significant correlation with their response to mycorrhization, relative water content, chlorophyll content, nutrient uptake, and antioxidant activity. The increase in all parameters except N acquisition and protein concentration was significantly higher on the formation of AM than rhizobial inoculation, albeit their combination displayed synergism to uplift metabolism and yield of host legume. Thus, the study indicated that synergistic behavior among microorganisms (AM and Rhizobium) had the most affirmative effects on the growth and harvest index of groundnut variety - TG37A and helped plants to thrive better in soils without chemical fertilizers.

Keywords: Arachis hypogaea L, Bradyrhizobium Funneliformis mosseae, Growth, Nodulation, Yield.

Received: 26 May 2020 / Revised: 29 June 2020 / Accepted: 4 August 2020/ Published: 31 August 2020

Contribution/ Originality

This study contributes to the existing literature of tolerance aptitude of groundnut variety - TG37A against existing adverse environment.  This study also documents the importance of AM and Rhizobium in improving the growth and metabolism of this variety.

1. INTRODUCTION

Arachishypogaea, an annual oil yielding plant of Fabaceae family, is one of the most important cultivated food legume (rank second) and edible oilseed crop (rank fourth) in world (Yol, Furat, Upadhyaya, & Uzun, 2018). However, biotic diseases and extremes of abiotic factors like temperature, drought, and soil salinity in semi-arid tropics are the severe limitations affecting both groundnut yield and excellence. In addition, impending climate change, poor agronomic practices, and inadequate inputs have further accentuated these harmful impacts (Krishna, Singh, Kim, Morya, & Ramteke, 2015; Sharma & Bhatnagar-Mathur, 2006; Thangella, Pasumarti, Pullakhandam, Geereddy, & Daggu, 2018) . Nevertheless, ever-increasing consumer stipulation and the desire to amplify worldwide export of groundnut, necessitate the investigation to improve yield of groundnut cultivars. Chemical fertilizers have mammalian toxicity, phytotoxic nature and are ineffective against abiotic constraints thereby not desirable (Sathiyabama & Balasubramanian, 2018). In view of these limitations in conventional technique, the fundamental paradigm for cost-effective and environmentally sound technology is to utilize beneficial representatives of microbiome in such a way as to improve crop health and productivity (Ruiz-Lozano, Porcel, Azcón, & Aroca, 2012).

Out of the most prevalent rhizospheric mutualisms, the arbuscular mycorrhiza (AM) and the Rhizobium-legume (RL) symbioses, have particular importance as ‘natural mini-fertilizer factories’ (Van der Putten, Klironomos, & Wardle, 2007). Both communications are totally different in terms of their host specificity, as Legume-Rhizobium symbiosis is very specific, permitting only particular strains of rhizobia to nodulate with accurate host legumes, while there is very little host specificity in mycorrhizal symbiosis formation and thus AM fungi (AMF) are considered as ubiquitous soil microorganisms (Gibson, Kobayashi, & Walker, 2008; Smith & Read, 2008). The RL symbiosis is a stupendous biological interface accountable for fixing a large quantity of nitrogen in terrestrial ecosystems, (Clúa, Roda, Zanetti, & Blanco, 2018). This root nodule symbiosis, require less fossil-based energy (~35–60 per cent lesser) than conventional N-fertilized crops (Jensen et al., 2012). The extensive mycelial structures (hyphae, arbuscules, vesicles, and spores) effectively explore soil substrates and obtain soil inorganic macro-nutrients nitrogen (N), phosphorus (P) and potassium (K) and micro-nutrients like copper (Cu), iron (Fe) and zinc (Zn) with some ability for acquiring organic N and P (Miransari, 2011; Parniske, 2008). Physiological benefit of both symbioses is not restricted to uptake and transfer of nutrients to the host (Evelin, Giri, & Kapoor, 2012) rather they also construct a buffer zone for host to resist biotic and abiotic stress (Lucas, García-Cristobal, Bonilla, Ramos, & Gutierrez-Manero, 2014); improve rhizospheric soil aggregation (Singh, 2012); improve host’s water absorption competence by improving root hydraulic conductivity (Aroca, Porcel, & Ruiz‐Lozano, 2007) produce antioxidant molecules (Patel & Saraf, 2013) improve host   photosynthetic carbon fixation (Hajiboland, Aliasgharzadeh, Laiegh, & Poschenrieder, 2010) and preserve membrane structure and phytohormones synthesis (Chandrasekaran, Boughattas, Hu, Oh, & Sa, 2014)suppress pathogenic attack (Raupach & Kloepper, 1998) and stimulate systemic resistance (Geng et al., 2018). These mechanism may act in a concerted manner and lead to increased plant growth and subsequently improve productiveness of polluted soils and recuperate agriculture by improving crop’s ability to nurture on nutrient-poor soils(Abdel Latef & Miransari, 2014).

If the incidence of one symbiont boosts resource accessibility in a way that releases the host from restriction or else promotes allotment to another symbiont, then constructive correlations i.e. co-colonization of multiple symbiotic species can be practical (Afkhami, Rudgers, & Stachowicz, 2014). In most of the studies, particularly when both N and P are limiting factors, rhizobia and AM have been reported to perform synergistically and forms an integral tripartite interaction to enhance legume development and reproduction more than either microsymbiont inoculating alone and also mutually enhance each other’s organization (Bauer, Kleczewski, Bever, Clay, & Reynolds, 2012; Gould & Lister, 2005; Xie et al., 1995) . Both symbionts are not only potent competitors for carbon requirements and/or nutrient complementarity, but also share resemblance in the downstream signal transduction pathways (i.e. common SYM genes) as well as hormonal regulation that arbitrate the perseverance and quantity of colonization events reviewed by Mukherjee and Ané (2011); Sakamoto, Ogiwara, and Kaji (2013) signifying the evolutionarily coupling of these two symbioses (Senoo et al., 2000; Takeda, Tsuzuki, Suzaki, Parniske, & Kawaguchi, 2013). Legume - mycorrhizal symbiosis is a vital link for effectual P nutrition, leading to improved N2 fixation that advocate a synergistic tripartite relationship (Sakamoto et al., 2013).

High yielding varieties in agriculture augment production by increasing per acre yield, consequently improving self-sufficiency and decrease dependency on imports. However, cultivation of high-yielding varieties is a chemical-intensive program with substantial requirement of both chemical fertilizers and pesticides (Samal & Rout, 2018). In recent years, more consideration has been given to the use of biofertilizers and their integration, to not only have high plant yields but also to cut the usage of environmentally unfavorable chemical fertilizers (Akhtar, Siddiqui, & Wiemken, 2011). Therefore, it would be of paramount importance to explore how endosymbionts and their mutualistic potential can modulate physiology, metabolism, and ultimately yield of a high-yielding variety of groundnut. Thus, the present study was intended to ascertain the impact of Rhizobium, Funneliformismosseae as well as their interaction on a) growth, b) symbiotic performance, c) nutrient acquisition, d) redox stability in a high-yielding variety of groundnut. We also measured the modulation in yield productivity of this groundnut variety to gain insights into broader aspects of biofertilizers and their integration mediated enhancement in agriculture.

2. EXPERIMENTAL MATERIALS, LAYOUT AND METHODOLOGY

2.1. Environmental Conditions and Experimental Layout

Greenhouse experiments were carried out in the Botanical garden of Department of Botany, SGTB Khalsa College, University of Delhi (28.61°N, 77.23°E and elevation 200 - 250 m), under natural climatic conditions (minimum temp. 22–26 °C and maximum 35–44 °C; relative humidity 28–30 % and 86–100 %, in morning and afternoon respectively). Soil for the experiment was obtained from close by agricultural meadow. The soil physico-chemical properties were determined as sand and loam in 1:1 ratio by volume (with 11.5 mg P kg-1(Olsen & Sommers, 1982) 0.19 meq 100 g-1 available K, 0.21 Na meq 100 g-1, 0.86 Cameq 100 g-1(Mehlich, 1953) 0.44 % total N (Nelson & Sommers, 1973) pH 7.5 (soil:water; 1:1), electrical conductivity (ECe) 0.86 dSm-1, 0.66 % organic carbon (Walkley, 1947). The soil was filled in earthen pots with capacity of 10 kg soil. 2×2 factorial design with two mycorrhizal conditions: with or without fungal inoculum combined with two conditions of Rhizobium inoculation: with or without Rhizobium. Thus, there were four combinations of treatment (each in the multiple of six) set in a completely randomized block design.

2.1.1. Biological Material

Seeds of groundnut cultivar (TG37A: A Spanish groundnut cultivar) were procured from Directorate of Groundnut Research (DGR), Gujrat, India. This cultivar of groundnut (popular among the farmers for large scale cultivation) was released in 2004 by Bhabha Atomic Research Centre, Mumbai. This cultivar is appropriate for both kharif and rabi summer seasons all over India and is tolerant to various biotic factors causing collar rot, rust and late leaf spot.

Groundnut specific Bradyrhizobium culture (TAL1000) was also procured from DGR, Gujrat. It was a charcoal-based rhizobial inoculum that readily forms nodules with groundnut in a variety of soils under various agro-climatic conditions. Non-sterile spores (from monosporal culture) of mycorrhizal isolate Funneliformismosseae (UTMU 128 WM1/11, T.H. Nicolson & Gerd.) C. Walker & A. Schüβler comb. nov.Schüβler and Walker (2010) were acquired from the Centre for Mycorrhizal Culture Collection, The Energy and Resource Institute, India. AM inoculum was bulked by inoculating Zea Mays L., Sorghum bicolor L. and Coriandrum sativum L. in an open-pot soil culture (Dalpé & Monreal, 2004).

2.1.2. Symbiotic Microorganism Inoculation

Healthy looking seeds of equal size were selected and consequently surface sterilized (to avoid microbial infection) using 10% hydrogen peroxide (v/v). The seeds were washed in sterilized distilled water a number of times to wipe out remaining traces of chemical soaked in water and left for overnight for imbibition. Next morning, half of these seeds were inoculated with rhizobial inoculum. Slurry of charcoal-based rhizobial inoculum was prepared and overnight soaked seeds were thoroughly stirred in this slurry. When seeds were properly coated with Bradyrhizobium(R), they were air dried at room temperature. Before sowing, half of the +R (inoculated) and half –R (non inoculated) seeds were also inoculated with 50 g of soil-based fungal inoculum [concoction of soil containing pieces of roughly 65 per cent colonized roots, approximately 23 spores per gram soil, filamentous hyphae], kept at a depth of 1.5 cm below the seed sowing plane, to aid plant root fungal colonization. Non-AM treatments were provided same weight of sterile inoculum with 10ml aliquot of an inoculum filtrate.

2.1.3. Harvesting

Plants were harvested for estimating various parameters at 50 days after sowing (DAS) i.e. vegetative stage and at 110 DAS i.e. at reproductive stage. Six plants of each treatment were harvested for every fresh as well as dry estimation and records calculated on per gram nodules/roots/leaves dry weight basis (full-fledged developed nodules/roots/leaves of one plant were regarded as one biological repeat). Plant materials were dried in oven at 70°C until they reached steady weight. Dried material was powdered and stored for further analyses. Yield parameters were documented daily from the commencement of flowering till seed growth and maturity stage (110 DAS). Pods/seeds number per plant was estimated by taking average of pods/seeds in six replicates per treatment at crop maturation stage. Harvested plant samples were divided into vegetative and reproductive parts and depending on their dry weights, harvest index (HI) was calculated at 110 DAS (Leport, Turner, Davies, & Siddique, 2006) as follows:

2.2. Physiological Estimations

2.2.1. Per Cent AM Colonization

Cleared roots (10 % KOH) were stained with (0.05 %) trypan blue (Phillips & Hayman, 1970) and were microscopically calculated using the magnified grid-line intersection method (Habte & Osorio, 2001; McGonigle, Miller, Evans, Fairchild, & Swan, 1990). Mycorrhizal responsiveness was calculated by following formula (Zhu, Smith, Barritt, & Smith, 2001):

2.2.2. Nodulation and Leghemoglobin (LHb) Protein Pigment 

The nodules were detached immediately after sampling and Bradyrhizobiumsymbiosis was estimated by counting total nodule number per root and by calculating total nodule dry weight per root system. LHb concentration was calculated by the method of Hartree (1957).

2.2.3. Relative Water Content (RWC)

RWC in leaves was estimated (Weatherley, 1950) and calculated as per the following formula:

where, ‘a’ is fresh wt., ‘b’ is dry wt., and ‘c’ is turgid wt. (weights taken after incubation of plant samples in 100 ml of distilled water for 4 h.)

2.2.4. Chlorophyll (A, B, Total) Concentration and Chlorophyll A/B in Leaves

Dimethyl sulphoxide (DMSO) based extraction of chlorophyll (Chl.) in leaves was done by the method of Hiscox and Israelstam (1979). The amount of Chl. was calculated from the extinction values following the equation of Arnon (1949).

2.2.5. Nutrient Uptake

Dried tissue of roots, nodules and shoots were analyzed for their nutrient composition. Concentration of Nitrogen (N) was estimated by using Nessler’s reagent in the colorimetric method of Lindner (1944) and the standard curve was prepared using graded concentrations of (NH4)2SO4. Phosphorus (P) concentration was measured by vanado-molybdophosphoric method of Jackson (1973)by taking absorbance at 420 nm. Appropriate standards of KH2PO4 were run simultaneously and against the calibration curve, P concentration was calculated in mg g-1 D.W. Magnesium (Mg) and Potassium (K+) concentration in acid based digest were measured with atomic absorption spectrophotometry (Allen, Grimshaw, & Rowl, 1984). Blank was run without plant samples and against the calibration curve, concentration was calculated in mg g-1 D.W.

2.2.6. Total Protein Concentration

The total proteins were estimated in fresh roots, nodules and shoots by method ofBradford (1976)where spectrophotometeric O.D. was taken at 595 nm and protein concentration was calculated in mg g-1 F.W.

Table-1. Result of ANOVA for independent variables including rhizobial inoculation (R), arbuscular mycorrhiza (AM) inoculation and interactions among them.

Section I		R			AM			R × AM
		P ≤ 0.05	P ≤ 0.01	P ≤ 0.001	P ≤ 0.05	P ≤ 0.01	P ≤ 0.001	P ≤ 0.05	P ≤0.01	P ≤ 0.001
RDW (75 DAS)		*	**	***	*	**	***	*	**	***
RDW (75 DAS)		*	**	***	*	**	***	*	**	***
RSR (75 DAS)		*	ns	ns	*	ns	ns	*	Ns	Ns
RWC (75 DAS)		*	**	ns	*	**	ns	*	**	Ns
Chl. a		*	**	***	*	**	***	*	**	***
Chl. b		*	**	ns	*	**	ns	*	**	Ns
Chl. a/b		*	ns	ns	*	ns	ns	*	Ns	Ns
Total Chl.		*	**	ns	*	**	*	*	**	Ns
NN (75 DAS)		*	**	***	*	**	ns	*	**	Ns
NDW (75 DAS)		*	**	ns	*	ns	ns	*	Ns	Ns
LHb concentration (75 DAS)		*	**	ns	*	**	ns	*	Ns	Ns
MC (75 DAS)		*	**	ns	-	-	-	-	-	-
MR (75 DAS)		*	ns	ns	-	-	-	-	-	-
Number of Flowers		*	**	ns	*	**	**	*	**	Ns
Number of Pods		*	**	ns	*	**	***	*	*	Ns
Pod dry weight		*	**	ns	*	**	ns	*	Ns	Ns
Number of Seeds		*	**	***	*	**	***	*	**	Ns
Seed dry weight		*	ns	ns	*	**	ns	*	Ns	Ns
100 seed weight		*	**	***	*	**	***	*	Ns	Ns
Above ground dry weight		*	ns	ns	*	ns	ns	*	Ns	Ns
HI		*	ns	ns	*	ns	ns	*	Ns	Ns
N concentration	Roots	*	**	ns	*	**	***	*	Ns	Ns
	Nodules	*	**	***	*	**	***	*	**	***
	Leaves	*	**	ns	*	**	***	*	**	***
P concentration	Roots	*	**	***	*	**	***	*	**	***
	Nodules	*	**	ns	*	**	***	*	Ns	Ns
	Leaves	*	**	ns	*	**	***	*	**	***
Mg2+concentration	Roots	*	**	***	*	**	***	*	**	***
	Nodules	*	**	ns	*	**	***	*	Ns	Ns
	Leaves	*	**	***	*	**	ns	*	**	***
K+ concentration	Roots	*	**	ns	*	**	***	*	Ns	Ns
	Nodules	*	**	ns	*	**	***	*	**	***
	Leaves	*	**	***	*	**	ns	*	**	***
Protein concentration	Roots	*	**	***	*	**	***	*	**	***
	Nodules	*	**	***	*	**	***	*	**	***
	Leaves	*	**	***	*	**	***	*	Ns	Ns
	Seeds	*	**	***	*	**	ns	*	Ns	Ns
SOD activity	Roots	*	**	ns	*	**	***	*	Ns	Ns
	Nodules	*	**	***	*	**	***	*	Ns	Ns
	Leaves	*	**	***	*	**	***	*	Ns	Ns
CAT activity	Roots	*	**	***	*	**	***	*	Ns	Ns
	Nodules	*	**	***	*	**	ns	*	Ns	Ns
	Leaves	*	**	ns	*	**	ns	*	Ns	Ns
POX activity	Roots	*	**	***	*	**	***	*	Ns	Ns
	Nodules	*	**	***	*	**	***	*	Ns	Ns
	Leaves	*	**	ns	*	**	ns	*	Ns	Ns

Note: ns no significant variation. * Significant variation at 95%, ** Significant variation at 99% and *** Significant variation at 99.9%.

2.2.7. Antioxidant Enzyme Activity

Superoxide dismutase (SOD, EC 1.15. 1.1) activity was assayed in fresh roots, nodules and shoot by the method of Dhindsa, Plumb-Dhindsa, and Thorpe (1981) and was expressed as µkat (microkatals) per mg protein (1 katal = 1 mol s-1catalytic activity). Catalase (CAT, 1.11.1.6) activity was assayed by method of Aebi (1984) and was expressed as nkat (nanokatals) per mg protein. Peroxidase (EC number 1.11.1.x) activity was assayed by method of Castillo, Penel, and Greppin (1984) and  was expressed as nkattetraguaiacol formed per mg protein.

2.3. Statistical Analysis

Data was finalized by taking average of values derived from six biological replicates ± standard error (S.E.) per treatment. Data was statistically ensured by analysis of variance (ANOVA) using SPSS 18.0 for Windows (SPSS, Inc., Chicago, IL, USA). One-way ANOVA, Duncan’s multiple-range test was carried out at p < 0.05 to evaluate the means of dependent variables. Two-way ANOVA was performed (at all three levels i.e. 95%, 99% and 99.9%) to study the significance of interaction between mycorrhiza and RL symbioses on various parameters.

3. RESULTS

Analysis of variance divulged that independent factors [rhizobial inoculation (R), arbuscular mycorrhiza (AM) inoculations], when considered independently, had significant effect on all dependent variable (at 95%). First order (R × AM) interactions too had significant effects at 95%, on all the dependent variables under investigation Table 1.

3.1. Growth Attributes

Shoot and root dry weight (SDW and RDW) of plants under different treatments were analyzed at 50 DAS Figure 1. Rhizobial and/or AM inoculation improved root growth, thereby increasing root’s absorptive surface area and the degree of explored soil for resources, which could also be associated with the improved above ground plant parts. Though benefits endorsed by co-inoculation of R and AM inoculation were the most significant, AM inoculation could provide higher degree of assistance in plant growth than rhizobial inoculation. Microbial colonization being more effective in improving RDW than SDW, led to higher RSR relative to non colonized plants.

Figure-1. Result of Rhizobium (R) and mycorrhizal inoculation [individually as well as in amalgamation] on Dry weight of Roots and Shoots (g plant-1) and Root to Shoot Ratio in groundnut variety grown in sterile and non-sterile conditions.

Treatments: Control (-R-AM), Rhizobial treatment (+R-AM), Mycorrhizal treatment (-R+AM) and Rhizobial and mycorrhizal treatment (+R+AM). Data represented is average of six biological replicates ± standard error (S.E.). According to Duncan's multiple-range test, values followed by the identical letter within a soil type do not vary at p < 0.05.

3.2. Symbiotic Effectiveness

3.2.1. Mycorrhizal Colonization and Responsiveness

Microscopic assessment for calculating per cent mycorrhizal colonization (MC) in roots was carried out and the data is presented in Table 2. No sign of MC was observed in the root segments of uninoculated plants, thereby confirming the absolute absence of innate mycorrhiza. On the other hand, remarkable colonization was observed in the mycorrhizal  roots at 50 DAS. Intensity of colonization by fungal endophyte in rhizobial treated plants was observed to be significantly higher than the respective –R+AM plants. Calculating plant responsiveness to mycorrhizas is a measure of mycorrhizal fungus effectiveness, thus variation in MR, with and without R application was calculated. Rhizobial application decreased plants responsiveness to mycorrhization Table 2.

Table-2. Result of Rhizobium (R) and mycorrhizal inoculation [individually as well as in amalgamation] on Mycorrhizal colonization (MC, %), Mycorrhizal responsiveness (MR, %), Nodule number (NN, plant-1), Dry weight of nodules (NDW, g plant-1) and Leghemoglobin (LHb) concentration (μg-1 g F.W.) in groundnut variety.

	ROOTS		NODULES
Treatment	MC	MR	NN	NDW	LHb
Control	-	-	27.54c±0.3329	0.25c±0.0085	144.275d±4.856
+R	-	-	33.18ab±1.0949	0.31ab±0.0121	197.451b±3.818
+AM	70.97±2.0835	32.01±3.3021	32.35b±0.3404	0.30b±0.0060	175.696c±2.322
+R+AM	80.24±3.6663	28.31±4.5432	35.90a±0.2426	0.34a±0.0060	227.706a±0.569

Treatments: Mycorrhizal treatment (-R+AM) and Rhizobial and mycorrhizal treatment (+R+AM). Data represented is average of six biological replicates ± standard error (S.E.). According to Duncan's multiple-range test, values followed by the identical letter within a soil type do not vary at p < 0.05.

3.2.2. Nodulation (Nodule Number, Dry Weight and Leghemoglobin Concentration)

Visual examination indicated clustered arrangement of large healthy pink colouredglobose nodules in plants, however suppression of successful nodule establishment in plants growing in -R soils was clearly evidenced by lower nodule count Table 2 as compared to their +R counterparts. It was observed that absence of Rhizobium had comparatively higher adverse impact on nodule dry weight (NDW) accumulation and leghemoglobin (LHb) concentration than their establishment, thus although nodule formation initiated under -R condition, it’s appropriate development and functioning could not be retained. Results further revealed that individually, R and AM inoculation led to remarkable enhancement in the new nodule formation and growth, which was witnessed by higher NN in +R-AM and –R+AM plants. The nodules were relatively healthier and accumulated higher biomass and LHb, when they were grown in the soils inoculated with either R or F. mosseae. Comparatively, rhizobial inoculation was more effective in improving NN, NDW and LHb than mycorrhization and rhizobial inoculation to mycorrhizal soils further improved development of Bradyrhizobium-legume association. Benefits of this tripartite association was elicited by much higher number and biomass accumulation in nodules. Higher leghemoglobin (LHb) pigment concentration in +R+AM treatments allied with higher nodular development, thereby increasing the requirement of LHb to maintain apposite oxygen tension.

3.3. Nutrient Content

Higher concentration of N, K and Mg was detected in leaves as compared to roots, but P concentration was higher in roots relative to leaves. However it was observed that plants inoculated with Bradyrhizobium or F. mosseaehad superior capability to maintain nutrient uptake and distribution (significant S × R and S × AM interactions), with higher effectiveness of mycorrhization as compared to R application (except for N, where rhizobial inoculation outperformed AM inoculation). Effectiveness of microbial inoculation was tissue dependent with higher augmentation provided in roots relative to shoots. Administration of R in the rooting medium along with mycorrhization, appeared to put forth a profound control on nutrients homeostasis (resulted in maximum accretion of nutrient pool), thereby further pointing towards mutual behaviour of R and AM Table 3.

3.4. Relative Water Content and Chlorophyll (Chl.) Content

Higher biomass in inoculated plants was strongly associated with their water status Table 3 and superior chl. Figure 2, which might be due to increased cellular turgidity leading to cellular enlargement, nutrient acquisition and adequate capability to trap photosynthetic light, ultimately improving plant metabolic activities and biomass accumulation. Further observations recorded evidenced that microbial inoculations, especially AM, could improve chl. a concentration better than chl. b, thereby improving chl. a/b ratio. Yellowing, scorching and subsequent senescence of leaves was least in +R+AM plants. Thus, results confirmed that interactions of R and AM were preeminent to counterbalance the plant water deficit and pigment loss caused by uncontrolled factors in natural soils.

Figure-2.Result of Rhizobium (R) and mycorrhizal inoculation [individually as well as in amalgamation] on Chlorophyll a, b and total (mg g-1 F.W.) and chlorophyll a/b ratio in the leaves of groundnut variety.

Treatments: Control (-R-AM), Rhizobial treatment (+R-AM), Mycorrhizal treatment (-R+AM) and Rhizobial and mycorrhizal treatment (+R+AM). Data represented is average of six biological replicates ± standard error (S.E.). According to Duncan's multiple-range test, values followed by the identical letter within a soil type do not vary at p < 0.05.

Table-3. Result of Rhizobium (R) and mycorrhizal inoculation [individually as well as in amalgamation] on Relative Water Content (RWC, %) in leaves, Nitrogen (N), Phosphorus (P), Potassium ion (K+) and Magnesium ion (Mg2+) concentration (mg g-1 D.W.) in roots and leaves of groundnut variety.

Treatment	RWC in leaves	Roots				Leaves
		N	P	K	Mg	N	P	K	Mg
-R-AM	70.71d ±1.231	13.00c ±0.455	2.77d ±0.095	8.60d ±0.185	9.71c ±0.170	19.30c ±0.310	2.18b ±0.132	17.06c ±0.485	12.27c ±0.315
+R-AM	74.87c ±0.345	16.51b ±0.040	3.69c ±0.122	10.50c ±0.213	11.25b ±0.254	25.03b ±0.585	2.69ab ±0.064	19.29b ±0.419	13.76b ±0.199
-R+AM	82.40b ±0.761	15.80b ±0.298	4.20b ±0.107	11.68b ±0.051	12.21ab ±0.469	24.79b ±0.096	2.98a ±0.083	20.68ab ±0.218	14.69ab ±0.152
+R+AM	94.68a ±0.462	18.56a ±0.215	4.65a ±0.206	12.90a ±0.060	13.19a ±0.346	27.76a ±0.296	3.23a ±0.173	22.11a ±0.483	15.65a ±0.257

Treatments: Control (-R-AM), Rhizobial treatment (+R-AM), Mycorrhizal treatment (-R+AM) and Rhizobial and mycorrhizal treatment (+R+AM). Data represented is average of six biological replicates ± standard error (S.E.). According to Duncan's multiple-range test, values followed by the identical letter within a soil type do not vary at p < 0.05.

3.5. Protein Concentration

Effect of R and/or AM inoculation on total protein concentration was determined in roots and leaves and observations recorded are shown in Figure 3. As compared to roots, superior nutrient homeostasis in foliar tissue accounted for better accumulation of proteins. Improvement in status of protein pool was recorded in plants treated with R and/or AM inoculated ones and the enhancement in proteins was coupled with enhanced vigor of +R-AM, -R+AM and +R+AM plants over –R-AM plants. Although both R application and AM inoculation (when applied individually) significantly improved protein concentration, yet R mediated enhancement in proteins was considerably higher than mycorrhization mediated enrichment of protein pool. Further, rhizobial inoculation as well as mycorrhization complemented each other and significantly improved protein status in groundnut variety.

Figure-3. Result of Rhizobium (R) and mycorrhizal inoculation [individually as well as in amalgamation] on Protein concentration (mg g-1 F.W.) in roots and leaves of groundnut variety grown in sterile and non-sterile conditions.

Treatments: Control (-R-AM), Rhizobial treatment (+R-AM), Mycorrhizal treatment (-R+AM) and Rhizobial and mycorrhizal treatment (+R+AM). Data represented is average of six biological replicates ± standard error (S.E.). According to Duncan's multiple-range test, values followed by the identical letter within a soil type do not vary at p < 0.05.

3.6. Enzymatic Antioxidant Activity

Activity of superoxide dismutase (SOD), catalase (CAT) and peroxidise (POX) in groundnut variety was strongly correlated with plant tissue, where higher activity was recorded in roots Table 4. Antioxidant enzyme activity further accelerated when plants were treated with R and/or F. mosseaeinoculum. Superior antioxidant enzyme activity under rhizobial inoculation and/or mycorrhization pointed towards competent scavenging of ROS in microbial treated plants relative to corresponding –R-AM ones. Although rhizobial inoculation and mycorrhization exhibited synchronisation (+R+AM) in up-regulating antioxidant activity, however individually mycorrhization (-R+AM) mediated upsurge in antioxidant activity was considerably higher than rhizobial inoculation (+R-AM) mediated upsurge. Improvement in root antioxidant machinery was more significant as compared to leaves, pointing towards microbial mediated better heath to below-ground plant parts, thereby imparting better adherence to soil for water and nutrient uptake.

Table-4. Result of Rhizobium (R) and mycorrhizal inoculation [individually as well as in amalgamation] on Superoxide dismutae (SOD, μkats mg protein), Catalase (CAT, µkat mg-1 protein) and Peroxidase (POX, nkat mg-1 protein) activity in roots and leaves of groundnut variety.

Treatment	ROOTS			LEAVES
	SOD	CAT	POX	SOD	CAT	POX
-R-AM	84.59c ±2.449	5.93c ±0.348	448.50d ±4.364	62.40c ±1.492	6.21d ±0.090	188.06c ±4.562
+R-AM	98.30bc ±2.808	6.75b ±0.216	522.95c ±4.572	69.91bc ±2.745	6.85c ±0.124	211.47b ±5.603
-R+AM	106.86ab ±1.510	7.26ab ±0.165	569.47b ±4.719	74.61ab ±2.160	7.26b ±0.082	226.10ab ±2.036
+R+AM	115.63a ±5.823	7.79a ±0.175	617.08a ±8.385	79.41a ±2.700	7.67a ±0.104	241.07a ±4.936

Treatments: Control (-R-AM), Rhizobial treatment (+R-AM), Mycorrhizal treatment (-R+AM) and Rhizobial and mycorrhizal treatment (+R+AM). Data represented is average of six biological replicates ± standard error (S.E.). According to Duncan's multiple-range test, values followed by the identical letter within a soil type do not vary at p < 0.05.

3.7. Yield Parameters

Harvest is an important trait measuring reproductive efficiency as well as source-sink balance of legumes and in multiplicative conjunction with biomass; it is a determinant of crop yield. Ultimate yield of crop plant is the function of various yield components comprising its flowering aptitude and their subsequent transition into pods enclosing harvestable seeds. Thus the effect of R and/or AM in modulating various yield components and subsequently HI of groundnut was analyzed till maturity at 110 DAS. Relative to inoculated plants, the competence of vegetative phase to progress into reproductive buds considerably reduced in non-inoculated plants and was elicited in the form of delayed as well as significantly restrained progression of flowers into pods Table 5. On the other hand fungal endophyte in the rhizosphere boosted flowering and robustness of pods and seeds more significantly than the rhizobial application. HI, an attribute portraying proportion of aboveground assimilates allocated to seeds, also improved with R and/or AM inoculation. Moreover, rhizobial inoculation and mycorrhization when applied individually had significant impact on protein accumulation in the economically important plant part i.e. seed. Rhizobial inoculation outperformed mycorrhization which could be highly correlated with better N acquisition by +R-AM plants. Moreover, when the rhizobial coated seeds were sown in mycorrhizal soils, the improvement in protein assimilation in seeds was most prominent, thereby improving the fitness of groundnut seeds in +R+AM plants.

Table-5. Result of Rhizobium (R) and mycorrhizal inoculation [individually as well as in amalgamation] on yield components of groundnut variety.

Treatment	Number of pods per plant	Number of seeds per plant	Seeds dry weight per plant (g)	Above ground dry weight (g plant-1)	HI	Protein concentration (mg g-1 seeds)
-R-AM	56b±2.309	42b±1.730	10.12d±0.530	23.99d±1.240	0.431	0.422c±0.029
+R-AM	74a±1.732	65a±2.520	21.34a±0.520	49.00a±1.580	0.442	0.618b±0.019
-R+AM	76a±2.081	41b±5.290	13.67c±1.040	30.77c±1.470	0.431	0.535b±0.0127
+R+AM	83a±6.082	58a±3.460	17.99b±1.090	39.58b±2.000	0.455	0.725a±0.008

Treatments: Control (-R-AM), Rhizobial treatment (+R-AM), Mycorrhizal treatment (-R+AM) and Rhizobial and mycorrhizal treatment (+R+AM). Data represented is average of six biological replicates ± standard error (S.E.). According to Duncan's multiple-range test, values followed by the identical letter within a soil type do not vary at p < 0.05.

4. DISCUSSION

Superior perpetuation of osmotic, photosynthetic, nutrient and redox equilibrium in +R plants directed to overall improvement in plant growth as evidenced by their improved biomass at both vegetative as well as reproductive stage. Increased nodulation and LHb concentration owing to rhizobial inoculation could be because of increased proportion of effective infections. Improvement in nodulation and functionality in +R-AM plants was evidenced by considerably higher nitrogen and protein concentration in roots and shoots of these plants as compared to –R-AM plants. Plants with rhizobial inoculation also evidenced superior P concentration which could be the probable source of energy for improved nodulation. In view of the fact that N is a vital constituent of chlorophyll (Tucker, 2004); rhizobia inoculated enhancement in chl. concentration could be an indirect consequence of improved N2-supplementation via enhanced legume–Rhizobium symbiosis. Superior RWC recorded in these samples could also be due to improved root density as well as vigor that upgraded water absorption aptitude of plants by widening the rhizosphere to be explored. Interestingly, activity of defense related proteins i.e. SOD, CAT and POX, also increased with higher activity recorded in roots thereby indicating the tendency of maintaining redox equilibrium in roots more significantly. Superior perpetuation of osmotic, photosynthetic, nutrient and redox equilibrium in +R plants directed to overall improvement in plant growth as evidenced by their improved biomass at both vegetative as well as reproductive stage.

As compared to rhizobial inoculation, mycorrhizal colonization was resourcefully more competent in improving plant growth. Highly dense root system in mycorrhizal plants relative to non-mycorrhizal ones, could be due to mycorrhization mediated alteration in root morphology in a structural, spatial, quantitative and temporal conduct (Kapoor, Sharma, & Bhatnagar, 2008); thereby resulting in better rooting structure and superior total potential absorbing surface relative to the non mycorrhizal plants (Khalil, Eissa, El-Shazly, & Nasr, 2011; Zai et al., 2007). A higher improvement in root than shoot biomass in -R+AM and +R-AM groundnut plants (as indicated by increased RSR) pointed towards the facilitation served by rhizobia inoculation as well as mycorrhization to preferentially recover root system for superior rhizosphere exploration so as to improve capitalization of nutrient and water uptake. Higher allocation of photosynthates to the below ground plant parts and the resultant higher RDW and MC could prompt advanced trade of N and P by mycorrhiza in exchange (Fellbaum et al., 2012; Hammer, Pallon, Wallander, & Olsson, 2011) thereby ensuring superior benefits to those plants. Comparatively higher RWC in leaves of mycorrhizal plants could be due to AM induced superior root morphology (Kothari, Marschner, & George, 1990) superior root hydraulic conductivity even at low water potential (Kapoor et al., 2008) higher stomatal conductance insisting for added transpiration (Sheng et al., 2008) and higher solutes accumulation, thus improving plant osmotic equilibrium (Abdel Latef & Miransari, 2014). Higher Mg2+ and chl. concentration in mycorrhizal plants corroborated with their higher growth, advocating that higher requirement of fixed carbon in mycorrhizal plants could have enhanced Mg2+ uptake thereby improving chl. concentration which could have consequently improved CO2 assimilation efficiency (Wu, Zou, & He, 2010) and hence plant fitness.

Although total proteins (defence as well as non defence related) increased more appreciably in +R-AM plants relative to –R+AM plants, defence related antioxidant proteins increased more significantly in –R+AM plants. Increase in antioxidants could be the plant’s inherent capacity to up-regulate proteins related to stress adaptation (Ghosh & Xu, 2014). Abbaspour, Saeidi-Sar, Afshari, and Abdel-Wahhab (2012) and Cicatelli et al. (2012) suggested that an efficient approach used by AM plants to attain tolerance is to increase antioxidant enzyme activity of plant origin. In this regard, Alguacil, Hernandez, Caravaca, Portillo, and Roldan (2003) and Ruiz-Lozano et al. (2012) proposed that mycorrhiza inoculation induces host’s antioxidant activity by improving its growth and assimilation of low mobility micronutrients exploited as co-factors of metallo-enzymes e.g. SOD, CAT etc.. In the present investigation mycorrhizal inoculation also improved nodulation and nitrogen fixation, which could be attributed to increased growth of root, which favoursrhizobial colonization (Goss & De Varennes, 2002; Patreze & Cordeiro, 2004). Further, mycorrhization can augment surface area of roots for additional absorption of nutrients and AM nutrient uptake pathway operates more extensively than direct uptake by root transporters (Smith, Facelli, Pope, & Smith, 2010). Thus, mycorrhization can result in better assimilation of minerals especially P, which would result in more energy available for N2 fixation by rhizobia (Dardanelli et al., 2008). P improvement in inoculated plants was proportionate to the improvement in nodulation and N fixation, thus authenticating the P essentiality for sufficient N2 fixation (Rotaru & Sinclair, 2009). Mycorrhization-adjudicated efficient assimilation of N in the host plants could also be because of increased ammonium (NH4+) and nitrate (NO3-) uptake from the soil by extra radical mycelium (ERM) of mycorrhiza, as has been proposed by Guether et al. (2009);Tian et al. (2010) and Fellbaum et al. (2012). In the present study, increase in N concentration was more significant in +R-AM plants relative to –R+AM plants thus proposing that, improvement in N assimilation via increase in rhizobial N2-fixation was the preferred stratagem than the increase in direct uptake of inorganic N. Higher P acquisition in mycorrhizal plants, was perhaps due to higher P uptake via mycorrhiza which can even completely replace direct uptake by plant transporters (Smith, Jakobsen, Grønlund, & Smith, 2011). In fact, mycorrhizal hyphae expand beyond the depletion zones surrounding roots and obtain nutrients that are far from the root surface (Smith & Read, 2008). As compared to rhizobial inoculation, mycorrhization was considerably better in sustaining the osmotic equilibrium along with photo-assimilating aptitude, thereby leading to much higher biomass accumulation.

Individually, mycorrhiza mediated improvement in overall plant growth and performance was higher than rhizobia inoculated improvement, but +R+AM plants possessed maximum competence to grow in experimental soils. Higher performance of +R+AM plants (in terms of relative water content, chlorophyll content, nutrient and redox equilibrium) could be either due to improved root growth, thereby providing better niche for AM colonization or due to cumulative effect of their individual affirmative effects. Furthermore as compared to –R+AM plants, MR decreased in +R+AM plants which specified that rhizobia inoculation also contribute in attenuating indigenous burden and hence abridged the exclusive investment of mycorrhiza in upregulating plant metabolism. Highest accumulation of photosynthetic pigments in +R+AM plants was also owing to improved N2-fixation via functional complementarity displayed by rhizobia and mycorrhiza. Nutrient accumulation (N, P, K and Mg) further increased in rhizobial inoculated mycorrhizal plants which could be due to cross-assistance provided by each microbe to another i.e. increased P uptake via mycorrhization further upregulated R-mediated improvement in N2 fixation which led to enhanced growth and mycorrhization as well as improved nutrient uptake in +R+AM plants. Relative assessment of rhizobial inoculation and mycorrhization indicated that improvement in all but nitrogen metabolism and N acquisition was more significant by mycorrhization than rhizobial inoculation, albeit their amalgamation displayed synergism to uplift rhizobial symbiosis and overall functioning of host legume.

Consequently, higher biomass accumulation accounted for higher photo-assimilates being loaded in the sink during seed filling, thereby strongly linking the plant dynamism at vegetative phase with that of reproductive phase. Interestingly in the present investigation, transition of vegetative phase to reproductive phase was significantly improved in both rhizobial and mycorrhizal inoculation, with improved flowering, pod formation, seed set and eventually harvest (as evidenced by HI). Better performance of inoculated plants at reproductive stage was tightly coupled with superior RWC and chlorophyll concentration, thus suggesting that the effectual water and photosynthates movement towards sink might have accounted for superior flower initiation, better pollen germination and pollen tube growth leading to healthier pod formation and finally higher seed set and protein concentration. Improvement in seed weight and the resultant harvest index in correspondence with the improvement in aboveground dry weight of inoculated plants substantiated the importance of efficient photosynthate allocation in the direction of seed filling in up regulating the ultimate harvest. Maximum preservation of water and redox status and photosynthetic pigments in +R+AM plants subsequently routed most efficient carbon allocation at reproductive stage, leading to utmost continuance of high protein yielding peanuts as is also statistically evidenced by 2-way ANOVA.

5. CONCLUSIONS

Thus, ‘symbiosis-promoting effect’ of these microbes had most affirmative effects on growth and harvest index of groundnut variety and helped plants to thrive better in soils without any chemical fertilizers. Thus, present investigation indicates that shaping dynamic rhizosphere microbiome can enhance the productivity of this variety for sustainable agriculture in changing environment and can offer many economical and environmental benefits.

Funding: This study received no specific financial support.

Competing Interests: The authors declare that they have no competing interests.

Acknowledgement: Authors gratefully acknowledge Science and Research Centre, SGTB Khalsa College, University of Delhi, Delhi, India for awarding fiscal support in undertaking this Summer Research Project. Authors gratefully acknowledge Directorate of Groundnut Research, Junagadh, Gujrat for providing Groundnut cultivar (TG37A: A Spanish groundnut cultivar) alongwith its specific Rhizobial culture (TAL1000) and Centre for Mycorrhizal Culture Collection, The Energy and Resource Institute (T.E.R.I.), New Delhi for providing pure cultures of Funneliformismosseae. Authors are highly thankful to Dr. RoopamKapoor, Department of Botany, University of Delhi, for her invariable support.

REFERENCES

Abbaspour, H., Saeidi-Sar, S., Afshari, H., & Abdel-Wahhab, M. (2012). Tolerance of mycorrhiza infected pistachio (Pistacia vera L.) seedling to drought stress under glasshouse conditions. Journal of Plant Physiology, 169(7), 704-709.

Abdel Latef, A. A. H., & Miransari, M. (2014). The role of arbuscular mycorrhizal fungi in alleviation of salt stress. In: Use of microbes for the alleviation of soil stresses, (Ed.) Miransari, M (pp. 23-38). New York: Springer Science Business Media.

Aebi, H. (1984). Catalase in vitro. Methods in Enzymology, 105, 121-126. Available at: 10.1016/s0076-6879(84)05016-3.

Afkhami, M. E., Rudgers, J. A., & Stachowicz, J. J. (2014). Multiple mutualist effects: Conflict and synergy in multispecies mutualisms. Ecology, 95(4), 833-844. Available at: https://doi.org/10.1890/13-1010.1.

Akhtar, M. S., Siddiqui, Z. A., & Wiemken, A. (2011). Arbuscular mycorrhizal fungi and rhizobium to control plant fungal diseases. In: Alternative farming systems, biotechnology, drought stress and ecological fertilization. 263-292.

Alguacil, M., Hernandez, J., Caravaca, F., Portillo, B., & Roldan, A. (2003). Antioxidant enzyme activities in shoots from three mycorrhizal shrub species afforested in a degraded semi-arid soil. Physiologia Plantarum, 118(4), 562-570. Available at: https://doi.org/10.1034/j.1399-3054.2003.00149.x.

Allen, S. F., Grimshaw, H. F., & Rowl, A. B. (1984). Chemical analysis. In: Methods in plant ecology, (Eds) Moor, P.D. and Chapman, S.B (pp. 185-344). Oxford: Blackwell.

Arnon, D. I. (1949). Copper enzymes in isolated chloroplasts. Polyphenoloxidase in Beta vulgaris. Plant Physiology, 24(1), 1-15. Available at: https://doi.org/10.1104/pp.24.1.1.

Aroca, R., Porcel, R., & Ruiz‐Lozano, J. M. (2007). How does arbuscular mycorrhizal symbiosis regulate root hydraulic properties and plasma membrane aquaporins in Phaseolus vulgaris under drought, cold or salinity stresses? New Phytologist, 173(4), 808-816. Available at: https://doi.org/10.1111/j.1469-8137.2006.01961.x.

Bauer, J. T., Kleczewski, N. M., Bever, J. D., Clay, K., & Reynolds, H. L. (2012). Nitrogen-fixing bacteria, arbuscular mycorrhizal fungi, and the productivity and structure of prairie grassland communities. Oecologia, 170(4), 1089-1098. Available at: https://doi.org/10.1007/s00442-012-2363-3.

Bradford, M. M. (1976). A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry, 72(1-2), 248-254. Available at: https://doi.org/10.1016/0003-2697(76)90527-3.

Castillo, F. J., Penel, C., & Greppin, H. (1984). Peroxidase release induced by ozone in Sedum album leaves: Involvement of Ca2+. Plant Physiology, 74(4), 846-851. Available at: https://doi.org/10.1104/pp.74.4.846.

Chandrasekaran, M., Boughattas, S., Hu, S., Oh, S.-H., & Sa, T. (2014). A meta-analysis of arbuscular mycorrhizal effects on plants grown under salt stress. Mycorrhiza, 24(8), 611-625. Available at: https://doi.org/10.1007/s00572-014-0582-7.

Cicatelli, A., Lingua, G., Todeschini, V., Biondi, S., Torrigiani, P., & Castiglione, S. (2012). Arbuscular mycorrhizal fungi modulate the leaf transcriptome of a Populus alba L. clone grown on a zinc and copper-contaminated soil. Environmental and Experimental Botany, 75, 25-35. Available at: https://doi.org/10.1016/j.envexpbot.2011.08.012.

Clúa, J., Roda, C., Zanetti, M. E., & Blanco, F. A. (2018). Compatibility between legumes and rhizobia for the establishment of a successful nitrogen-fixing symbiosis. Genes, 9(3), 1-21. Available at: https://doi.org/10.3390/genes9030125.

Dalpé, Y., & Monreal, M. (2004). Arbuscular mycorrhiza inoculum to support sustainable cropping systems. Crop Management, 3(1), 1-11. Available at: https://doi.org/10.1094/cm-2004-0301-09-rv.

Dardanelli, M. S., de Cordoba, F. J. F., Espuny, M. R., Carvajal, M. A. R., Díaz, M. E. S., Serrano, A. M. G., . . . Megías, M. (2008). Effect of Azospirillum brasilense coinoculated with Rhizobium on Phaseolus vulgaris flavonoids and Nod factor production under salt stress. Soil Biology and Biochemistry, 40(11), 2713-2721. Available at: https://doi.org/10.1016/j.soilbio.2008.06.016.

Dhindsa, R. S., Plumb-Dhindsa, P., & Thorpe, T. A. (1981). Leaf senescence: Correlated with increased levels of membrane permeability and lipid peroxidation, and decreased levels of superoxide dismutase and catalase. Journal of Experimental Botany, 32(1), 93-101. Available at: https://doi.org/10.1093/jxb/32.1.93.

Evelin, H., Giri, B., & Kapoor, R. (2012). Contribution of Glomus intraradices inoculation to nutrient acquisition and mitigation of ionic imbalance in NaCl-stressed Trigonella foenum-graecum. Mycorrhiza, 22(3), 203-217. Available at: https://doi.org/10.1007/s00572-011-0392-0.

Fellbaum, C. R., Gachomo, E. W., Beesetty, Y., Choudhari, S., Strahan, G. D., Pfeffer, P. E., . . . Bücking, H. (2012). Carbon availability triggers fungal nitrogen uptake and transport in arbuscular mycorrhizal symbiosis. Proceedings of the National Academy of Sciences, 109(7), 2666-2671. Available at: https://doi.org/10.1073/pnas.1118650109.

Geng, L.-L., Shao, G.-X., Raymond, B., Wang, M.-L., Sun, X.-X., Shu, C.-L., & Zhang, J. (2018). Subterranean infestation by Holotrichia parallela larvae is associated with changes in the peanut (Arachis hypogaea L.) rhizosphere microbiome. Microbiological Research, 211, 13-20. Available at: https://doi.org/10.1016/j.micres.2018.02.008.

Ghosh, D., & Xu, J. (2014). Abiotic stress responses in plant roots: A proteomics perspective. Frontiers in Plant Science, 5, 6.

Gibson, K. E., Kobayashi, H., & Walker, G. C. (2008). Molecular determinants of a symbiotic chronic infection. Annual review of Genetics, 42, 413-441. Available at: https://doi.org/10.1146/annurev.genet.42.110807.091427.

Goss, M., & De Varennes, A. (2002). Soil disturbance reduces the efficacy of mycorrhizal associations for early soybean growth and N2 fixation. Soil Biology and Biochemistry, 34(8), 1167-1173. Available at: https://doi.org/10.1016/s0038-0717(02)00053-6.

Gould, K. S., & Lister, C. (2005). Flavonoid functions in plants. In: Flavonoids: Chemistry, biochemistry, and applications (eds.) Anderson, O.M. and Markham, K.R (pp. 397-441). Boca Raton: CRC.

Guether, M., Neuhäuser, B., Balestrini, R., Dynowski, M., Ludewig, U., & Bonfante, P. (2009). A mycorrhizal-specific ammonium transporter from Lotus japonicus acquires nitrogen released by arbuscular mycorrhizal fungi. Plant Physiology, 150(1), 73-83. Available at: https://doi.org/10.1104/pp.109.136390.

Habte, M., & Osorio, N. W. (2001). Arbuscular mycorrhizas: Producing and applying arbuscular mycorrhizal inoculum. Department of Tropical Plant and Soil Sciences, College of Tropical Agriculture and Human Resources, University of Hawaii, Monoa.

Hajiboland, R., Aliasgharzadeh, N., Laiegh, S. F., & Poschenrieder, C. (2010). Colonization with arbuscular mycorrhizal fungi improves salinity tolerance of tomato (Solanum lycopersicum L.) plants. Plant and Soil, 331(1-2), 313-327. Available at: https://doi.org/10.1007/s11104-009-0255-z.

Hammer, E. C., Pallon, J., Wallander, H., & Olsson, P. A. (2011). Tit for tat? A mycorrhizal fungus accumulates phosphorus under low plant carbon availability. FEMS Microbiology Ecology, 76(2), 236-244. Available at: https://doi.org/10.1111/j.1574-6941.2011.01043.x.

Hartree, E. F. (1957). Haematin compounds. In: Modern methods of plant analysis, (eds.) Paech, K. and Tracey, M.V. (pp. 197-245). Berlin: Springer-Verlag, Germany.

Hiscox, J., & Israelstam, G. (1979). A method for the extraction of chlorophyll from leaf tissue without maceration. Canadian Journal of Botany, 57(12), 1332-1334. Available at: https://doi.org/10.1139/b79-163.

Jackson, M. L. (1973). Soil chemical analysis (pp. 485). New Delhi: Printice Hall.

Jensen, E. S., Peoples, M. B., Boddey, R. M., Gresshoff, P. M., Hauggaard-Nielsen, H., Alves, B. J. R., & Morrison, M. J. (2012). Legumes for mitigation of climate change and feedstock in a bio-based economy – A review. Agronomy for Sustainable Development, 32, 329-364. Available at: doi.org/10.1007/s13593-011-0056-7.

Kapoor, R., Sharma, D., & Bhatnagar, A. (2008). Arbuscular mycorrhizae in micropropagation systems and their potential applications. Scientia Horticulturae, 116(3), 227-239. Available at: https://doi.org/10.1016/j.scienta.2008.02.002.

Khalil, H. A., Eissa, A. M., El-Shazly, S. M., & Nasr, A. M. A. (2011). Improved growth of salinity-stressed citrus after inoculation with mycorrhizal fungi. Scientia Horticulturae, 130(3), 624-632. Available at: https://doi.org/10.1016/j.scienta.2011.08.019.

Kothari, S., Marschner, H., & George, E. (1990). Effect of VA mycorrhizal fungi and rhizosphere microorganisms on root and shoot morphology, growth and water relations in maize. New Phytologist, 116(2), 303-311. Available at: https://doi.org/10.1111/j.1469-8137.1990.tb04718.x.

Krishna, G., Singh, B. K., Kim, E.-K., Morya, V. K., & Ramteke, P. W. (2015). Progress in genetic engineering of peanut (Arachis hypogaea L.)—A review. Plant Biotechnology Journal, 13(2), 147-162.

Leport, L., Turner, N. C., Davies, S., & Siddique, K. (2006). Variation in pod production and abortion among chickpea cultivars under terminal drought. European Journal of Agronomy, 24(3), 236-246. Available at: https://doi.org/10.1016/j.eja.2005.08.005.

Lindner, R. (1944). Rapid analytical methods for some of the more common inorganic constituents of plant tissues. Plant Physiology, 19(1), 76-89. Available at: https://doi.org/10.1104/pp.19.1.76.

Lucas, J. A., García-Cristobal, J., Bonilla, A., Ramos, B., & Gutierrez-Manero, J. (2014). Beneficial rhizobacteria from rice rhizosphere confers high protection against biotic and abiotic stress inducing systemic resistance in rice seedlings. Plant Physiology and Biochemistry, 82, 44-53. Available at: https://doi.org/10.1016/j.plaphy.2014.05.007.

McGonigle, T., Miller, M., Evans, D., Fairchild, G., & Swan, J. (1990). A new method which gives an objective measure of colonization of roots by vesicular—arbuscular mycorrhizal fungi. New Phytologist, 115(3), 495-501. Available at: https://doi.org/10.1111/j.1469-8137.1990.tb00476.x.

Mehlich, A. (1953). Determination of P, Ca, Mg, K, Na and NH4. Short Test Methods Used in Soil Testing Division, Department of Agriculture, North Carolina Soil Testing Division, Raleigh, North Carolina.

Miransari, M. (2011). Soil microbes and plant fertilization. Applied Microbiology and Biotechnology, 92(5), 875-885. Available at: https://doi.org/10.1007/s00253-011-3521-y.

Mukherjee, A., & Ané, J.-M. (2011). Germinating spore exudates from arbuscular mycorrhizal fungi: Molecular and developmental responses in plants and their regulation by ethylene. Molecular Plant-Microbe Interactions, 24(2), 260-270. Available at: https://doi.org/10.1094/mpmi-06-10-0146.

Nelson, D. W., & Sommers, L. (1973). Determination of total nitrogen in plant material 1. Agronomy Journal, 65(1), 109-112.

Olsen, S. R., & Sommers, L. E. (1982). Phosphorus. In: Methods of soil analysis, Agron. No. 9, Part 2-Chemical and microbiological properties, (ed.) Page, A.L (2nd ed., pp. 403-430). Madison, Wisconsin, USA: American Society of Agronomy.

Parniske, M. (2008). Arbuscular mycorrhiza: The mother of plant root endosymbioses. Nature Reviews Microbiology, 6(10), 763-775. Available at: https://doi.org/10.1038/nrmicro1987.

Patel, D., & Saraf, M. (2013). Influence of soil ameliorants and microflora on induction of antioxidant enzymes and growth promotion of Jatropha curcas L. under saline condition. European Journal of Soil Biology, 55, 47-54. Available at: https://doi.org/10.1016/j.ejsobi.2012.12.004.

Patreze, C. M., & Cordeiro, L. (2004). Nitrogen-fixing and vesicular–arbuscular mycorrhizal symbioses in some tropical legume trees of tribe Mimoseae. Forest Ecology and Management, 196(2-3), 275-285. Available at: https://doi.org/10.1016/j.foreco.2004.03.034.

Phillips, J. M., & Hayman, D. (1970). Improved procedures for clearing roots and staining parasitic and vesicular-arbuscular mycorrhizal fungi for rapid assessment of infection. Transactions of the British Mycological Society, 55(1), 158-161. Available at: https://doi.org/10.1016/s0007-1536(70)80110-3.

Raupach, G. S., & Kloepper, J. W. (1998). Mixtures of plant growth-promoting rhizobacteria enhance biological control of multiple cucumber pathogens. Phytopathology, 88(11), 1158-1164. Available at: https://doi.org/10.1094/phyto.1998.88.11.1158.

Rotaru, V., & Sinclair, T. R. (2009). Interactive influence of phosphorus and iron on nitrogen fixation by soybean. Environmental and Experimental Botany, 66(1), 94-99. Available at: https://doi.org/10.1016/j.envexpbot.2008.12.001.

Ruiz-Lozano, J. M., Porcel, R., Azcón, C., & Aroca, R. (2012). Regulation by arbuscular mycorrhizae of the integrated physiological response to salinity in plants: New challenges in physiological and molecular studies. Journal of Experimental Botany, 63(11), 4033-4044. Available at: https://doi.org/10.1093/jxb/ers126.

Sakamoto, K., Ogiwara, N., & Kaji, T. (2013). Involvement of autoregulation in the interaction between rhizobial nodulation and AM fungal colonization in soybean roots. Biology and Fertility of Soils, 49(8), 1141-1152. Available at: https://doi.org/10.1007/s00374-013-0804-8.

Samal, K. C., & Rout, G. R. (2018). Genetic improvement of vegetables using transgenic technology. In: Genetic engineering of horticultural crops (pp. 193-224): Academic Press.

Sathiyabama, M., & Balasubramanian, R. (2018). Protection of groundnut plants from rust disease by application of glucan isolated from a biocontrol agent Acremonium obclavatum. International Journal of Biological Macromolecules, 116, 316-319. Available at: https://doi.org/10.1016/j.ijbiomac.2018.04.190.

Schüβler, A., & Walker, C. (2010). The glomeromycota: A species list with new families and genera. Edinburgh & Kew, UK, The Royal Botanic Garden; Munich, Germany: Botanische staatssammlung munich and oregon. USA: Oregon State University.

Senoo, K., Solaiman, M. Z., Kawaguchi, M., Imaizumi-Anraku, H., Akao, S., Tanaka, A., & Obata, H. (2000). Isolation of two different phenotypes of mycorrhizal mutants in the model legume plant lotus japonicus after EMS-treatment. Plant and Cell Physiology, 41(6), 726-732. Available at: https://doi.org/10.1093/pcp/41.6.726.

Sharma, K. K., & Bhatnagar-Mathur, P. (2006). Peanut (arachis hypogaea L.), In: Agrobacterium protocols. Methods in molecular biology, (ed.) wang, K (Vol. 343, pp. 347-358). New Jersey: Springer.

Sheng, M., Tang, M., Chen, H., Yang, B., Zhang, F., & Huang, Y. (2008). Influence of arbuscular mycorrhizae on photosynthesis and water status of maize plants under salt stress. Mycorrhiza, 18(6-7), 287-296. Available at: https://doi.org/10.1007/s00572-008-0180-7.

Singh, P. K. (2012). Role of glomalin related soil protein produced by arbuscular mycorrhizal fungi: A review. Academic Research Journal of Agricultural Science, 2(3), 119-125.

Smith, S. E., & Read, D. J. (2008). Mycorrhizal symbiosis. San Diego, CA: Academic Press, Inc.

Smith, S. E., Facelli, E., Pope, S., & Smith, F. A. (2010). Plant performance in stressful environments: Interpreting new and established knowledge of the roles of arbuscular mycorrhizas. Plant and Soil, 326(1-2), 3-20. Available at: https://doi.org/10.1007/s11104-009-9981-5.

Smith, S. E., Jakobsen, I., Grønlund, M., & Smith, F. A. (2011). Roles of arbuscular mycorrhizas in plant phosphorus nutrition: Interactions between pathways of phosphorus uptake in arbuscular mycorrhizal roots have important implications for understanding and manipulating plant phosphorus acquisition. Plant Physiology, 156(3), 1050-1057. Available at: https://doi.org/10.1104/pp.111.174581.

Takeda, N., Tsuzuki, S., Suzaki, T., Parniske, M., & Kawaguchi, M. (2013). CERBERUS and NSP1 of Lotus japonicus are common symbiosis genes that modulate arbuscular mycorrhiza development. Plant and Cell Physiology, 54(10), 1711-1723. Available at: https://doi.org/10.1093/pcp/pct114.

Thangella, P., Pasumarti, S., Pullakhandam, R., Geereddy, B., & Daggu, M. (2018). Differential expression of leaf proteins in four cultivars of peanut (arachis hypogaea L.) under water stress. 3 Biotech, 8(3), 157-157. Available at: https://doi.org/10.1007/s13205-018-1180-8.

Tian, C., Kasiborski, B., Koul, R., Lammers, P. J., Bücking, H., & Shachar-Hill, Y. (2010). Regulation of the nitrogen transfer pathway in the arbuscular mycorrhizal symbiosis: Gene characterization and the coordination of expression with nitrogen flux. Plant Physiology, 153(3), 1175-1187. Available at: https://doi.org/10.1104/pp.110.156430.

Van der Putten, W. H., Klironomos, J. N., & Wardle, D. A. (2007). Microbial ecology of biological invasions. The ISME Journal, 1(1), 28-37.

Walkley, A. (1947). A critical examination of a rapid method for determining organic carbon in soils—effect of variations in digestion conditions and of inorganic soil constituents. Soil Science, 63(4), 251-264. Available at: https://doi.org/10.1097/00010694-194704000-00001.

Weatherley, P. (1950). Studies in the water relations of the cotton plant. I. The field measurement of water deficits in leaves. New Phytologist, 49(1), 81-97. Available at: https://doi.org/10.1111/j.1469-8137.1950.tb05146.x.

Wu, Q.-S., Zou, Y.-N., & He, X.-H. (2010). Contributions of arbuscular mycorrhizal fungi to growth, photosynthesis, root morphology and ionic balance of citrus seedlings under salt stress. Acta Physiologiae Plantarum, 32(2), 297-304. Available at: https://doi.org/10.1007/s11738-009-0407-z.

Xie, Z.-P., Staehelin, C., Vierheilig, H., Wiemken, A., Jabbouri, S., Broughton, W. J., . . . Boller, T. (1995). Rhizobial nodulation factors stimulate mycorrhizal colonization of nodulating and nonnodulating soybeans. Plant Physiology, 108(4), 1519-1525. Available at: https://doi.org/10.1104/pp.108.4.1519.

Yol, E., Furat, S., Upadhyaya, H. D., & Uzun, B. (2018). Characterization of groundnut (Arachis hypogaea L.) collection using quantitative and qualitative traits in the Mediterranean Basin. Journal of Integrative Agriculture, 17(1), 63-75.

Zai, X., Qin, P., Wan, S., Zhao, F., Wang, G., Yan, D., & Zhou, J. (2007). Effects of arbuscular mycorrhizal fungi on the rooting and growth of beach plum (Prunus maritima) cuttings. The Journal of Horticultural Science and Biotechnology, 82(6), 863-866. Available at: ttps://doi.org/10.1080/14620316.2007.11512319.

Zhu, Y.-G., Smith, S. E., Barritt, A., & Smith, F. A. (2001). Phosphorus (P) efficiencies and mycorrhizal responsiveness of old and modern wheat cultivars. Plant and Soil, 237(2), 249-255.

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