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Indian Journal of Pure & Applied Biosciences (IJPAB)
Year : 2020, Volume : 8, Issue : 3
First page : (554) Last page : (560)
Article doi: : http://dx.doi.org/10.18782/2582-2845.8169
Ameliorative Effect of Sodium Nitroprusside and Trichoderma on Morpho-Physiological Character of Chickpea (Cicer arietinum L.) Genotypes under Drought Stress
Khushboo Gupta1* , Padmanabh Dwivedi2 and Pooja3
1Research Scholar, Department of Plant Physiology, 2Professor, Department of Plant Physiology,
3Research Scholar, Department of Agronomy
Institute of Agricultural Sciences, Banaras Hindu University, Uttar Pradesh, India
*Corresponding Author E-mail: lovablekhush98@gmail.com
Received: 13.06.2020 | Revised: 21.06.2020 | Accepted: 26.06.2020
ABSTRACT
Chickpea is very important food legume also it is the good source of carbohydrate (48.2-67.6%), starch (41-50%), protein (12.4-31.5%), fat (6%) as well as nutritionally important minerals. It is also used as a rotation crop as of its nitrogen fixing property. Drought stress is one of the most important abiotic stress disturbing plant growth and productivity worldwide. Grain legumes, in general, and chickpea, in particular, as compared to cereals seem to have more sensitivity towards drought stress. The present study was carried out during 2015-2016, in order to estimate drought tolerance in two chickpea genotypes (susceptible and tolerant), under both control and drought conditions and various parameters were recorded. The experiment was laid out in randomized block design with three replications. Drought stress is created by applying PEG 10%. PEG 10% reduced most of the morpho-physiological attributes, but plants could sustain up drought stress when SNP and Trichoderma alone or in combination given.
Keywords: Drought stress, Chickpea, SNP, Trichoderma.
Full Text : PDF; Journal doi : http://dx.doi.org/10.18782
Cite this article: Gupta, K., Dwivedi, P., & Pooja (2020). Ameliorative Effect of Sodium Nitroprusside and Trichoderma on Morpho-Physiological Character of Chickpea (Cicer arietinum L.) Genotypes under Drought Stress, Ind. J. Pure App. Biosci. 8(3), 554-560. doi: http://dx.doi.org/10.18782/2582-2845.8169
INTRODUCTION
Chickpea is a crucial food legume which will be grown under a varied range of environments. It is well identified as a drought tolerant crop that performs well in low input agriculture and is taken into account as the second important leguminous crop in the world. The agri-food importance of chickpeas is associated to its great richness in proteins: 25.3 to 28.9% (Hulse, 1991). This leguminous crop is taken into account as substitute source of proteins for human nutrition (Tejera et al., 2006). Smita and Nayyar (2005) witnessed reduction in root length of Cicer arietinum under water stress and detrimental effects may be because of reduction in root-hair diameter as well as distortion and plasmolysis, therefore rendering the uptake of accessible water by roots.
MATERIALS AND METHODS
1. Morphological and Growth Parameters
Root length (cm)
Root length is measured at 35 and 70 DAS in the net house in controlled and treated plants from the root-stem transition to the base of the root apex.
Shoot length (cm)
Shoot height or length of one plant, from each treatment and under each replication was measured in centimetre from the base of the plant to the growing tip of the main shoot with the help of a meter scale and expressed in cm. The shoot height of three plants (one from each replication) was averaged to obtain the height of per plant for each treatment.
Number of leaves plant-1
The number of leaves plant-1 was counted separately at 35 and 70 DAS in net house in controlled and treated plants of chick pea genotypes.
Root shoot length ratio
The ratio root of root and shoot length is measured at 35 and 70 DAS.
RESULTS
MORPHO-PHYSIOLOGICAL CHARACTERS
1. Length of root (cm)
The data on root length at different treatments under two growth periods (35 and 70 DAS) are presented in Fig. 1. There was a significant decrease in root length with 10% PEG treatment. Among treatments, the maximum reduction of 44.06% and 43.36% in root length (9.89 and 9.88 cm) was recorded at 35 DAS under drought stress in Pusa 262 and Pant G-114, respectively as compared to SNP and Trichoderma treatment. Our results are in accordance with the findings of several workers who reported decreased root length in various crops under heavy metal stress (Esmaeilian et al., 2011; Asgharipour et al., 2011; Shekar et al., 2011). Both treatments namely, SNP and Trichoderma alone or in combination of SNP and Trichoderma showed increasing root length as compared to both control and PEG 10%. Smita and Nayyar (2005) also observed reduction in root length of Cicer arietinum under water stress and detrimental effects could be due to reduction in root-hair diameter as well as distortion and plasmolysis.
Among treatments, maximum root length (20.23 and 19.57 cm) was observed with SNP and Trichoderma at 70 DAS, in both the varieties, Pusa 262 and Pant G-114 respectively. Effect of NO on growth parameters of plants under drought, heavy metal and salinity stress has been reported (Nasibi & Kalantari, 2009; Zhao et al., 2001; Singh et al., 2008). Reduction of root length under stress conditions may due to an impediment of cell division and elongation leading kinds of tuberization.
Table- 4.1.1. Effect of Drought stress, Sodium nitroprusside and Trichoderma on root length at two growth periods in Chickpea (Cicer arietinum L.)
TREATMENT |
GENOTYPE(G) |
|||
35DAS |
70DAS |
|||
PUSA 262 |
PANT G-114 |
PUSA 262 |
PANT G-114 |
|
P0S0T0 |
16.65 |
16.61 |
18.51 |
18.39 |
P1S0T0 |
9.89 |
9.88 |
10.81 |
10.73 |
P0S1T0 |
17.10 |
16.88 |
19.44 |
19.58 |
P0S0T1 |
17.63 |
17.21 |
19.98 |
19.28 |
P1S1T0 |
12.88 |
12.25 |
14.98 |
14.41 |
P1S0T1 |
13.53 |
13.03 |
15.65 |
14.95 |
P0S1T1 |
18.11 |
17.38 |
20.23 |
19.47 |
P1S1T1 |
16.94 |
16.43 |
18.77 |
18.26 |
|
SEM± |
CD 5% |
SEM± |
CD 5% |
G |
0.043 |
0.125 |
0.062 |
0.181 |
T |
0.086 |
0.25 |
0.125 |
0.362 |
G×T |
0.122 |
0.354 |
0.176 |
N/A |
P0 = No PEG treatment; P1= PEG treatment
S0= No SNP; S1 =SNP treatment
T0=No Trichoderma; T1= Trichoderma treatment
2. Length of shoot (cm)
The data on shoot length at different treatments under two growth periods (35 and 70 DAS) are presented in Fig. 2. There was a significant decrease in shoot length under drought stress. Among the treatments, the maximum 73.96% and 71.09% reduction (14.28 and 13.70 cm) in root length was observed at 35 DAS under drought stress in Pusa 262 and Pant G-114, respectively. Many studies have shown that there is significant decrease in shoot length under drought stress (Turkan et al., 2004; Tuna et al., 2010), Kavar et al. (2007).
According to Mohammadkhani and Heidari, (2008), all the upland rice varieties displayed significant reduction in shoot length at the most drought levels as compared with control. This reduction in growth might be due to low osmotic potential as well as a decrease in wall extensibility and cellular expansion.
Table-4.1.2. Effect of Drought stress, Sodium nitroprusside and Trichoderma on shoot length at two growth periods in Chickpea (Cicer arietinum L.)
TREATMENT |
GENOTYPE(G) |
|||
35DAS |
70DAS |
|||
PUSA 262 |
PANT G-114 |
PUSA 262 |
PANT G-114 |
|
P0S0T0 |
19.79 |
19.18 |
22.56 |
21.53 |
P1S0T0 |
14.29 |
13.70 |
16.78 |
16.81 |
P0S1T0 |
24.86 |
23.44 |
29.63 |
28.61 |
P0S0T1 |
23.13 |
22.91 |
26.81 |
25.71 |
P1S1T0 |
16.31 |
15.30 |
19.53 |
18.58 |
P1S0T1 |
17.23 |
16.40 |
20.30 |
19.63 |
P0S1T1 |
22.29 |
21.58 |
24.25 |
23.55 |
P1S1T1 |
20.85 |
19.72 |
23.37 |
22.17 |
|
SEM± |
CD 5% |
SEM± |
CD 5% |
G |
0.072 |
0.2088 |
0.081 |
0.234 |
T |
0.144 |
0.417 |
0.161 |
0.467 |
G×T |
0.203 |
N/A |
0.228 |
N/A |
3. Number of Leaves per plant
Data pertaining to number of leaves per plant at two growth periods (35 and 70 DAS) are presented in Fig.3. which elucidated that the treatments had significantly decreased number of leaves per plant in drought condition. Among the treatments, the maximum 57.45 and 58.81% decrease in number of leaves (40.14 and 38.37) per plant was observed at 35 DAS in Pusa 262 and Pant G-114, respectively in drought stress as compared to SNP and Trichoderma in combination. Similar result was observed by Ali et al. (2007) who indicated that the reduction in growth characters during stress may be due to water potential hampering nutrient uptake, reduction in meristem cells and oxidative stress.
Among treatments, SNP alone or in combination of Trichoderma, showed ameliorative effects at both the growth periods. Among treatments, maximum number of leaves per plant (140.49 and 139.47) was observed with SNP and Trichoderma at 70 DAS. The results of reduced leaf number in water deficit condition is similar to the findings of Khalil et al.(2010) in Ocimum basilicum. Similar result was observed by Shao et al. (2008) where reduction in leaf area index and number of leaves under water stress were perhaps due to decline in cell enlargement and more leaf senescence resulting from reduced turgor pressure.
Table- 4.1.3. Effect of Drought stress, Sodium nitroprusside and Trichoderma on number of leaf at two growth periods in Chickpea (Cicer arietinum L.)
TREATMENT |
GENOTYPE(G) |
|||
35DAS |
70DAS |
|||
PUSA 262 |
PANT G-114 |
PUSA 262 |
PANT G-114 |
|
P0S0T0 |
67.70 |
66.64 |
99.70 |
98.50 |
P1S0T0 |
40.14 |
38.37 |
67.11 |
66.18 |
P0S1T0 |
91.22 |
89.96 |
135.45 |
133.92 |
P0S0T1 |
87.65 |
86.54 |
120.11 |
119.11 |
P1S1T0 |
54.23 |
53.21 |
89.56 |
88.59 |
P1S0T1 |
57.42 |
56.26 |
92.33 |
91.31 |
P0S1T1 |
94.34 |
93.17 |
140.49 |
139.47 |
P1S1T1 |
71.53 |
70.47 |
110.47 |
109.12 |
|
SEM± |
CD 5% |
SEM± |
CD 5% |
G |
0.053 |
0.154 |
0.087 |
0.252 |
T |
0.106 |
0.309 |
0.174 |
0.504 |
G×T |
0.151 |
N/A |
0.245 |
N/A |
4. Root and Shoot Length ratio
Data pertaining to root shoot ratio at two growth periods (35 and 70 DAS) are presented in Fig. 4. which elucidated that the treatments had significantly decreased root shoot ratio under drought stress in both the varieties. Among the treatments, the maximum increase in root shoot length ratio was observed in control treatment at 35 DAS in both the varieties, which is followed by SNP and Trichoderma treatment in combination at 70 DAS.
Table- 4.1.4. Effect of Drought stress, Sodium nitroprusside and Trichoderma on root shoot length ratio at two growth periods in Chickpea (Cicer arietinum L.)
TREATMENT |
GENOTYPE(G) |
|||
35DAS |
70DAS |
|||
PUSA 262 |
PANT G-114 |
PUSA 262 |
PANT G-114 |
|
P0S0T0 |
0.840 |
0.867 |
0.820 |
0.854 |
P1S0T0 |
0.689 |
0.721 |
0.643 |
0.639 |
P0S1T0 |
0.688 |
0.720 |
0.656 |
0.683 |
P0S0T1 |
0.762 |
0.751 |
0.745 |
0.750 |
P1S1T0 |
0.789 |
0.801 |
0.767 |
0.775 |
P1S0T1 |
0.785 |
0.794 |
0.771 |
0.761 |
P0S1T1 |
0.812 |
0.805 |
0.833 |
0.827 |
P1S1T1 |
0.812 |
0.832 |
0.803 |
0.824 |
|
SEM± |
CD 5% |
SEM± |
CD 5% |
G |
0.004 |
0.011 |
0.003 |
N/A |
T |
0.008 |
0.023 |
0.007 |
0.019 |
G×T |
0.011 |
N/A |
0.009 |
N/A |
RESULT AND DISCUSSION
Drought stress is one of the major abiotic stresses affecting plant growth and productivity globally. Keeping this in mind, the present investigation was undertaken in net house of Institute of Agricultural Sciences, Banaras Hindu University, Varanasi during winter session 2015-2016 to study the influence of PEG 6000 (10%) either alone or in combination with SNP and Trichoderma in chickpea (Cicer arietinum L.). The experiment was laid out in Factorial Randomized Block Design (FRBD), which consisted of 8 treatments, 3 replication for each treatment, 2 varieties, and plants were subjected to these chemicals in the pots at two different growth periods- 35 and 70 DAS. The summary and conclusion obtained from the investigation are presented in this chapter. The salient finding of the investigation are summarized as under:
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