Document Type : Research papers
Authors
1 Department of Soil and Water, Faculty of Agriculture, University of Bani walid-Libya.
2 Department of Soil and Agricultural Chemistry, Faculty of Agriculture, Saba Bash, Alexandria University Egypt
Abstract
Keywords
Main Subjects
Introduction
Barley (Hordeum vugareL.) is the major cereal crops in many dry areas of the Middle East, North Africa and west Asia (Ceccerelli et al., 1987). Its distribution is worldwide and is of considerable economic importance for animal feed and human consumption. Throughout the world around, 80% of the grown barley is used to feed animals (Amri et al. 2005).
Berseem or Egyptian clover (Trifolium alexandrinum L.) is an annual legume that is a vine with climbing growth habit, great productivity due to its high growth rate and good fodder recovery after cutting, and high levels of crude protein. It is well adapted to a range of environments and is usually grown in the Mediterranean, central European, and Southeast Asian Countries for forage production (El-Bably, 2002; De Santis et al., 2004).
Cobalt is required by Rhizobia for nitrogen fixation and indirectly by leguminous and other plants (Riley and Dillwarth, 1985). On the other hand, low concentrations of cobalt can have a favorable effect on plant growth of non-leguminous crops (Walser et al., 1996). Cobalt affects metabolism and plant growth and is an essential component of several enzymes and co-enzymes (Palit et al., 1994). Its beneficial effects include retardation of leaf senescence, inhibition of ethylene biosynthesis, and stimulation of alkaloid biosynthesis (Palit et al., 1994).
There are three main methods of adding micronutrients to crops: soil fertilization, foliar sprays and seed treatment. Atta-Aly (1998) found that soaking summer squash (Cucurbita pepo cv. Esksandarany) seed in continuously aerated solution of 0.25, 0.50, and 1.00 ppm Co2+ for 48 h before sowing strongly increased plant growth, femaleness, and fruit yield compared with those of water- (control) or 0.5 mM amino Oxyacetic acid soaked seed. In the same line, Atta-Aly (2003) reported that soaking Galia melon (Cucumis melo var. reticulatus, c.v. Royal) seed in continuously aerated solution of 1.00 ppm Co2+ for 48 h before sowing significantly increased ethylene (C2H4) level, plant growth and fruit yield compared with those of water- soaked seeds.
Arbuscular mycorrhizal fungi (AMF) play an important role in vegetation restoration because of symbiosis with plant root; they can facilitate mineral absorption by host plant, stability and improve soil structure, affect the population structure and preserve species diversity (Bothe et al., 2010).
Gad et al., (2012) studied the effect of cobalt and mycorrhizae (Gigaspora gigantean) on growth and yield of corn as monocots and soybean as dicots. The seedling (at the third truly leaf) were irrigated with cobalt sulphate once, with 0, 4, 8, 10, 12, 16 and 20 ppm cobalt. They found that the cobalt with mycorrhizae inoculation under low phosphorus level enhanced the growth, yield quantity and quality in both corn and soybean, but this positive impact was more significant in the dicot plants compared to monocot.The aim of this research was to study the effect of cobalt application using soaking seed method and mycorrhizal fungi inoculation on growth and nutrients content of barley (non-legumes) and Egyptian Clover (legumes) grown on calcareous soil.
Materials and Methods
Soil
Surface calcareous soil sample (0-15cm) was collected from Al-Hamam region at the northern western coast of Egypt. The soil sample was air dried ground to pass 2 mm sieve and thoroughly mixed before using. The characteristics of this soil are presented in Table (1). Practical size distribution was determined by the hydrometer method according to Black (1965). Field capacity was measured by saturated the soil samples through capillary rise then pull the gravitational water from the samples and drying at 105oC for 24 hours as reported by Black et al. (1965). Soil organic matter was determined by Walkley and Black method according to Jackson (1973). The water soluble Ca2+, Mg2+, HCO-3, Cl-, pH and EC in the soil were measured according to Jackson (1967). The calcimeter method was used to determine the total carbonates volumetrically (Black, 1965). The amounts of available nitrogen and potassium were determined according to Jackson (1967), that of phosphorus was determined as described by Murphy and Riley (1962), and that of cobalt was determined using the methods of Lindsay and Norvell (1978).
Table (1). The main physical and chemical properties of the experimental soil
|
Soil property |
Particle size distribution |
Soil moisture content |
|||||||||||
|
Physical |
Sand % |
Silt% |
Clay% |
Texture |
F.C % (w:w) |
||||||||
|
73 |
14 |
13 |
Silty loam |
20 |
|||||||||
|
Chemical |
pH (1:1) |
EC(dSm-1) (1:1) |
CaCO3,% |
O.M (%) |
|||||||||
|
8.0 |
2.14 |
19.95 |
1.06 |
||||||||||
|
Water soluble cation (meq/l) |
Water soluble anion (meq/l) |
||||||||||||
|
Ca2+ |
Mg2+ |
K+ |
Na+ |
HCO3- |
CO3- |
SO42- |
Cl- |
||||||
|
7.0 |
2.5 |
0.87 |
13.1 |
4.00 |
- |
5.08 |
14.00 |
||||||
|
Available nutrients (mg/kg soil) |
|||||||||||||
|
N |
P |
K |
DTPA-Co |
||||||||||
|
60 |
7 |
185 |
0.196 |
||||||||||
Seed soaking in cobalt solutions
The seeds of barley or clover were soaked for 48 h at room temperature in continuously aerated solutions of 0.00 (distilled water), 0.3, 0.6. 0.9, 1.2 and 1.5 mg L-1 Co2+ using cobalt sulphate salts as described by Atta-Aly (1998). By the end of soaking, the seeds were radicated with a ridacle length of 1-1.5 mm and were directly sown.
Experimental procedures
Two pot experiments were carried out at the green-house of Faculty of agriculture (Saba Basha), Alexandria University to study the effect of cobalt applied with seeds through soaking in relation to mycorrhiza inoculation (Glomus macrocarpium (G.M) or Glomus intraradiaces (G.I)) on the growth and quality of barely crop (Hordeum vulgare,L.) during 2012-2013 growing season and on Egyptian Clover (Trifolum alexandarinum,L.) during 2013-2014 growing season under calcareous soil conditions. Plastic pots (12.5 cm diameter and 11.5 cm depth) were filled with 1 kg calcareous soil for each pot.The barley and E. Clover were fertilized by recommended dose of super phosphate (15% P2O5), which was added and mixed with soil in each pot during the preparation of the experimental soil at the rate of (90 and 200 kg P2O5/fed) respectively, while N fertilizer was added in the form of (NH4NO3, 33% N) at the rate of (100 and 50 kg N/fed) in three equal dose, and K fertilizer was added in the form of K2SO4 (K2O 50%), at the rate of (50 and 100 kg/fed) for barley and clover, respectively. Five gramsof mycorrhiza (about 500 spores) inoculate (mycorrhiza spores with sand) was applied in a hole under the seeds before planting. Ten seeds bed of barely or clover were sown in each pot in holes and the seedlings were thinned to six plants per pot after three weeks from sowing. The seeds of Egyptian clover (Balady 1) were inoculated prior sowing with the specific strain of rhizobium leguminosarum. Soil moisture content was monitored at 80% of field capacity daily by distilled water. The cobalt (the main plot) and arbuscular-mycorrhizal (AM) species (the sub plot) treatments for the experiment were distributed in complete randomized block design with three replicates. At the harvest time (50, 47 days after planting of barley and clover, respectively), the plant height and number of leaves were measured. Also, samples of soil were collected from each pot and available cobalt was determined (Lindsay and Norvell, 1978).
Morphological root parameters
Plant roots were removed from each pot and separated from soil by washing under a jet of tap water on a 0.5 mm sieve. Excess moisture was blotted from the cleaned roots by wrapping up the roots in layers of paper towel for 3 min (Schenk and Barber, 1979). For each pot three samples of 0.3 g fresh weight were used for the determination of root length by the line intersect method of Tannant (1975).
Where:
RL= root length, N = sum of horizontal and vertical crossing,
G= length of the grid unit (2cm or 1cm).
Surface area of a 1cm root cylinder (SAC) was calculated as follows:
Where SAC = surface area of the root cylinder and r0 = root radius
Estimation of root radius (r0) (cm) was based on the assumption thatthe specific weight of root is almost equal to that of water,1 g cm-1(Barber 1995).
Where RFW = root fresh weight (g) and RL = root length (cm) and r0 = root radius
Mean half distance between neighbouring roots (r1) was calculated according to (Schenk and Barber, 1979):
Where V = volume of the soil in the pot (cm3) and RL= root length per pot
Plant analyses
Samples of shoots were measured from each pot and weighed, washed with running tap water and then with distilled water .The samples were air dried for few hours, and weight was measured, then oven dried at 65oC for 48 hours and grounded after recording the oven-dry weight of shoots. After dryness, the plant samples were ground by mill well and 0.5g of oven-dried plant materials were digested with H2SO4-H2O2 digest (Lowther, 1980) and the digested solutions, were analysed for total nitrogen, phosphorus, potassium and cobalt. Total N was determined colorimetrically by Nessler method (Chapman and Pratt, 1961). The vanado molydate colorimetric method was used to measure P in the digested plant samples (Jackson, 1967) using spectrophotometer at 480 nm wave length. Cobalt concentration was determined in the digested solution (Jackson, 1967) using the atomic absorption spectrophotometer (Model SpectrAA-200).
The obtained data were statistically analyzed according to the technique of analysis of variance (ANOVA) and the least significant difference (L.S.D) method was calculated to test the difference between the treatment means, as described by Gomez and Gomez (1984).
Results and Discussion
1. Barley and E. Clover growth parameters
A. Shoot growth
The results presented in Table (2) revealed that soaking barley and E. clover seeds in cobalt solutions and mycorrhizal inoculation had significant effects on shoot height, shoot fresh and dry weights and number of leaves.
Increasing cobalt concentration up to 0.6 mg/l in soaking solution for barley shoot growth parameters produced the highest plant length (48.33cm), shoot fresh and dry weights (2.23 and 0.77g), and number of leaves/ plant (10.4). Conversely, increasing cobalt concentration up to 1.5ppm in soaking solution showed the lowest values (45.5, 6.92, 1.38 g and 0.58 g) for shoot height, number of leaves, shoot fresh and dry weights of barley, respectively. Cobalt promotes many developmental processes including stem and coleoptiles elongation, opening of hypocotyls hooks, leaf disc expansion and feet development (Ibrahim et. al., 1989). It is clear from Table (2) that there were highly significant positive interaction effects between cobalt concentrations and mycorrhizal species on shoot height, shoot fresh and dry weight of barley and E. Clover plants.
Table (2). The main effects of cobalt concentrations and Mycorrhizae on shoot growth parameters of barley and E. Clover plants
|
Treatments |
Shoot height (cm/ plant) |
No.of leaves/ plant |
Shoot fresh weight (g/plant) |
Shoot dry weight (g/plant) |
|||||
|
Barley |
E. Clover |
Barley |
E. Clover |
Barley |
E. Clover |
Barley |
E. Clover |
||
|
Cobalt concentration, mg/l (A) |
|||||||||
|
Control |
46.92d |
50.50e |
8.01ab |
55.55b |
1.59d |
2.11c |
0.63d |
0.514d |
|
|
0.3 |
47.56c |
53.14d |
9.04b |
58.5ab |
1.79c |
2.18bc |
0.72c |
0.615c |
|
|
0.6 |
48.33a |
53.30cd |
10.36a |
59.23ab |
2.23a |
2.19bc |
0.77a |
0.618c |
|
|
0.9 |
48.06ab |
54.30ab |
9.55a |
61.75ab |
2.01b |
2.83a |
0.75ab |
0.684b |
|
|
1.2 |
47.61bc |
54.78a |
9.32ab |
62.19a |
1.8c |
2.87a |
0.73bc |
0.713a |
|
|
1.5 |
45.5e |
53.96bc |
6.92b |
59.25ab |
1.38e |
2.26b |
0.58e |
0.675b |
|
|
Mycorrhizal inoculation (B) |
|||||||||
|
Control |
45.64c |
51.37c |
7.14b |
52.16c |
1.34c |
1.6c |
0.59c |
0.581c |
|
|
G.M |
47.52b |
53.95b |
7.66b |
59.55b |
1.67b |
2.7b |
0.64b |
0.639b |
|
|
G.I |
48.83a |
54.66a |
11.8a |
66.51a |
2.39a |
2.92a |
0.86a |
0.689a |
|
|
L.S.D 0.05 |
|||||||||
|
A |
0.35 |
0.54 |
ns |
4.64 |
0.04 |
0.10 |
0.02 |
0.008 |
|
|
B |
0.50 |
0.77 |
2.41 |
6.56 |
0.05 |
0.144 |
0.03 |
0.012 |
|
|
AxB |
0.85 |
1.34 |
ns |
ns |
0.092 |
0.25 |
0.046 |
0.021 |
|
*The values in each column followed by the same letter are not significant at 0.05 probability level
These results are in accordance with those obtained by Abd-Elgawad et al. (2014) and Gad and Abdel- Moez (2015). Previous studied have shown that cobalt also promotes the growth of seedlings and alleviates the senescence of aged tissues as it inhibits the activities of ACC oxidase and reduced ethylene production (Lau and Yang, 1976). On the other hand, increasing cobalt concentration for E. Clover shoot growth parameters, in soaking solution up to 1.2 mg/l, produced the highest shoot (54.78 cm); massive shoot fresh weight (2.87g) and heaviest shoot dry weight (0.713g). Also, this concentration showed the highest number of leaves/plant (62.19), but without significant difference with other concentrations (Atta-Aly et al., 1998). On the other hand, soaked E. Clover seeds in solution without cobalt gave the shortest shoot (50.50 cm), lowest number of leaves/plant (55.55( and lightest shoot dry weight (0.514g). It is obvious that Co is an essential element for legumes because of its use by microorganisms in fixing atmospheric nitrogen (Evan and Kliwer, 1964). These results are in accordance with those obtained b Abdul Jaleel et al. (2009); and Gad and El-Metwally (2015).
Regarding mycorrhizal effect on barley and E. Clover shoot growth parameters, the results in Table (2) showed that treated barley and E. Clover seeds with mycorrhizae, significantly increased all the studied growth parameters as compared with the (control). It has been recognized that Arbuscular mycorrhizal (AM) fungi plays an essential role for nutrient uptake of the majority of plants, including many important crop species. The extraradical mycelium of the fungus takes up nutrients from the soil, transfers these nutrients to the intraradical mycelium within the host root, and exchanges the nutrients against carbon from the host across a specialized plant-fungal interface (Bücking and Kafle 2015). These results agreed with those reported by Bano and Ashfag (2013) and Abou Elseoud (2008). On the other hand, G. intraradiaces was more efficient than G. macrocarpium for the studied growth parameters of barley and E. Clover plants. Similar results were reported by Banni and Faituri (2013) who reported that plants treated with G. intraradiaces had higher mycorrhizal colonization rate and was more effective than G. macrocarpium–treated plants.
B. Root growth parameter
The main treatment effects, including cobalt concentration in soaking solution and inoculated barley and E. Clover seeds has exhibited significant trend on all root growth parameters, Table (3). The data also showed that treated barley seeds with 0.6 mg/L cobalt produced the heaviest root fresh and dry weights (2.40 and 0.52g), longest roots length (1069.39cm) and highest root surface (187.61 cm2). Additional data revealed that soaking barley seeds in solutions contained the highest studied cobalt concentration (1.5 mg/L) showed maximum root radius (0.028cm) and longest distance between roots (0.572cm). These results are generally confirmed with those reported by Helmy and Gad (2002), and Gad and El-Metwally (2015). However, Atta-Aly et al. (1989) found that supplementing the nutrient solution with a concentration of 0.5 mg/L Co2+ or less significantly induced ethylene production and adventitious root formation of tomato and squash cuttings. On the other hand, the results in Table (3) pointed out that the heaviest root fresh weight (1.18 g), dry weight (0.61g), longest root length (875.25 cm) and highest root surface area (113.06 cm2) of E. Clover plants was due to treatment by 1.2mg/L Co2+. Besides, the thickest root (0.23cm) and widest distance between roots (0.61cm) resulted from applied 0.6 mg/L cobalt and without cobalt application to soaking solution, respectively. However, soaking seeds of E. Clover seeds in solution without cobalt showed the lowest root fresh weight (0.81) and dry weight (0.184), shortest root (619.30cm) and lowest root surface (79.65cm2). Occonner (1992) showed that soybean grown without cobalt exhibited severe nitrogen deficiency, leading the death in about one of four plants. These results are in accordance with those obtained by Atta-Aly (2003). As shown in Table (3) there were highly significant positive interaction effect between cobalt concentration and mycorrhizal species on root fresh weight, root dry weight, root length, root radius and root surface for both two plants.
Table (3). The main effect of cobalt concentrations and Mycorrhizae on root growth parameters of barley and E. Clover plants
|
Treatments |
Root fresh weight (g/plant) |
Root dry weight (g/plant) |
Root length (cm/plant) |
Root radius (cm) |
Mean half distance between roots |
Root surface (cm2/ plant) |
||||||
|
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
|
|
Cobalt concentration, mg/l (A) |
||||||||||||
|
Control |
1.89c |
0.81d |
0.42c |
0.18d |
1004.29b |
6.19.30e |
0.0248b |
0.02bc |
0.497b |
0.61a |
153.67c |
79.65e |
|
0.3 |
2.24b |
1.01c |
0.43c |
0.41c |
1011.97b |
677.29d |
0.0264ab |
0.21b |
0.491b |
0.57b |
168.38bc |
92.69d |
|
0.6 |
2.4a |
1.04b |
0.52a |
0.42c |
1069.39a |
737.15c |
0.0254ab |
0.23a |
0.4451b |
0.55c |
187.61a |
104.02c |
|
0.9 |
2.3b |
1.17ab |
0.51a |
0.53b |
1053.58b |
851.45a |
0.0265ab |
0.02b |
0.469bc |
0.51de |
174.85ab |
109.35ab |
|
1.2 |
2.3b |
1.18a |
0.46b |
0.61a |
1042.67b |
875.25a |
0.0260ab |
0.019c |
0.472bc |
0.51e |
170.89abc |
113.06a |
|
1.5 |
1.66d |
1.16ab |
0.38d |
0.52b |
739.4c |
808.05b |
0.0275a |
0.029b |
0.572a |
0.53d |
122.96d |
107.67bc |
|
Mycorrhizal inoculation (B) |
||||||||||||
|
Control |
1.7c |
0.95c |
0.37c |
0.196c |
775.35c |
685.47c |
0.0268a |
0.020b |
0.554a |
0.58a |
127.88c |
92.73c |
|
G.M |
1.83b |
1.07b |
0.42b |
0.528b |
938.63b |
759.12b |
0.0251a |
0.021ab |
0.499b |
0.55b |
146.38b |
101.09b |
|
G.I |
2.87a |
1.21a |
0.57a |
0.623a |
1296.68a |
839.66a |
0.0264a |
0.021a |
0.422c |
0.52c |
214.91a |
109.4a |
|
L.S.D 0.05 |
||||||||||||
|
A |
0.07 |
0.03 |
0.02 |
0.019 |
98.4 |
36.67 |
0.003 |
8.55 |
0.035 |
0.01 |
18.82 |
3.79 |
|
B |
0.05 |
0.02 |
0.01 |
0.013 |
69.61 |
25.93 |
0.002 |
6.04 |
0.025 |
0.01 |
13.3 |
2.68 |
|
AxB |
0.12 |
0.06 |
0.013 |
0.033 |
170.52 |
63.5 |
0.004 |
0.001 |
ns |
0.026 |
32.58 |
6.57 |
*The values in each column followed by the same letter are not significant at 0.05 probability level
As shown in Table (3), inoculated seeds barley and E. Clover with mycorrhizae generally increased significantly all the studied root parameters except root radius and mean half distance between roots compared to the other plants without mycorrhizal inoculation (control). Inoculation barley and E. Clover with G. intraradiaces (G.I) produced the heaviest root fresh and dry weights (2.87 and 0.57g), tallest root length (1296.68cm) and largest root surface (214.91 cm2) compared with the other mycorrhizal species (G. macrocarpium). Abou Elseoud (2005) and Puttaradder and Lakshman (2015) reported similar results. They found that mycorrhizal inoculation greatly influenced plant growth, root length, fresh and dry weight of shoots and roots. Also, Abou Elseoud (2008) showed that plants inoculation by mycorrhizal fungi significantly increased root length and root surface area compared to the control.
2. Barley and E. Clover macronutrients content
Considering cobalt concentrations and mycorrhizal inoculation effects on nitrogen, phosphorus and potassium contents and uptake by barley and E. Clover plants, results presented in Table (4) revealed that both studied factors had significant effects on the studied traits. With respect to cobalt concentrations in soaking solutions of barley plants, results showed that low concentration level (0.6 mg/L) produced the highest N, P and K plant contents (18.17, 10.05 and 45.43mg/ g d.m.) and uptake (16.9, 8.43 and 19.81 mg/ plant), respectively. Conversely, the highest cobalt concentration (1.5 mg/L) showed the lowest N, P and K contents in barley plant (9.38, 3.85 and 32.65 mg/ g d.m) and uptake (4.35, 2.07 and 18.3mg/ plant), respectively. Gad and Azize (2011) and Atiia et al. (2016) reported similar results. On the other hand, results in Table (4) pointed out that applied 1.2mg cobalt /L to soaking solution produced the highest N, P and K content in E. clover plants (24.89, 11.75 and 28.96 mg/g d.m.) and uptake (16.9, 8.43 and 19.81 mg/plant), respectively. However, the lowest values due to soaking solution without cobalt the (control). Cobalt had positive effect due to several induced effects in hormonal synthesis (auxin and gibberellin contents) and metabolic activity resulted in maximum growth and yield of tomato, and increase the activity of some enzymes i.e. peroxidase and catalase in plant and hence increasing the catabolism rather than anabolism (Gad, 2005). As shown in Table (4) there were highly significant interaction effect between cobalt concentrations and mycorrhizal species on N, P, and K content and uptake of both two plants.
Table (4). The main effects of cobalt concentrations and Mycorrhizae on N, P and K content and uptake of barley and E. Clover plants
|
Treatments |
N content (g/kg d.m) |
P content (mg/g d.m) |
K content (mg/g d.m) |
N uptake (mg/plant) |
P uptake (mg/plant) |
K uptake (mg/plant) |
||||||
|
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
|
|
Cobalt concentration, mg/l (A) |
||||||||||||
|
Control |
10.4e |
15.95d |
4.94d |
2.53e |
34.39d |
23.16d |
5.18e |
5.70d |
3.0e |
1.10d |
19.85e |
9.59d |
|
0.3 |
11.99d |
19.24c |
5.23d |
4.02d |
35.25d |
24.35cd |
7.23d |
9.93c |
3.61d |
2.26cd |
21.49d |
13.49c |
|
0.6 |
18.17a |
21.86b |
10.05a |
4.82cd |
45.43a |
24.81c |
13.51a |
11.64c |
8.13a |
2.84c |
33.09a |
14.10c |
|
0.9 |
14.83b |
23.96a |
7.88b |
6.46b |
42.64b |
27.55b |
10.3b |
15.07ab |
6.17b |
4.39b |
30.26b |
17.95b |
|
1.2 |
13.55c |
24.89a |
6.45c |
11.75a |
39.42c |
28.96a |
9.3c |
16.9a |
4.42c |
8.43a |
27.67c |
19.81a |
|
1.5 |
9.38f |
22.57b |
3.85e |
5.49c |
32.65e |
26.55b |
4.35f |
13.69b |
2.07f |
3.57bc |
18.30f |
16.77b |
|
Mycorrhizal inoculation (B) |
||||||||||||
|
Control |
8.03c |
17.97c |
2.76c |
3.30c |
30.83c |
23.46c |
3.57c |
6.83c |
1.45c |
1.54c |
16.91c |
10.83c |
|
G.M |
11.34b |
21.66b |
5.17b |
5.89b |
35.92b |
25.54b |
5.87b |
13.01b |
3.0b |
3.77b |
20.95b |
15.63b |
|
G.I |
19.60a |
24.61 |
11.27a |
8.36a |
48.15a |
28.68a |
15.48a |
16.63a |
9.24a |
5.99a |
37.68a |
19.41a |
|
LSD.05 |
||||||||||||
|
A |
0.57 |
1.31 |
0.36 |
0.94 |
1.34 |
1.32 |
0.39 |
1.91 |
0.22 |
1.40 |
1.21 |
1.32 |
|
B |
0.4 |
0.92 |
0.26 |
0.66 |
0.95 |
0.94 |
0.28 |
1.35 |
0.15 |
0.99 |
0.85 |
0.94 |
|
AxB |
0.98 |
2.27 |
0.062 |
1.63 |
2.33 |
2.30 |
0.68 |
3.31 |
0.37 |
2.42 |
2.08 |
2.30 |
*The values in each column followed by the same letter are not significant at 0.05 probability level
Results presented in Table (4) showed that uninoculated barley and E. Clover seeds with mycorrhizae showed the lowest N, P, and K plant content and uptake respectively. However, inoculated seeds with G.intraradiaces showed a significant highest N, P and K content and uptake compared to the other plants inoculated with G. macrocarpium. Mycorrhizal plants roots hyphae can increase the branching of root system in rhizosphere so that mycorrhizal plants roots have more absorption efficiency compared to non-mycorrhizal ones. These results are in agreement with those found by Nourinia et al. (2007) and Robinson et al. (2014).
3. Cobalt contents in barley and E. Clover plants
Table (5) indicated that cobalt contents in shoot, root and whole barley and E. Clover plants were significantly affected by cobalt concentrations in soaking solution and mycorrhizal inoculation.
The results, showed that, applied 1.5 mg / L cobalt to soaking solution produced the highest amount of available cobalt in soil (0.17 and 0.21 mg/ kg soil); and in total shoot cobalt contents (4.99 and 1.81 mg/g d.m); root cobalt contents (7.51 and 17.81 mg/g d.m) and total plant cobalt contents (12.51 and 19.62 mg/g d.m) for barley and E. Clover plants, respectively.
Conversely, the control treatment produced the lowest cobalt in shoot, root and plant content. Similarly, Gad and Abdel-Moez (2015) reported that cobalt content in fenugreek grains significantly increased with increasing cobalt concentration in plant growing in media as compared to the control.
Concerning mycorrhizal effect, results presented in Table (5) revealed that inoculation both barley seeds and E. Clover seeds with G. intraradiaces showed the highest amount of available cobalt (0.17 and 0.25 mg/ kg soil); shoot cobalt contents (3.88 and 2.03 mg/g d.m), root cobalt contents (7.16 and 14.99 mg/g d.m) and total plant cobalt contents (11.05 and 17.01 mg/g d.m.) for the two plants, respectively as compared to the other mycorrhizal species (G. macrocarpium).
However, the lowest cobalt content resulted from unicoculated seeds. It can be seen from Table (5) that there were highly significant positive interaction effect between cobalt concentrations and mycorrhizal species on available Co2+ in soil, shoot Co2+, root Co2+and plant cobalt content for both barley and E. Clover plants.
Table (5). The main effects of cobalt concentrations and Mycorrhizae on available cobalt in soil and cobalt content of barley and E. Clover plants
|
Treatments |
Available Co2+ (mg/ kg soil) |
Shoot Co2+content (mg/ kg d.m) |
Root Co2+ content (mg/ kg d.m) |
Plant Co+2 content (mg/ kg d.m) |
||||||
|
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
Barley |
E.Clover |
|||
|
Cobalt concentration, mg/l (A) |
||||||||||
|
Control |
0.135c |
0.02e |
0.22e |
0.11d |
0.43d |
0.74e |
0.65d |
0.85e |
||
|
0.3 |
0.15bc |
0.02e |
0.23d |
0.14c |
0.45cd |
0.93d |
0.68d |
1.07d |
||
|
0.6 |
0.15abc |
0.03d |
0.25c |
0.16b |
0.51bc |
1.11c |
0.76c |
1.28c |
||
|
0.9 |
0.16ab |
0.11c |
0.25c |
0.17ab |
0.55b |
1.23b |
0.81bc |
1.40b |
||
|
1.2 |
0.16ab |
0.18b |
0.31b |
0.17ab |
0.56b |
1.27b |
0.88b |
144b |
||
|
1.5 |
0.17a |
0.21a |
0.49a |
0.18a |
0.75a |
1.78a |
1.25a |
1.96a |
||
|
Mycorrhizal inoculation (B) |
||||||||||
|
Control |
0.13c |
0.01c |
0.20c |
0.09c |
0.37c |
0.93c |
0.57c |
1.02c |
||
|
G.M |
0.15b |
0.03b |
0.29b |
0.17b |
0.55b |
1.11b |
0.84b |
1.29b |
||
|
G.I |
0.17a |
0.25a |
0.38a |
0.20a |
0.71a |
1.49a |
1.11a |
1.70a |
||
|
LSD.05 |
||||||||||
|
A |
0.01 |
0.006 |
0.009 |
0.01 |
0.07 |
0.045 |
0.075 |
0.04 |
||
|
B |
0.015 |
0.004 |
0.006 |
0.009 |
0.05 |
0.031 |
0.053 |
0.03 |
||
|
AxB |
0.025 |
0.009 |
0.016 |
0.023 |
0.12 |
0.078 |
0.13 |
0.08 |
||
*The values in each column followed by the same letter are not significant at 0.05 probability level
Conclusion
It can be concluded that soaking seeds of barley and E. Clover in cobalt solution and mycorrhizal inoculation had significant effects on all growth parameters of the two plants. Moreover, the interaction was highly positive between cobalt concentrations and mycorrhizae species with both crops forge. Under the same experimental conditions, it can be recommended that G. intraradiaces was more effective than G. macrocarpium for the studied traits. Also, the recommended cobalt concentration for barley crops was lower (0.6 mg/l) than that for E. Clover (1.2mg/l) since legume plants needs cobalt supply for enhancing nitrogen fixation in all Rhizobium species and hence promotes legume growth.
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