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Growth Responses of Vigna radiata to Arid Land Bacteria Exhibiting Antimicrobial Activity



Khushi Muhammad, Azra Yasmin, Hazir Rehman, Muhammad Faisal and Shahida Hasnain
 
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ABSTRACT

Twenty-four bacterial strains were isolated from rhizosphere and histoplane of four different arid plants, Trianthema partulacastrum, Rumex dentatus, Chenopodium morale and Coronopus didymus. These bacteria were inoculated to seeds of Vigna radiata var NM-92 which were germinated and grown for 15 days. Majority of strains had inhibitory effect on seed germination (2.2 to 13.0%). The increase in seedling length ranged from 17 to 38% with different inoculations. Bacterial strains TP1, TP3, TP4, RTP4 and RRD1 were the most effective ones for the different growth parameters such as seed length and seed weight whereas the most adverse effects were recorded with the inoculation of TP17 strain. Maximum increase in protein and auxin content was observed with strains TP5 and RCM2, respectively. Peroxidase and acid phosphatase showed maximum activity with the inoculation of strain TP1.

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  How to cite this article:

Khushi Muhammad, Azra Yasmin, Hazir Rehman, Muhammad Faisal and Shahida Hasnain, 2008. Growth Responses of Vigna radiata to Arid Land Bacteria Exhibiting Antimicrobial Activity. Research Journal of Environmental Sciences, 2: 139-144.

DOI: 10.3923/rjes.2008.139.144

URL: https://scialert.net/abstract/?doi=rjes.2008.139.144

INTRODUCTION

Bacteria are ubiquitous in their distribution and are present in water (Klaus et al., 2007), soil (Sager et al., 2007) and play an important role in soil quality (Hill et al., 2000) by increasing organic carbon and moisture level (Eaton, 2000). They are also essential for various functions such as plant growth promotion (Humphry et al., 2007), inhibition of plant pathogen (antimicrobial activity) (Cho et al., 2007), improvement of soil structures and leaching metal (Van Veen et al., 1997). Tillage reduction in agriculture soil has been reported by microbial mass and microbial density (Lupwayi et al., 2000). The plant species, type and development influenced the variation of microbial communities in soil and association with roots (Wieland et al., 2001). These bacteria produce antimicrobial agents which inhibit/promote the growth of plants in the soil (Casida and Lukezic, 1992). Bacterial strains that enhance plant growth under heavy metal stress have been reported by Faisal et al. (2005) and Faisal and Hasnain (2006). Microbes exhibiting the antimicrobial behavior can effect their host in different ways. Their effect may be stimulatory (Alami et al., 2000) or inhibitory (Li et al., 2007). Vigna radiata is an important cash crop of Pakistan. Keeping the association of antimicrobial activity and plant promoting ability of bacterial strains, twenty-four bacterial strains were used for the present study, to evaluate the impact of antimicrobial activity exhibiting bacterial strains on the growth of V. radiata.

Table 1: Bacterial isolates from histoplane and rhizoplane of four different plants Trianthema partulacastrum, Rumex dentatus, Chenopodium morale and Coronopus didymus
Image for - Growth Responses of Vigna radiata to Arid Land Bacteria Exhibiting Antimicrobial Activity

MATERIALS AND METHODS

Bacterial Strains and Seeds Inoculation
The study was conducted in the University of the Punjab, Lahore, Pakistan in the year 2005 to 2006. Twenty four different strains were isolated from the roots of four weeds (Trianthema partulacastrum, Rumex dentatus, Chenopodium morale and Coronopus didymus) by Ahmed (2000), (Table 1). Bacterial strains were grown in L-agar medium (Gerhardt et al., 1994) at 37°C for 24 h. Healthy seeds of V. radiata were surface sterilized by soaking in 0.1% HgCl2 and then washed thrice with distilled water. Seeds were then soaked in bacterial suspension for 15 to 20 min. For control, seeds were soaked in sterile glass distilled water for same duration.

Germination Experiments
Ten milliliter of autoclaved distilled water was poured in labeled petriplate (lined with double layer of Whattman filter paper No. 1 autoclaved and oven dried). With the help of sterilized forceps, seeds (control as well as inoculated) were spread in the respective labeled petri plate (15 seeds of V. radiata per petri plate) uniformly. Petri plates were kept in dark at 25±1°C for germination. Germination was recorded daily. After germination, plates were shifted to light (10D lux and 16 h day length) at 25±1°C after adding 10 mL of Hewitt nutrient solution in each plate (Hewitt, 1963). Seedlings were grown for 10 days after shifting to light. Experiment was repeated eight times. Seedlings were removed from the petri plates. Different growth parameters (seed germination, seedling length, fresh weight of seedlings, dry weight of seedling, dry weight per gram fresh weight of seedling) were recorded.

Biochemical Analysis
For biochemical analysis auxin (Mahadevan, 1984), soluble protein (Bhatti et al., 1993; Lowry et al., 1951), peroxidase (David and Murray, 1965) and acid phosphatases content (Iqbal and Rafique, 1986) were studied.

Statistical Analysis
Standard errors of the means and LSD were calculated following Steel and Torrie (1981).

RESULTS

Seed germination of V. radiata was affected with the inoculation of bacterial strains. The germination was increased over control with few bacterial strains such as TP17 (4.5%), RTP4, RCD1, RCD2, RD3 (4%). Majority of strains had inhibitory effects on this parameter and 1.04 to 2.7% reductions in germination of seeds were recorded (Table 2). Inoculation of TP2, TP9, RCD3 and RD4 and RCM2 did not cause any change in germination parameter. Seedling length was increased with inoculation of bacterial strains except TP17 where slight decrease (2.5%) over control was recorded (Table 2).

Table 2: Effects of bacterial inoculations on seed germination, seedling length, fresh weight, dry weight and dry weight g-1 fresh weight of V. radiata seedlings
Image for - Growth Responses of Vigna radiata to Arid Land Bacteria Exhibiting Antimicrobial Activity

Table 3: Effects of bacterial inoculation on the soluble protein, auxin, peroxidase and acid phosphatase activity of in V. radiata seedlings
Image for - Growth Responses of Vigna radiata to Arid Land Bacteria Exhibiting Antimicrobial Activity

Maximum increase in the seedling was observed with inoculation of RRD1 (38.0%). Fresh weight of V. radiata was increased in the presence of bacterial strains TP1, TP2, TP3, TP4, TP8, TP9, TP17, RCD1, RCD2, RD3, RRD1, RCM2 and RTP2, when compared with non-inoculated control (Table 2). The maximum increase in this parameter was observed with the inoculation of RTP2 (19.0%). Dry weight and dry weight per gram fresh weight increased with bacterial inoculation as compared to non-inoculated control.

Protein content was increased with the inoculation of majority of bacterial strains while TP7, TP14, TP16, TP17, RCD2, RD8 and RRD1 caused reduction in the soluble protein content over non-inoculated seedlings (Table 3). The maximum increase was observed with the inoculation of RCM2 (79.0%). The maximum increase in auxin content was observed with inoculation of RCM2 (26.7%). Peroxidase activity of V. radiata seedlings were increased with the inoculation of bacterial strains TP9 (44.0%). The activity of acid phosphatases increased with the inoculation of majority of bacterial strains. The maximum increase in the acid phosphatases activity was observed with the inoculation of TP1 (153.2%).

DISCUSSION

Microorganisms of soil are sensitive indicator of soil health because of the relationships between microbial diversity, soil quality and ecosystem sustainability (Doran et al., 1994). Hence the microorganism plays important roles in soil quality and plant productivity (Hill et al., 2000). The rhizospheric bacteria promote plant growth by inducing systemic resistance in host plant and protect plant from pathogens (Zheng et al., 2000). The strains used in present work were characterized and screened for antimicrobial activity against Saccharomyces cervisae, E. coli and Bacillus subtilis by Ahmed (2000). Majority of them showed antimicrobial activity against yeast but none of them showed any activity against E. coli. Strains TP13 and RD8 produce certain substances that inhibit Bacillus subtilis growth.

Germination of V. radiata was adversely affected by the inoculation of bacterial strains excluding TP13 and RTP4 (Table 2). The increase in fresh weight might be due to rise in water content (Hashim et al., 1996). Enhanced dry weight could be attributed to the accumulation of salts and nutrients, enhanced ion uptake and increased level of organic salts in cytoplasm (Sudhakar et al., 1993). Improved seedling length coupled with increased dry weight, which is clear indication of growth stimulation by bacteria. Decrease in fresh weight of seedlings may be due reduce water uptake under stress condition. Soluble protein content was also affected with the inoculation of bacterial strain. Maximum increase in this parameter was caused by the inoculation of RCM2 (79.01%). According to Staples and Dacher (1986) auxin and protein are formed from tryphtophan molecules with different molecular arrangement, so the amount of the auxin is directly related to the amount of soluble protein content. Auxin is the master hormone, exercising regulatory action over many different sorts of plant process. Campbell (1985) reported that bacterial strains stimulate plant growth by synthesizing and liberating growth hormone. Enhancement in the auxin contents with the inoculation of bacterial strains was reported in the present study. Enzymes are biochemical catalyst, which play important role. Two enzymes, acid phosphatases and peroxidase were studied for their activity vis-à-vis treatments. Activities of these enzymes were also improved with bacterial inoculation as compared to non-inoculated treatments (Table 3). Majority of bacterial strains caused improvements in the activity of peroxidase and acid phosphatase. The increase in antioxidant enzyme activity in plants under stress provides better protection against reactive oxygen activities (Meloni et al., 2003).

REFERENCES

  1. Ahmed, M., 2000. Characterized of root associated bacteria exhibiting antimicrobial activity. M.Sc. Thesis, University of the Punjab, Pakistan.


  2. Alami, Y., W. Achouak, C. Marol and T. Heulin, 2000. Rhizosphere soil aggregation and plant growth promotion of sunflowers by an exopolysaccharide-producing Rhizobiumsp. Strain isolated from sunflower roots. Applied Environ. Microbiol., 66: 3393-3398.
    CrossRef  |  Direct Link  |  


  3. Bhatti, G.A., N. Qureshi, A. Qureshi and K. Sultana, 1993. Studies on heat shock response of wheat seedlings using E. coli GroEL antibodies. Pakphyton, 5: 157-166.


  4. Campbell, R., 1985. Microbiology of Roots. In: Plant Microbiol, Arnold, E. (Ed.). Edward Arnold, London, pp: 106-152


  5. Casida, L.E.J. and F.L. Lukezic, 1992. Control of leaf spot diseases of alfalfa and tomato with applications of the bacterial predator Pseudomonas strain 679-2. Plant Dis., 76: 1217-1220.


  6. Cho, H.S., S.Y. Park, C.M. Ryu, J.F. Kim, J.G. Kim and S.H. Park, 2007. Interference of quorum sensing and virulence of the rice pathogen Burkholderia glumae by an engineered endophytic bacterium. FEMS Microbiol. Ecol., 60: 14-23.
    Direct Link  |  


  7. Racusen, D. and M. Foote, 1965. Protein synthesis in dark-grown bean leaves. Can. J. Bot., 43: 817-824.
    CrossRef  |  Direct Link  |  


  8. Doran, J.W., D.C. Coleman, D.F. Bezdicek and B.A. Stewart, 1994. Defining Soil Quality for a Sustainable Environment. SSSA Special Publication, Madison, WI., USA


  9. Eaton, W.D., 2001. Microbial and nutrient activity in soils from three different subtropical forest habitat in Beliza, Central American before and during the transition from dry to wet season. Applied Soil Ecol., 16: 219-227.
    CrossRef  |  


  10. Faisal, M., A. Hameed and S. Hasnain, 2005. Chromium resistant bacteria and cyanobacteria: Impact on Cr (VI) reduction potential and plant growth. J. Indus. Microbiol. Biotechnol., 32: 615-621.
    Direct Link  |  


  11. Faisal, M. and S. Hasnain, 2006. Growth stimulatory effects of Bacillus cereus and Ochrobactrum intermedium on Vigna radiata. Lett. Applied Microbiol., 43: 461-466.
    Direct Link  |  


  12. Gerhardt, P., R.G.E. Murray, W.A. Wood and N.R. Krieg, 1994. Methods for General and Molecular Bacteriology. 2nd Edn., American Society for Microbiology, Washington, DC., ISBN-10: 1555810489
    Direct Link  |  


  13. Hashim, F., A. Yasmin and S. Hasnain, 1996. Pre-germination and post-germination bacterial inoculation differently affecting Triticum aestivum seedling growth under Cr stress. Proc. 1st Ingu. Conf. Genetic, Islamabad.


  14. Hewitt, E.J., 1963. Mineral Nutrition of Plant in Culture Media. In: Plant Physiology, Steward, F.C., (Ed.). Academic Press, New York, pp: 97-137


  15. Hill, G.T., N.A. Mitkowski, L. Aldrich-Wolfe, L.R. Emele and D.D. Jurkonie et al., 2000. Methods for assessing the composition and diversity of soil microbial communities. Applied Soil Ecol., 15: 25-36.
    CrossRef  |  Direct Link  |  


  16. Humphry, R.D., M. Andrews, R.S. Santos, K.E. James, V.L. Vinogradova, L. Perin, M.V. Reis and P.S. Cummings, 2007. Phylogenetic assignment and mechanism of action of a crop growth promoting Rhizobium radiobacter strain used as a biofertiliser on graminaceous crops in Russia. Antonie van Leeuwenhoek, 91: 105-113.
    Direct Link  |  


  17. Iqbal, J. and N. Rafique, 1986. Toxic effects of BaCl2 on germination, early seedling growth, soluble proteins and acid phosphatase in Zea mays L. Pak. J. Bot., 19: 1-8.


  18. Klaus, J.S., I. Janse, J.M. Heikoop, R.A. Sanford and B.W. Fouke, 2007. Coral microbial communities, zooxanthellae and mucus along gradients of seawater depth and coastal pollution. Environ. Microbiol., 9: 1291-1305.
    CrossRef  |  Direct Link  |  


  19. Li, L., M. Mo, Q. Qu, H. Luo and K. Zhang, 2007. Compounds inhibitory to nematophagous fungi produced by Bacillus sp. strain H6 isolated from fungistatic soil. Eur. J. Plant Pathol., 117: 329-340.
    Direct Link  |  


  20. Lowry, O.H., N.J. Rosebrough, A.L. Farr and R.J. Randall, 1951. Protein measurement with the folin phenol reagent. J. Biol. Chem., 193: 265-275.
    CrossRef  |  PubMed  |  Direct Link  |  


  21. Lupwayi, N.Z., M.A. Arshad, W.A. Rice and G.W. Clayton, 2000. Bacterial diversity in the water-soluble aggregates of soils under conventional and zero tillage management. Applied Soil Sci., 16: 251-261.


  22. Mahadevan, A., 1984. Growth Regulators, Microorganisms and Diseased Plants. Oxford and IBH Publishing Co. Pvt. Ltd., India, pp: 31


  23. Meloni, D.A., M.A. Oliva, C.A. Martinez and J. Cambraia, 2003. Photosynthesis and activity of superoxide dismutase, peroxidase and glutathione reductase in cotton under salt stress. Environ. Exp. Bot., 49: 69-76.
    CrossRef  |  Direct Link  |  


  24. Sager, M., J. Park and H. Chon, 2007. The effect of soil bacteria and perlite on plant growth and soil properties in metal contaminated samples. Water. Air Soil Poll., 179: 265-281.


  25. Staples, R.C. and R.F. Dacher, 1986. Salinity Induced Gene Expression in Crop Plants. In: Prospects for Biosaline Research, Ahmad, R. and A. San Pietro, (Eds.). Karachi University, Karachi, pp: 3-22


  26. Steel, R.G.D. and J.H. Torrie, 1981. Principles and Procedures of Statistics a Biometrical Approach. 2nd Edn., McGraw Hill Book Co., New York, USA., ISBN-13: 9780070609266, pp: 173-175


  27. Sudhakar, C. and P.S. Reddy and K. Veeranjaneyulu, 1993. Effect of salt stress on the enzymes of proline synthesis and oxidation in greengram (Phaseolus aureus Roxb.) seedlings. J. Plant Physiol., 141: 621-623.


  28. Van Veen, J.A., L.S. Overbeek and van Elas, 1997. Fate and activity of microorganisms introduce into the soil. Microbiol. Mol. Rev., 61: 121-135.


  29. Wieland, G., R. Neumann and H. Backhams, 2001. Variation of microbial communities in soil, rhizosphere and rhizoplane in response to crop species, soil type and crop development. Applied Environ. Microbiol., 67: 5849-5854.
    Direct Link  |  


  30. Zheng, Z., W. Zeng, Y. Huang, Z. Yang, J. Li, H. Cai and W. Su, 2000. Detection of anti-tumor and antimicrobial activities in marine organisms associated actinomycetes isolated from the Taiwan atrait, China. FEMS Microbiol. Lett., 188: 87-91.
    Direct Link  |  


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