Effects of Vermicompost and Mycorrhizal Fungi on Growth Characteristics, Essential Oil and Yield of Thyme (Thymus vulgaris L.)

Document Type : Scientific - Research

Authors

1 Department of Agronomy, Faculty of Agriculture, Shahrood University of Technology, Shahrood, Iran

2 Medicinal Plants Research Institue Academic Center for Education, Shahrood, Culture and Research, Iran

Abstract

Introduction
Thyme (Thymus vulgaris L.) is one of the most important essential oil plants that its essential oil constituent be used in different medicinal and food industries. Vermicompost is organic manure that significant amounts of macro and micronutrients make available to the plants. Although some of this material is minerals but most of them gradually and slowly released through the mineralization of organic matter. Mycorrhizal fungi are one of the biological factors in the rhizosphere, which include a relatively important part of soil organisms. Under water deficit conditions, mycorrhiza enhances photosynthesis and carbon fixation during the growing season by increasing the leaf area. This condition does not directly contribute to increased photosynthesis in the host plant, but keeps the photosynthesis level higher than control by improving water relations and changing the hormonal relations.
Materials and methods
The treatments included vermicompost in four levels (0, 2, 4, and 6 ton.ha-1) and mycorrhiza in three levels (without inoculation, inoculation with Glomus mosseae and Glomus intraradices) was arranged based on randomized complete block design with 12 treatments and 3 replications. Fresh leaf tissue was used to measure chlorophyll content. Dimethyl sulfoxide (7 ml) was added to 0.1 g leaf tissue and the samples were incubated at 70°Cfor 4h. The light absorptance was measured at 663, 645 and 470 nm with spectrophotometer (Jenway, 6305) to obtain chlorophyll content. To measure Arbuscular Mycorrhizal (AM) symbiosis, plant roots were collected one week before harvesting, cleaned by 10% KOH at 80˚C for 2h, and acidified in 1% HCL for 60 min. Then the cleaned up roots were stained in a solution of trypan blue. The roots were destained in a mixture of 500 ml glycerol, 450 ml water and 5 ml HCL for 24 h, allowing the fungus to be revealed under microscopic examination (Taylor et al. 2008).
Statistical analysis: Analysis of variance (ANOVA) was performed using SAS statistical software (SAS Institute, 1998) and Duncan's multiple range procedure was employed at probability level of 5%.

Results and discussion
The results indicated that the vermicompost application improved significantly plant height, dry weight, colonization, chlorophyll b, total chlorophyll, essential oil content, essential oil yield and thymol yield. Mycorrhizal inoculation affects significantly on chlorophyll b, total chlorophyll and colonization. The highest amount of plant height was recorded by application of 6 ton.ha-1 vermicompost (31 cm) and the lowest amount were obtained in control plots (21.78 cm).
The highest biological yield was obtained from application of 6 ton.ha-1 (3443 kg.ha-1) and the lowest biological yield was recorded in control plots (1966 kg.ha-1). Our results showed that colonization percent significantly increased by application of 6 ton.ha-1 in control plots (49.44 and 22.33%, respectively). The greatest amount of chlorophyll obtained by application of 6 tonha-1 vermicompost and the lowest amount was in control plots.
The best results of essence yield obtained from 4 ton.ha-1 vermicompost, while the maximum essence yield recorded by application of 6 ton.ha-1 vermicompost. The best interaction effects of vermicompost and mycorrhizal was significant on essential oil yield, thymol yield, chlorophyll b and total chlorophyll by the use of 6 ton.ha-1 vermicompost and without inoculation. The most content of chlorophyll a was obtained with the use of 4 ton.ha-1 vermicompost and inoculation with Glomus intraradices. The results showed the highest percent of colonization by the use of 6 ton.ha-1 vermicompost and inoculation with Glomus intraradices. The highest percent of essence was obtained from control (no application of vermicompost and no inoculation of mycorrhiza) treatment.

Conclusion
Vermicompost is one of the organic manure that significant amounts of macro and micronutrients make available to the plants. Mycorrhizal fungi are one of the biological factors in the rhizosphere that increased plant growth especially under stress conditions. In this study vermicompost application significantly increased essence yield. Also, vermicompost and mycorrhizal interaction increased chlorophyll content of plant leaf.

Keywords

References

Andrade, G., Mihara, K.L., Linderman, R.G., and Bethlenfalvay, G.J. 1998. Soil aggregation status and Rhizobacteria in the Mycorrhizosphere. JournalofPlant and Soil 202: 86–96.
Anwar, M., Patra, D.D., Chand, S., Alpesh, K., Naqvi, A.A., and Khanuja, S.P.S. 2005. Effect of organic manures and inorganic fertilizer on growth, herb and oil yield, nutrient accumulation, and oil quality of French basil. Communication in Soil Science and Plant Nutrition 36(13-14): 1737-1746.
Arguello, J.A., Ledesma, A., Nunez, S.B., Rodriguez, C.H., and Goldfarb, M.D.D. 2006. Vermicompost effects on blubbing dynamics, nonstructural carbohydrate content, yield and quality of Rosado Paraguay garlic bulbs. Horticulture Science 4(3): 589-592.
Azizi, M., Rezvani, F., Hassan Zadeh, M., Lakzian, A., and Nemati, H. 2009. Effects of vermicompost and irrigation on morphological traits and essential oil of chamomile. Iranian Journal of Medicinal and Aromatic Plants Research 24(1): 82-93. (In Persian with English Summary)
Azizi, M., Lakzian, A., and Bagani, M. 2007. Effect of different amount of vermicompost and vermivash on morphological factors and essential oil content of basil. Agricultural Science 2: 5-8. (In Persian with English Summary)
Bedini, S., Pellegrino, E., Avio, L., Pellegrini, S., Bazzoffi, P., Argese, E., and Giovannetti, M. 2009. Changes in soil aggregation and glomalin related soil protein content as affected by the arbuscularmycorrhizal fungal species Glomusmosseae and Glomusintraradices. Soil Biology and Biochemistry 41: 1491–1496.
Caravaca, F., Algxuacil, M. M., Azcon, R., and Roldan, A. 2006. Formation of stable aggregates in rhizosphere soil of Juniperusoxycedrus: effect of AM fungi and organic amendments. Appled Soil Ecology 33: 30-38.
Chaoui, H. I., Zibilske, L. M., and Ohno, T. 2003. Effects of earthworm casts and compost on soil microbial activity and plant nutrient availability. Soil Biologyand Biochemistry 35: 295-302.
Darzi, M. T., Ghalavand, A., and Rejali, F. 2008. Effect of mycorrhiza, vermicompost and phosphate biofertilizer application on flowering, biological yield and root colonization in fennel (Foeniculumvulgare Mill.). Iranian Journal of Crop Science 10(1): 88-109. (In Persian with English Summary)
Demir, S. 2004. Influence of Arbuscularmycorrhiza on some physiological growth parameters of pepper. Turkish Journal of Biology 28: 85-90.
Dominguez, J., Aira, M., and Gomez Brandon, M. 2010. Vermicomposting: Earthworms Enhance the Work of Microbes”. In: Insam H., Franke-Whittle I. and Goberna M. (Eds.), “Microbes at Work” From Wastes to Resources, Berlin Heidelberg 93-114.
Hornok, L. 1992. Cultivation and Processing of Medicinal Plants. AkademianKiado. Budapest, Hungary 200-205.
Kapoor, R., Giri, B., and Mukerji, K.G. 2004. Improved growth and essential oil yield and quality in Foeniculumvulgare on mycorrhizal inoculation supplemented with P-fertilizer. Journal of Biological Resource Technology 93: 307–311.
Leake, J.R., Johnson, D., Donnelly, D., Muckle, G., Boddy, L., and Read, D. 2004. Network of power and influence: The role of mycorrhizal mycelium in controlling plant communities and agroecosystem functioning. Canadian Journal of Botany 82: 1016–1045.
Liuc, J., and Pank, B. 2005. Effect of vermicompost and fertility levels on growth and oil yield of Roman chamomile. ScientiaPharmaceutica 46: 63-69.
Moemeni, T., and Shahrokhi, N. 1991. Plant Essences and their Effects. Tehran University Press, Tehran, Iran 171 pp. (In Persian)
Moradi, R., Rezvani Moghaddam, P., Nassiri Mahallati, M., and Nezhadali, A. 2011. Effects of organic and biological fertilizers on fruit yield and essential oil of sweet fennel (Foeniculum vulgar var. Dulce). Spanish Journal of Agricultural Research 9(2): 546-553.
OmidBeigi, R. 2004. Production and Technology of Medicinal Crops. AstaneQodsRazaviPress. 397 pp. (In Persian)
Ozkutla, F., Bulent, T., and Cakmak, I. 2006. Effects of zinc humate on growth of soybean and wheat in zinc-deficient calcareous soil. Communication in soil science and plant Analysis 37: 2769-2778.
Picuric-Jonanovic, K., Milovanovic, M., and Vrbaski, Z. 1995. Thymus vulgaris as a source of natural antioxidant: Review of Research-Work at the Faculty of AgricultuerBelgrad, USSR 40: 141-146.
Pirdashti, H., Motaghian, A., and Bahmanyar, M.A. 2010. Effect of organic amendments application on grain yield, leaf chlorophyll content and some morphological characteristics in soybean cultures. Journal of Plant Nutrition 33: 485-495.
Putievsky, E., Sanderowich, D., and Ron, R. 1981. Growing spice plants from seeds or cutting. Horticultural Abstracts 51(1): 589.
Roy, D.K., and Singh, B.P. 2006. Effect of level and time of nitrogen application with and without vermicompost on yield, yield attributes and quality of malt barley (Hordeumvulgare). Indian Journal of Agronomy 51: 40-42.
Ratti, N., Kumar, S., Verma, H.N., and Gautam, S.P. 2001. Improvement in bioavailability of tricalcium phosphate to Cymbopogonmartinii var. motia by rhizobacteria, AMF and azospirillum inoculation. Microbiological. Research 156: 145-149.
Rezvani Moghaddam, P., Amiri, M.B., and Ehyaee, H.R. 2016. Effect of simultaneous application of mycorrhiza with compost, vermicompost and sulfural geranole on some qualitative and quantitative characteristics of Sesame (Sesmum indicum L.) in a low input cropping system. Journal of Agroecology 7(4): 563-577. (In Persian with English Summary)
Rillig, M.C., and Mummey, D. 2009. Mycorrhizas and soil structure. New Phytology 171: 41-53.
Rillig, M.C., Wright, S.F., Nichols, K.A., Schmid, W.F., and Torn, M.S. 2002. The role of arbuscularmycorrhizal fungi and glomalin in soil aggregation: Comparing effects of five plant species. Journal of Plant andSoil 238: 325-333.
Roldan-Fagardo, B.E., Barea, B.E., Ocampo, J.A., and Azcon-Aguilar, C. 1982. The effect of season on VA mycorrhiza of the almond tree and of phosphate fertilization and species of endophyte on its mycorrhizal dependency. Journal of Plant and Soil 68: 361-367.
Sangwan, P., Garg, V.K., and Kaushik, C.P. 2010. Growth and yield response of marigold to potting media containing vermicompost produced from different wasts. Journal of Environent. 30: 123-130.
Smith, S.E., and Read, D.J. 2008. Mycorrhizal symbiosis” 3rd ed. Academic, London.
Stahl, E. 2002. Thyme as AHerbalDrug-pharmacopoeias and Other Product Characteristics. In: Stahl-Biskup, E., Saez, F. (Eds.) Thyme, the genus Thymus. Taylor and Francis, London: 293-316.
Uma, B., and Malathi, M. 2009. Vermicompost as a soil supplement to improve growth and yield of Amaranths species. Research Journal of Agricultural and Biological Science 5: 1054–1060.
Wilson, G.W. T., Rice, C.W., Rillig, M.C., Springer, A., and Hartnett, D.C. 2009. Soil aggregation and carbon sequestration are tightly correlated with the abundance of arbuscularmycorrhizal fungi”: results from long-term field experiments. Ecological Letter 12: 452-461.
Zargari, A. 1993. Medicinal Plants. Volume 4. Tehran University Press, Tehran, Iran 217 pp. (In Persian)
Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 19 November 2014
  • Accept Date: 19 November 2014
  • First Publish Date: 21 March 2017

Share

How to cite

Statistics