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بررسی تغییرات رشدی گیاه کرفس (Apium graveolens) تحت تیمار ورمی کمپوست و قارچ Trichoderma harzianum BI

نوع مقاله : مقالات پژوهشی

نویسندگان

1 دانشگاه فردوسی مشهد

2 دانشگاه تهران

چکیده

با توجه به اهمیت کودهای زیستی و استفاده بهینه از آنها در کشاورزی پژوهش حاضر با هدف بررسی اثر ورمی­کومپوست و قارچ تریکودرما بر برخی خصوصیات مورفولوژیکی گیاه کرفس پایه‌ریزی شد. این طرح به صورت یک آزمایش گلدانی تحت شرایط کشت بدون خاک در گلخانه، در قالب آزمایش فاکتوریل بر پایه طرح کاملاً تصادفی با 4 غلظت قارچ Trichoderma harzianum جدایه BI : صفر درصد (شاهد)، 5 درصد، 10 درصد و 15 درصد حجم50 لیتری آب مصرفی و همچنین 4 تیمار ورمی کمپوست شامل: صفر درصد (شاهد)، 25 درصد، 50 درصد و 75 درصد حجم گلدان با 3 تکرار اجرا شد. نتایج حاصل از این تحقیق حاکی از اثر مثبت کاربرد توام ورمی­کمپوست و قارچ تریکودرما بود. به طوری‌که بیشترین وزن خشک ساقه (23/49 گرم)، تعداد برگ (46 عدد)، قطر ساقه (15 میلی­متر) و میزان کلروفیل و کاروتنوئید در کاربرد ورمی­کمپوست × قارچ تریکودرما  نسبت به تیمار شاهد مشاهده شد. طول ساقه اصلی به میزان (20/77 سانتی­متر) تحت تاثیر قارچ با غلظت 10 درصد در بیشترین میزان نسبت به سایر تیمارها بود، همچنین تیمار 50 درصد حجمی ورمی­کمپوست بیشترین طول ریشه (66/36 سانتی­متر) را داشت. بیشترین میزان کلروفیل a در اثر متقابل ورمی­کمپوست 75 درصد و غلظت قارچ 15 درصد (02/10 میلی­گرم در گرم وزن تر برگ) مشاهده شد. به طور کلی نتایج نشان داد که کاربرد ورمی­کمپوست در بستر کشت و استفاده از عصاره قارچ تریکودرما با تیمار هم زمان از عصاره قارچ 15 درصد × ورمی­کمپوست 75 باعـث بهبود رشد و عملکرد گیاه کرفس می­شوند که می­توان استفاده از آنها را در جهت بهبود رشد و عملکرد گیاه کرفس توصیه کرد.

کلیدواژه‌ها

عنوان مقاله [English]

Evaluation of Growth Changes of Celery (Apium graveolens) under Treated, Vermicompost and Trichoderma harzianum BI

نویسندگان [English]

  • Shahabedin Ahooi 1
  • Ladan Ajdanian 1
  • Seyyed Hossein Nemati 1
  • Hossein Arouiee 1
  • Mehdi Babaei 2

1 Ferdowsi University of Mashhad

2 Tehran University

چکیده [English]

Introduction: In the past decades, chemical fertilizers are used by farmers have numerous environmental impacts, including various types of water and soil contamination, and cause many problems to human health and other organisms. Sustainable agricultural policy and sustainable agricultural development have prompted experts to make greater use of soil organisms to meet the plant's nutritional needs, and that is why the production of biofertilizers began. Biological imbalances in the field of sustainable agriculture can be attributed to the fungi of myoderma and its species. According to various studies, it seems that this microorganism having high ability to compete for food and space, and the establishment of spores in the environment and in particular soil around the roots of most crops and non-farm and can induce plant resistance not only reduces pathogen agents Vermicompost is a microbiologically rich, nutrient-rich, organic modifier that is produced by the interaction between earthworms and microorganisms during the decomposition of organic matter. This type of organic fertilizer contains the waste of certain species of earthworms as a result of alteration, conversion, and relative organic residues as they pass through the digestive tract of these animals. Research has shown that vermicompost has a positive effect on growth, crop development, and crop yield. The aim of this study was to investigate the effect of different amounts of vermicompost and different concentrations of Trichoderma Bi isolate on different properties of celery.
Materials and Methods: This study was conducted to investigate the effects of Trichoderma and vermicompost as a biofertilizer promoting growth in research greenhouse at the Ferdowsi University of Mashhad with an average daily temperature of 15-27 °C and relative humidity of 40-70%. The present study was a factorial experiment based on a completely randomized design with three replicates as a pot experiment under no-tillage conditions in the greenhouse. The first factor consisted of four concentrations of Trichoderma harizianum isolate Bi: zero percent (control), 5%, 10%, and 15% volume of 50 liters of water consumed. The second factor also included four vermicompost treatments: zero percent (control), 25 percent, 50 percent, and 75 percent pot volume. Celery seeds were sown in transplant trays. The transplants were ready for transfer to the main litter after 10 weeks. The pots used were of plastic-type with a span diameter of 20 cm and a height of 25 cm. The plant media consisted of a mixture of 20% cocoon and 80% perlite, the roots of which were easily separable. After full harvest of plants at the commercial size, when a complete set of petiole sets was created (40 days after transplanting) morphological traits including the fresh and dry weight of roots and stems, a number of leaves, stem diameter, stem and root lengths were evaluated. The dry and dry weight of plant root was measured using a digital marking scale and with an accuracy of 0.01 g. Dry weight was determined after placing the specimens in the oven at 72 ° C for 48 hours. Also, the stem diameter was measured using a caliper machine with 0.01 mm accuracy. Root and shoot lengths were measured separately in the laboratory by a ruler in cm. Chlorophyll a, b and carotenoids were read at 663 nm, 653 nm and 470 nm for absorption by spectrophotometer, respectively. Data were analyzed using JMP8 software and ANOVA was performed using the LSD test at 5% probability level. Charts were drawn using Excel 2013 software.
Results and Discussion: The results of this study showed a positive and optimal effect of combined vermicompost and Trichoderma fungi. The highest shoot dry weight (49.23 g), leaf number (46), stem diameter (15 mm) and chlorophyll and carotenoid were observed in the effect of vermicompost and Trichoderma fungi compared to the control treatment. The main stem length (77.20 cm) was affected by the fungus with a 10% concentration at the highest rate compared to other treatments. Also, 50% vermicompost treatment had the highest root length (36.66 cm). The highest chlorophyll a was observed at 75% vermicompost interaction at 15% fungi concentration (10.02 mg / g fresh leaf weight). Application of vermicompost in the culture medium and application of Trichoderma fungus extract resulted in improved growth and yield. As can be seen in the results, the best treatment was 15% and 75% vermicompost, respectively. They can be used to improve plant growth and function. Many researchers believe that mainly isolates of Trichoderma produce biochemical stimuli to stimulate plant growth or reduce the inhibitory effects of certain compounds, biological and chemical toxins. According to available reports, the application of vermicompost with 30% volume in ornamental Lilium increased leaf area, fresh and dry weight of plant and plant height. So, fresh and dry weights of bean stem under vermicompost application significantly increased compared to the control treatment, which is in line with the results of this study. However, the researchers believe that the wet and dry weight gain of the plant body if used with vermicompost is probably due to the high amount of humic acids in this biofertilizer.
Conclusion: Based on the results of this study and other studies on vermicompost as an enriched fertilizer with numerous growth enzymes and hormones, as well as Trichoderma, it can be concluded that the use of bio-fertilizers plays an important role in the production of high-quality products. Also, the effect we find depends on the concentration used, but in the end, even their application at the lowest concentration compared to the control treatment increased growth and morphological characteristics of the plant. Overall, the results of this study showed that, in the case of the studied species, the combination of vermicompost and Trichoderma had a significant advantage over their separate application, and considering the superiority results of most traits at the time of application of these two together. Therefore, a combination of Trichoderma and vermicompost based on the results (concurrent use of 15% fungus extract and 75% vermicompost) is recommended to improve plant growth and yield.

کلیدواژه‌ها [English]

  • Fresh weight
  • Bio fertilizer
  • Morphological
  • Bi isolate
مراجع
1- Arancon N., Edwards C., and Bierman P. 2006. Influences of vermicomposts on field strawberries: Part 2. Effects on soil microbiological and chemical properties. Bioresource Technology 97(6): 831-840.
2- Arancon N., Edwards C., Bierman P., Welch C. and Metzger J. 2004. Influences of vermicomposts on field strawberries: 1. Effects on growth and yields. Bioresource Technology 93(2): 145-153.
3- Arancon N.Q., Galvis P.A., and Edwards C.A. 2005. Suppression of insect pest populations and damage to plants by vermicomposts. Bioresource Technology 96(10): 1137-1142.
4- Argüello J.A., Ledesma A., Núñez S.B., Rodriguez C.H., and Goldfarb M.D.C.D. 2006. Vermicompost effects on bulbing dynamics, nonstructural carbohydrate content, yield, and quality ofRosado Paraguayo'garlic bulbs. Hortscience 41(3): 589-592.
5- Atiyeh R., Lee S., Edwards C., Arancon N., and Metzger J. 2002. The influence of humic acids derived from earthworm-processed organic wastes on plant growth. Bioresource Technology 14-7(1): 84.
6- Badole S., More S., Adsul P., Shaikh A., and Dhamak A. 2004. Residual effect of organic manures and inorganic fertilizers on yield and gross monetary returns of groundnut (Arachis hypogaea L.). Journal of Soils and Crops 14(1): 196-19.
7- Benitez T., Rincon A.M., Limon M.C., and Codon A.C. 2004. Biocontrol mechanisms of Trichoderma strains. International Microbiology 7(4): 249-260.
8- Chaves F., Ming L.C., Ehlert P., Meireles M., and Fernandes D. 2001. Influence of Organic Fertilisation on Leaves and Essential Oil Production of Ocimum gratissimum L. Paper presented at the International Conference on Medicinal and Aromatic Plants. Possibilities and Limitations of Medicinal and Aromatic Plant 576.
9- Claire J.R.O. 2001. Effects of vermicompost applied in a high tunnel. & Quiet Creek Herb Farm, B., PA. FNE03-486.
10- Clevely A. 2000. Herbs, A user's guide and identifier. Harmers House, London.
11- Cutler H.G., Cox R.H., Crumley F.G., and Cole P.D. 1986. 6-Pentyl-α-pyrone from Trichoderma harzianum: its plant growth inhibitory and antimicrobial properties. Agricultural and Biological Chemistry 50(11): 2943-2945.
12- Ders S.G.T.S R. S.1999. d. o. c.-a., b and total carotenoid contents of some algae species using different solvents. Journal of Botany 22: 13-17.
13- De Sanfilippo E.C., Argüello J., Abdala G. and Orioli G. 1990. Content of auxin-inhibitor-and gibberellin-like substances in humic acids. Biologia Plantarum (32): 346-351.
14- Gajalakshmi S., and Abbasi S. 2002. Effect of the application of water hyacinth compost/vermicompost on the growth and flowering of Crossandra undulaefolia, and on several vegetables. Bioresource Technology 85(2): 197-199.
15- Gajdoš R. 1997. Effects of two composts and seven commercial cultivation media on germination and yield. Compost Science & Utilization 5(1): 16-37.
16- Haggag W.M., and Abo-Sedera S. 2005. Characteristics of three Trichoderma species in peanut haulms compost involved in biocontrol of cumin wilt disease. International Journal of Agriculture and Biology 7: 222-229.
17- Harman G.E. 2006. Overview of Mechanisms and Uses of Trichoderma spp. Phytopathology 96(2): 190-194.
18- Harman G.E., Howell C.R., Viterbo A., Chet I., and Lorito M. 2004. Trichoderma species—opportunistic, avirulent plant symbionts. Nature Reviews Microbiology 2(1): 43.
19- Hidalgo P., Sindoni M., Matta F., and Nagel D.H. 1999. Earthworm castings increase germination rate and seedling development of cucumber. Mississippi Agricultural and Forestry Experiment Station, Research Report 1999, 22.
20- Hoitink H., Madden L., and Dorrance A. 2006. Systemic resistance induced by Trichoderma spp.: interactions between the host, the pathogen, the biocontrol agent, and soil organic matter quality. Phytopathology 96(2): 186-189.
21- Inze D. and Montagu MV. 2000. Oxidative stress in plants.
22- Jayalal R., and Adikaram N. 2007. Influence of Trichoderma harzianum metabolites on the development of green mould disease in the oyster mushroom.
23- Joshi R. and Vig A.P. 2010. Effect of vermicompost on growth, yield and quality of tomato (Lycopersicon esculentum Mill). African Journal of Basic and Applied Sciences (2): 117-123.
24- Karmegam N., and Daniel T. 2000. Effect of biodigested slurry and vermicompost on the growth and yield of cowpea, Vigna unguiculata (L.) Walp. Variety Cl. Environment and Ecology 18(2): 367-370.
25- Korikanthimath, V. S. V. u. w. a. i. c., & (813), g. a. A. X.
26- KüÇük Ç., Kivan Ç., M., Kinaci E., and Kinaci G. 2007. Efficacy ofTrichoderma harzianum (Rifaii) on inhibition of ascochyta blight disease of chickpea. Annals of Microbiology 57(4): 665-668.
27- Lazcano C., and Dominguez J. 2011. The use of vermicompost in sustainable agriculture: impact on plant growth and soil fertility. Soil Nutrients 10: 1-23.
28- Maheshbabu H., Hunje R., Biradar Patil N. and Bablad H. 2010. Effect of organic manures on plant growth, seed yield and quality of soybean. Karnataka Journal of Agricultural Sciences 21: 268-276.
29- Marschner H. M. N. o. H. P. A. P., London.
30- Mastouri F., Björkman T., and Harman G.E. 2010. Seed treatment with Trichoderma harzianum alleviates biotic, abiotic, and physiological stresses in germinating seeds and seedlings. Phytopathology, 100(11): 1213-1221.
31- Mcginnis M., Cooke A., Bilderback T., and Lorscheider M. 2003. Organic fertilizers for basil transplant production. Acta Horticulturea 491: 213-218.
32- Moghadam A.R.L., Ardebili Z.O., and Saidi F. 2012. Vermicompost induced changes in growth and development of Lilium Asiatic hybrid var. Navona. African Journal of Agricultural Research 7(17): 2609-2621.
33- Mokhtar M., and El-Mougy N. 2014. Bio-compost application for controlling soil-borne plant pathogens–a review. Population 4: 61-68.
34- Mottaghian A., Pirdashti H., Bahmanyar M.A., Shahsavari A., and Hasanpour R. 2009. Effect of three Trichoderma species and different amounts of enriched municipal waste compost on growth parameters in spinach (Spinacia oleracea). 5th International Scientific Conference of Iran and Russia on Agricultural Development Problems. Saint Petersburg, Russia. pp: 267-270.
35- Muscolo A., Bovalo F., Gionfriddo F., and Nardi S. 1999. Earthworm humic matter produces auxin-like effects on Daucus carota cell growth and nitrate metabolism. Soil biology and Biochemistry 31(9): 1303-1311.
36- Narender P., Malik T.P. and Mangal J.L. 2002. Effect of FYM and vermicompost, & on tomato (Lycopersicon esculantum Mill VAR.SEL-7). XXVI th International horticultural congress. Toronto, C. h. a. a. s. f. l.
37- Narkhede S., Attarde S., and Ingle S. 2011. Study on effect of chemical fertilizer and vermicompost on growth of chilli pepper plant (Capsicum annum). Journal of Applied Sciences in Environmental Sanitation 6(3): 327-332.
38- Ousley M.A., Lynch J.M., and Whipps J.M. 1994. Potential of Trichoderma spp. as consistent plant growth stimulators. Biology and Fertility of Soils 17(2): 85-90.
39- Ozbay N., Newman S.E., and Brown W.M. N2004. The effect of theTrichodermaharzianumstrains on the growth of tomato seedlings ,ActaHort (635): 131-135
40- Papavizas G., and Lumsden R. 1982. Improved medium for isolation of Trichoderma spp. from soil [Fungi]. Plant Diseases (USA).
41- Patterson D. 1981. Effects of allelopathic chemicals on growth and physiological responses of soybean (Glycine max). Weed Science 53-59.
42- Production C. C. R. A. B. C. A. P. M. S. P. f. C. C.
43- Pant A.P., Radovich T.J.K., Hue N.V., Talcott S.T., and Krenek K.A. 2009. Vermicompost extracts influence growth, mineral nutrients, phytonutrients and antioxidant activity in pak choi (Brassica rapa cv. Bonsai, Chinensis group) grown under vermicompost and chemical fertiliser. Journal Science Food Agriculture 89: 2383-2392.
44- Pandurang M.U. 2013. Efficacy of weed vermicompost and chemical fertilizer on yield, morpho-physiological and biochemical investigations of maize. African Journal of Biotechnology 14: 3786-3791.
45- Patra P. and Biswas S. 2009. Integrated nutrient management on growth, yield and economics of maize (Zea mays L) under terai region. Journal of Crop and Weed 5(1): 136-139.
46- Samuels G.J. 1996. Trichoderma: a review of biology and systematics of the genus. Mycological Research 100(8): 923-935.
47- Senesi N., Saiz-Jiminez C., and Miano T. 1992. Spectroscopic characterization of metal-humic acid-like complexes of earthworm-composted organic wastes. Science of the total Environment 117: 111-120.
48- Singh R., Sharma R., Kumar S., Gupta R., and Patil R. 2008. Vermicompost substitution influences growth, physiological disorders, fruit yield and quality of strawberry (Fragaria x ananassa Duch.). Bioresource Technology 99(17): 8507-8511.
49- Singh V., Singh P., Yadav R., Awasthi S., Joshi B., Singh R., and Duttamajumder S. 2010. Increasing the efficacy of Trichoderma harzianum for nutrient uptake and control of red rot in sugarcane. Journal of Horticulture and Forestry 2(4): 66-71.
50- Vinale F., Ambrosio G. D., Abadi K., Scala F., Marra R., Turrà D., and Lorito M. 2004. Application of Trichoderma harzianum (T22) and Trichoderma atroviride (P1) as plant growth promoters, and their compatibility with copper oxychloride. Journal of Zhejiang University (Agriculture and Life Sciences) 30(4): 425.
51- Vinale F., Sivasithamparam K., Ghisalberti E.L., Marra R., Woo S.L., and Lorito M. 2008. Trichoderma–plant–pathogen interactions. Soil biology and Biochemistry 40(1): 1-10.
52- Windham M.T., Elad Y. and Baker R. 1986. A mechanism for increased plant growth induced by Trichodermaspp. , Phytopathology 76: 518-552.
53- Yazdani M., Pirdashti H., Tajik M., and Bahmanyar M. 2008. Effect of Trichoderma spp. and different organic manures on growth and development in soybean [Glycine max (L.) Merril.
54- Yedidia I., Srivastva A.K., Kapulnik Y., and Chet I. 2001. Effect of Trichoderma harzianum on microelement concentrations and increased growth of cucumber plants. Plant and Soil 235(2): 235-242.
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علوم باغبانی
دوره 34، شماره 3 - شماره پیاپی 47
آذر 1399
صفحه 389-403
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  • تاریخ دریافت: 14 مهر 1397
  • تاریخ بازنگری: 20 بهمن 1398
  • تاریخ پذیرش: 13 اسفند 1398
  • تاریخ اولین انتشار: 01 آذر 1399
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