KnE Life Sciences

ISSN: 2413-0877

The latest conference proceedings on life sciences, medicine and pharmacology.

Growth and Yields of Three Tomato Strains of Lycopersicum Esculentum Mill With Various Dosages of Trichoderma Sp

Published date: Jun 07 2022

Journal Title: KnE Life Sciences

Issue title: The First Asian PGPR Indonesian Chapter International e-Conference 2021

Pages: 152–161

DOI: 10.18502/kls.v7i3.11116

Authors:

Endah WahyuriniEmail: endahwahyurini@yahoo.com
Affiliation: UPN “Veteran” Yogyakarta, Indonesia
Biography:

L. LagimanEmail: N/A
Affiliation: UPN “Veteran” Yogyakarta, Indonesia
Biography:

Endah Wahyurini - endahwahyurini@yahoo.com

L. Lagiman

Abstract:

By testing several F1 tomato lines, the genetic diversity of tomatoes can be observed for their agronomic characters and product. To increase fruit production, Trichoderma sp, a biological microbial material and plant growth stimulator, can be applied to tomatoes. The goal of this study was to track the growth and development of three tomato strains along with their interactions with Trichoderma sp. A completely randomized design was used in this study, with two factors and three responses, and the two treatments were repeated three times. The tomato strains were Servo F1, F2, and F3, and the Trichoderma sp dosages were 30 g/plant, 40 g/plant, and 50 g/plant. ANOVA was used to analyze the data, followed by a DMRT test at a 5% level. This study found that the F1 tomato strain was significantly taller, while the F3 tomato strain had a sweeter taste. Trichoderma sp at a dose of 40 g/plant accelerated the appearance of flowers and fruit diameter. The addition of Trichoderma sp at a dose of 40 g/plant in Servo F1 tomatoes increased the total number of leaves and the total weight per plant. Tomato vitamin C content was increased in the F1, F2, and F3 tomato strains with 30 g/plant Trichoderma sp.

Keywords: Tomato, Trichoderma sp, strain

References:

[1] Fahmil U. Tomato for heart disease prevention. Jurnal Kesehatan. http://ejournal.poltekkesternate.ac.id/ojs 2020;13(1):21-27.

[2] Badan Pusat Statistika. Seasonal vegetables and fruits (tons) for the year 2019-2020. BPS Indonesia. 2020; Available at: https://www.bps.go.id/subject/55/hortikultura.html#subjekViewTab3

[3] Moriones E and Catillo JN. Tomato yellow leaf curl virus, and emerging virus complex causing epidemics worldwide. Virus Research. Elsevier. 2000;71:123-134.

[4] Wahyuni SH. The potential of Trichoderma in suppressing attacks Sclerotium rolfsii on soybean plants. Jurnal Agrotek Lestari. 2018;15(1):51-57.

[5] Herlina L and Pramestri D. The use of Trichoderma harzianum active compost in improving chili plant growth. Jurnal Saians dan Teknologi. Universitas Negeri Semarang. Semarang; 2017.

[6] Berliance ASS, Bambang P, and Bambang S. Trichoderma sp. application. to control the attack of Fusarium oxysporum f.sp. lycopercii on cung tomato plants (Lycopersicum esculentum mill). Bengkulu State University. Bengkulu. Indonesia; 2017. http://repository.unib.ac.id/id/eprint/12696

[7] Sopialena S. The effect of giving Trichoderma sp. in tomato plants on production factors. AGRIFOR: Jurnal Ilmu Pertanian dan Kehutanan. 2018;12(2):345-354.

[8] I Made Setyadi D, I Nengah Artha, and Gusti Ngurah Alit SW. The effectiveness of composting Trichoderma sp. on the growth of chili plants (Capsicum annum L.). E-Journal of Tropical Agroecotechnology. 2017;6(1):21-30.

[9] Qosim WA. Plant breeding method. Bandung: Plantaxia; 2018.

[10] Nazirwan I, Wahyudi A, and Dulbari D. Characterization of germplasma collection in local and introduction of tomato. Jurnal Penelitian Pertanian Terapan. 2014;14(1):70- 75.

[11] Panah Merah. Servo variety tomato description. Research report. PT East West Seed Indonesia. Purwakarta. West Java. Indonesia; 2020.

[12] Syukur M, Sriani S, and Yunianti R. Plant breeding techniques. Jakarta: Self-Help Spreader; 2014.

[13] Nufrifaldi N, Hariyadi H, and Widyastuti R. Identifikasi and potential of indigenous fungi for weathering oil palm trunks. Jurnal Agronomi Indonesia. 2019; 47(3):312-317.

[14] Salisbury FB and Ross CW. Plant physiology. 3rd ed. Bandung: Institut Teknologi Bandung; 2017.

[15] Santi KP, Rustikawati R, and Dotti S. Growth performance and yield of sixteen genotypes of tomato (Solanum lycopersicum L.) in the lowlands. Journal Akta Agrosia. 2016;19(2):118–128.

[16] Achmad B, Nawawi M, and Abadi AL. Application techniques of Trichoderma sp on growth and yield of potato (Solanum tuberosum LJ). Journal of Plant Production. 2013;1(3):21–30.

[17] Harjadi H. Introduction of agronomi. Jakarta: PT Gramedia Main Library; 1996.

[18] Winarno W. Post-harvest physiology. Jakarta: Sastra Hudaya; 1981.

[19] Sari LD, Ningrum KRS, Ramadani AH. Vitamin C content of tomato fruit (Lycopersicum esculentum mill) each maturity phase based on days after planting. Journal Indonesian Pharmacy and Pharmacy. 2021;8(1):74-82.

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