2020
Buku Ajar

Pengelolaan Penyakit Tanaman Terpadu


Sutarman
Universitas Muhammadiyah Sidoarjo, Indonesia
Andriani E Prihatiningrum
Universitas Muhammadiyah Sidoarjo, Indonesia
A Miftakhurrohmat
Universitas Muhammadiyah Sidoarjo, Indonesia
Picture in here are illustration from public domain image or provided by the author, as part of their works
Published September 23, 2021
Keywords
  • Pengelolaan,
  • Pengelolaan Penyakit,
  • Tanaman Terpadu
How to Cite
Sutarman, Prihatiningrum, A. E., & Miftakhurrohmat, A. (2021). Pengelolaan Penyakit Tanaman Terpadu. Umsida Press, 1-139. https://doi.org/10.21070/2020/978-623-6833-08-7

Abstract

Puji syukur kehadirat Allah SWT atas tersusunnya buku ajar dengan judul: “Pengelolan Penyakit Tanaman Hortikultur Terpadu” yang merupakan salah satu luaran penelitian sesuai kompetensi penyusun di bidang kesehatan dan penyakit tanaman serta agroteknologi. Buku ini disusun berdasarkan hasil penelitian dan kajian literatur yang bersumber pada berbagai artikel jurnal Internasional relevan terkait dan jurnal yang khusus memuat tema penyakit tanaman yaitu Jurnal Hama dan Penyakit Tanaman Tropika yang mulai tahun 2018 semua artikelnya menggunakan bahasa Inggris. Buku ini memuat sebagian materi perkuliahan Pengelolaan Hama dan Penyakit Tanaman Terpadu (PHPT). Di samping itu buku ini juga dapat digunakan bagi mahasiswa dan praktisi pertanian yang menggeluti persoalan kesehatan dan perlindungan tanman. Meskipun syarat mengambil mata kuliah PHPT ini mahasiswa harus lulus mata kuliah Dasar-dasar Perlindungan Tanaman, namun materi buku bisa dicerna dan dipahami mengingat materi disampaikan dengan ilustrasi yang memperjelas uraian. Oleh karenanya disarankan sambil membaca buku ini, pembaca dapat menggali ilmu-ilmu dasar penyakit tanaman dari berbagai sumber lainnya. Pada kesempatan ini penulis menyampaikan terima kasih kepada: Rektor Universitas Muhammadiyah Sidoarjo (UMSIDA), Dekan, Ketua Program Studi Agroteknologi Fakultas Sains dan teknologi UMSIDA atas dukungan moril dan fasilitas yang disediakan bagi kelancaran penelitian dan penyusunan buku ini. Semoga karya ilmiah ini bermanfaat.

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References

  1. Tilman D, Cassman KG, Matson PA, Naylor R & Polasky S. 2002. Agricultural sustainability and intensive production practices. Nature 418, 671– 677.
  2. Sutarman. 2017. Dasar-dasar ilmu peyakit tanaman. UMSIDA Presss. 201Lu Y, Rao S, Huang F, Cai Y, Wang G, & Cai K. 2016. Effects of biochar amendment on tomato bacterial wilt resistance and soil microbial amount and activity. Int. J. Agron. 2016: 2938282.
  3. Helina S, Sulandari S, Hartono S, Trisyono A. 2018. Detection and transmission of rice stunt virus on Ciherang and Situ Bagendit varieties. J. HPT Tropika. 18(2): 169–176. DOI: 10.23960/J.Hptt.218169-176.
  4. Iswanto EH, Munawar D, & Rahmini. 2020. Resistance evaluation of modern rice varieties to brown planthopper Nilaparvata lugens STÅL. J. HPT Tropika. 20(2):157–164. DOI : 10.23960/J.Hptt.220157-164.
  5. Swibawa IG, Susilo FX, Purnomo, Aeny TN, Utomo SD, & Yuliadi E. 2020. Infestation of major pests and diseases on various cassava clones in Lampung-Indonesia. J. HPT Tropika. 20(1):13–18. DOI: 10.23960/J.Hptt.12013-18.
  6. Sutarman. 2017. Pengendalian Penyakit Benih dan Bibit. UMSIDA Press.
  7. Sutarman. Hadi S, Saefuddin A, Achmad, Suryani A. 2004. Epidemiologi hawar daun bibit Pinus merkusii yang disebabkan oleh Pestalotia theae. Jurnal Manajemen Hutan Tropika 10 (1): 43-60.
  8. Febbiyanti TR, Wiyono S, Yahya S, & Widodo. 2019. Analysis of causative factors for stem canker Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 122 disease epidemic on rubber plants in South Sumatra. J. HPT Tropika. 19(1): 82–91 DOI : 10.23960/J.Hptt.11982-91.
  9. Suharti T, Joko T, & Arwiyanto T. 2017. Deteksi bakteri patogen terbawa benih akor (Acacia auriculiformis a. cunn. ex benth.). J. HPT Tropika. 17(1): 19 – 36.
  10. Sutarman & Prihatiningrum AE. 2015. Penyakit hawar daun Pinus merkusii di berbagai persemaian kawasan utama hutan pinus Jawa Timur. J. HPT Tropika. 15(1): 44 – 52.
  11. Glare T, Caradus J, Gelernter W, Jackson T, Keyhani N, Kohl J, Marrone P, Morin L & Stewart A. 2012.Have biopesticides come of age? Trends Biotechnol. 30, 250-258.
  12. Buysens C, César V, Ferrais F, De Boulois HD & Declerck S. 2016. Inoculation of Medicago sativa cover crop with Rhizophagus irregularis and Trichoderma harzianum increases the yield of subsequently-grown potato under low nutrient conditions. Applied Soil Ecology 105,137–143.
  13. Pruksakorn P, Arai M, Kotoku N, Vilchèze C, Baughn AD, Moodley P, Jacobs WR Jr, & Kobayashi M. 2010. Trichoderins, novel aminolipopeptides from a marine sponge-derived Trichoderma sp., are active against dormant mycobacteria. Bioorg. Bioorganic Med. Chem. Lett. 20(12): 3658–3663.
  14. Yedidiaa I, Benhamoub N, Kapulnikc Y & Cheta I. 2000. Induction and accumulation of PR proteins activityduring early stages of root colonizationby the mycoparasite Trichoderma harzianum strain T-203. Plant Physiology and Biochemistry 38 (11): 863–873.
  15. Chowdappa P, Kumar SPM, Lakshmi MJ, & Upreti KK. 2013. Growth stimulation and induction of systemic resistance in tomato against early and late blight by Bacillus subtilis OTPB1 or Trichoderma harzianum OTPB3. Biol. Control. 65(1): 109–117. Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 123
  16. Hu X, Roberts DP, Xie L, Maul JE, Yu C, Li Y, Zhang Y, Qin L & Liao X. 2015. Components of a riceoilseed rape production system augmented with Trichoderma sp. Tri-1 control Sclerotinia sclerotiorum on oilseed rape. Phytopathology 105, 1325-1333.
  17. Martínez-Medina, A., Pascual, J.A., Perez-Alfocea, L.F., Roldán, A., 2010. Trichodermaharzianum and Glomus intraradices modify the hormone disruption induced by Fusarium oxysporum infection in melon plants. Phytopathology 100, 682–688.
  18. Vinale F, Sivasithamparam K, Ghisalberti EL, Marra RS, Woo L & Lorito M. 2008. Trichoderma–plant– pathogen interactions. Soil Biol. Biochem. 40, 1-10.
  19. Hu X, Roberts DP, Xie L, Yu C, Li Y, Qin L, Hu L, Zhang Y, & Liao X. 2016. Use of formulated Trichoderma sp. Tri-1 in combination with reduced
  20. rates of chemical pesticide for control of Sclerotiniasclerotiorium on oilseed rape. Crop Prot. 79: 124– 127.
  21. Tasik S, Widyastuti SM, & Harjono. 2015. Mekanisme parasitisme Trichoderma harzianum terhadap Fusarium oxysporum pada semai Acacia mangium. J. HPT Tropika. 15(1): 72 – 80.
  22. Sutarman. 2019. Application of Trichoderma harzianum as soil treatment and additional treatment for control of potato diseases. J. Agric. Sci. 2(2): 139 150.
  23. Huang J, Wei Z, Tan S, Mei X, Yin S, Shen Q, & Xu Y. 2013. The rhizosphere soil of diseased tomato plants as a source for novel microorganisms to control bacterial wilt. Appl. Soil Ecol. 72: 79– 84.
  24. Sutarman. 2016. Seleksi Trichoderma Spp Dari Bawah Tegakan Pinus Dan Uji Daya Dukung Isolat Terpilih Terhadap Pertumbuhan Tomat Dan Sawi. Hlm. 125-134 dalam Prosiding Konser Karya Ilmiah Nasional; Salatiga, 4 Agustus 2016. Prihtanti Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 124 TM dan Herawati MM (peny,), Salatiga, Indonesia, Universitas Kristen Satya Wacana, Salatiga.
  25. Ginting C, Prasetyo J, Nurhidayat A, & Maryono T. 2017. Efikasi isolat Trichoderma terpilih dengan bahan organik untuk mengendalikan penyakit busuk pangkal batang pada lada di lapangan. J. HPT Tropika. 17(1): 77 – 83.
  26. Jahuddin R, Jamila, Awaluddin, & Suriani. 2018. Exploration and screening for endophytic microbes of maize plant root against Fusarium verticillioides. J. HPT Tropika. 18(1): 57–64. DOI : 10.23960/J.Hptt.11857-64.
  27. Prihatiningsih N & Djatmiko HA. 2016. Enzim amilase sebagai komponen antagonis Bacillus subtilis b315 terhadap Ralstonia solanacearum kentang. J. HPT Tropika. 16(1): 10 – 16.
  28. Kim HJ, Choi HS, Yang SY, Kim IS, Yamaguchi T, Sohng JK, Park SK, Kim JC, Lee CH & Garderner BM. 2014. Both extracellular chitinase and new cyclic lipopeptide,chromobactomycin, contribute to the biocontrol activity of Chromobacterium sp. C61. Molecular Plant Pathology 15(2): 122–132 Raza, W., Yousaf, S., and Rajer, F. U. (2016). Plant growth promoting activity of volatile organic compounds produced by biocontrol strains. Sci. Lett. 4, 40–43.
  29. Tahir, H. A. S., Gu, Q., Wu, H., Niu, Y., Huo, R., and Gao, X. 2017. Bacillus volatiles adversely affect the physiology and ultra-structure of Ralstonia solanacearum and induce systemic resistance in tobacco against bacterial wilt. Sci. Rep. 7:40481. doi: 10.1038/srep40481
  30. Ortíz-Castro, R., Contreras-Cornejo, H. A., Macías- Rodríguez, L., and López-Bucio, J. (2014). The role of microbial signals in plant growth and development. Plant Signal. Behav. 4, 701–712. doi: 10.4161/psb.4.8.9047 Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 125
  31. Batoo T, Ali S, Seleiman MF, Naveed NM, Ali A, Ahmed K, Abid M, Rizwan M, Shahid MR, Alotaibi M, Al‑Ashkar I & Mubushar M . Plant growth promoting rhizobacteria alleviates drought stress in potato in response to suppressive oxidative stress and antioxidant enzymes activities. Scientifc Reports. (2020) 10:16975. [48] https://doi.org/10.1038/s41598-020-73489-z
  32. Radchenko VV, Vasilyev IY, Ilnitskaya EV, Garkovenko AV, Asaturova AM, Tomashevich NS, Kozitsyn AE, Milovanov AV, Grigoreva TV, Shternshis MV. 2020. Draft genome sequence of the plant growth- promoting bacterium Bacillus subtilis strain BZR 517, isolated from winter wheat, now reclassified as Bacillus velezensis strain BZR 517. Microbiol Resour Announc 9:e00853-20. https://doi.org/10.1128/MRA.00853-20.
  33. Hafiz A. S. Tahir, Qin Gu, Huijun Wu, Waseem Raza, Alwina Hanif, Liming Wu, Massawe V. Colman and Xuewen Gao. Plant Growth Promotion by Volatile Organic Compounds Produced by Bacillus subtilis SYST2. Front. Microbiol., 2017. https://doi.org/10.3389/fmicb.2017.00171.
  34. Blake, C., Nordgaard Christensen, M., & Kovács, Á. T. (2020). Molecular aspects of plant growth promotion and protection by Bacillus subtilis. Molecular Plant Microbe Interactions®. doi:10.1094/mpmi-08-20-0225-cr
  35. Chen XH, Koumoutsi A, Scholz R, Eisenreich A, Schneider K, Heinemeyer I, Morgenstern B, Voss B, Hess WR, Reva O, Junge H, Voigt B, Jungblut PR, Vater J, Süssmuth R, Liesegang H, Strittmatter A, Gottschalk G, Borriss R. 2007. Comparative analysis of the complete genome sequence of the plant growth promoting bacterium Bacillus amyloliquefaciens FZB42. Nat Biotechnol 25:1007– 1014. https://doi.org/10.1038/nbt1325. Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 126
  36. Borriss R, Danchin A, Harwood CR, Médigue C, Rocha EPC, Sekowska A, Vallenet D. 2018. Bacillus subtilis, the model Gram-positive bacterium: 20 years of annotation refinement. Microb Biotechnol 11:3–17. https://doi .org/10.1111/1751- 7915.13043.
  37. Zakia A, Ilyas S, Budiman C, Syamsuddin, & Manohara D. 2018. Exploration and selection of rhizobacteria that inhibit Phytophthora capsici in vitro. J. HPT Tropika. 18(1): 83–94. DOI :10.23960/J.Hptt.21883-94.
  38. Gil VS, Pastor S and GJ March Quantitative isolation of biocontrol agents Trichoderma spp., Gliocladium spp. and actinomycetes from soil with culture media. Microbiol. Res. 2009;164(2):196-205
  39. Li Y, Feng J, Liu H, Wang L, Hsiang T, Li X, & Huang J. 2016. Genetic diversity and pathogenicity of Ralstonia solanacearum causing tobacco bacterial wilt in China. Plant Dis. 100(7): 1288– 1296.
  40. Wuryandari Y, Wiyatiningsih S, & Maroeto. 2015. Formula berbahan aktif Pseudomonad fluoresen dan pengaruhnya terhadap perkembangan penyakit layu pada cabai. J. HPT Tropika. 15(1): 89 – 94.
  41. Yanti Y, Habazar T, & Resti Z. 2017. Formulasi padat rhizobakteria indigenus Bacillus thuringiensis TS2 dan waktu penyimpanan untuk mengendalikan penyakit pustul bakteri Xanthomonas axonopodis pv. glycines. J. HPT Tropika. 17(1): 9 – 18.
  42. Muis A, Djaenuddin N, & Nonci N. 2015. Evaluasi lima jenis inner carrier dan formulasi Bacillus subtilis untuk pengendalian hawar pelepah jagung (Rhizoctonia solani kuhn). J. HPT Tropika. 15(2): 164 – 169.
  43. Gusnawaty HS, Taufik M, Bande LOS, & Asis A. Efektivitas beberapa media untuk perbanyakan Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 127 agens hayati Trichoderma sp. J. HPT Tropika. 17(1): 70 – 76.
  44. John NS, Anjanadevi IP, Nath VS, Sankar SA, Jeeva ML, John KS, & Misra RS. 2015. Characterization of Trichoderma isolates against Sclerotium rolfsii, the collar rot pathogen of Amorphophallus – A polyphasic approach. Biological Control, 90, 164– 172.doi:10.1016/j.biocontrol.2015.07.001.
  45. Youssef SA, Tartoura KA & Abdelraouf GA. 2016. Evaluation of Trichoderma harzianum and Serratia proteamaculans effect on disease suppression, stimulation of ROS-scavenging enzymes and improving tomato growth infected by Rhizoctonia solani. Biological Control 100, 79–86.
  46. Saravanakumar K, Yu C, Dou K, Wang M, Li Y, & Chen J. 2016. Synergistic effect of Trichodermaderived antifungal metabolites and cell wall degrading enzymes on enhanced biocontrol of Fusarium oxysporum f. sp. cucumerinum. Biol. Control. 94: 37–46.
  47. Chowdappa P, Kumar SPM, Lakshmi MJ, & Upreti KK. 2013. Growth stimulation and induction of systemic resistance in tomato against early and late blight by Bacillus subtilis OTPB1 or Trichoderma harzianum OTPB3. Biol. Control 65(1): 109–Nurbailis, Martinius, & Naipinta R. 2017. Kesintasan beberapa jamur antagonis pada buah cabai dan potensinya dalam menekan penyakit antraknosa yang disebabkan oleh Co lletotrichum gloeosporioides. J. HPT Tropika. 17(2): 162–169.
  48. Hutauruk D, Suryanto D, & Munir E. 2016. Asai isolat bakteri kitinolitik Bacillus sp. BK17 pada media pembawa tanah gambut dan kompos janjang kelapa sawit dalam menghambat pertumbuhan jamur patogen Sclerotium rolfsii dan Fusarium oxysporum pada kecambah cabai. J. HPT Tropika. 16(1): 61 – 70.Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 128
  49. Sutarman. 2017. Pengujian Trichoderma sp. sebagai pengendali hawar daun bibit kakao yang disebabkan oleh Phytophthora palmivora. J. HPT Tropika. 17(1): 45 – 52.
  50. Tahir HAS, Gu Q, Wu H, Niu Y, Huo R, & Gao X. 2017. Bacillus volatiles adversely affect the physiology and ultra-structure of Ralstonia solanacearum and induce systemic resistance in tobacco against bacterial wilt. Sci. Rep. 7: 40481.
  51. Subiadi, Sipi S, & Basundari FRA. 2019. Decrease in production and quality of grain due to neck blast disease in some lowland rice varieties. J. HPT Tropika 19(1): 74 – 81. DOI : 10.23960/J.Hptt.11975-82.
  52. Surutini R & Soelistijono. 2020. Development of pink disease on various ages of Acacia crassicarpa cunn ex. benth. J. HPT Tropika. 20(2): 116-122. DOI : 10.23960/J.Hptt.220116-122
  53. Wicaksono D, Wibowo A, & Widiastuti A. 2017. Metode isolasi Pyricularia oryzae penyebab penyakit blas padi. J. HPT Tropika. 17(1): 62 – 69.
  54. Saridewi LP, Prihatiningsih N, & Djatmiko HA. 2020. Characterization of eggplant endophyte bacteria and rhizobacteria as well as their antagonistic ability against Ralstonia solanacearum. J. HPT Tropika. 20(2): 150-156. DOI : 10.23960/J.Hptt.220150-156
  55. Kumar S, Stecher G, Li M, Knyaz C, & Tamura K. 2018. MEGA X: Molecular evolutionary genetics analysis across computing platforms. Mol. Biol. Evol. 35(6): 1547–1549.
  56. [NCBI] National Center for Biotechnology Infromation. 2020. Basic Logical Alignment Search Tool. http://www.ncbi.nlm.nih.gov/BLAST. Diakses 23 Maret 2020.
  57. Kurniawati F, Suastika G, & Giyanto. 2015. Identifikasi Tomato Infectious Chlorosis Virus penyebab penyakit klorosis pada tanaman tomat di Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 129 Cipanas Jawa Barat melalui perunutan nukleotida gen protein selubung utama. J. HPT Tropika. 15(1): 33 – 43.
  58. Fierer N, Jackson JA, Vilgalys R, & Jackson RB. 2005. Assessment of soil microbial community structure by use of taxon-specific quantitative PCR assays. Appl. & Environ. Microb. 71(7): 4117–
  59. Supyani, Dwiwiyati Nurul Septariani, & Hadiwiyono. 2020. Symptoms variation of viral infectionsin yardlong bean. J. HPT Tropika. 20(1): 28–36. DOI : 10.23960/J.Hptt.12028-36
  60. Prasetyo AE, Mutaqin KH, & Giyanto. 2017. Karakterisasi fitoplasma penyebab penyakit layu kelapa di pulau derawan menggunakan rflp in silico J. HPT Tropika. 17(2): 105 –110.
  61. Miftakhurohmah, Suastika G, Damayanti TA, & NoverizaR. 2015. Identifikasi molekuler Broad Bean Wilt Virus 2 (BBWV2) dan Cymbidium Mosaic Virus (CyMMV) asal tanaman nilam (Pogostemon cablin benth.). J. HPT Tropika. 15(2): 188 – 199.
  62. Melinda, Damayanti TA, & Hidayat SH. 2015. Identifikasi molekuler Bean Common Mosaic Virus yang berasosiasi dengan penyakit mosaik kuning kacang panjang. J. HPT Tropika. 15(2): 132 – 140.
  63. Yanti Y, Hamid H, & Reflin. 2018. Indigenous rhizobacteria screening from tomato to control Ralstonia syzigii subsp. Indonesiensis and promote plant growth rate and yield. J. HPT Tropika. 18(2): 177–185. DOI : 10.23960/J.Hptt.218177-185.
  64. Sa’diyah N, Adawiah, Prasojo I, Rugayah, Dirmawati SR. Genotypic selection on red chili plants resistant to anthracnose disease at M2 generation. J. HPT Tropika. 18(2): 151–159. DOI : 10.23960/J.Hptt.218151-159.
  65. Evizal R, Sugiatno, Ivayani, Pujisiswanto H, Wibowo L, & Prasmatiwi FE. 2018. Incidence dynamic of Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 130 pod rot disease of cocoa clones in Lampung, Indonesia . J. HPT Tropika. 18(2): 105–111.
  66. Ginting S, Nadrawati, Zarkani A, & Sumarni T. 2020. Natural incidence of entomopathogenic fungus Nomuraea rileyi on Spodoptera frugiperda infesting corn in Bengkulu. J. HPT Tropika. 20(2): 85–91. DOI : 10.23960/J.Hptt.22085-91
  67. Dweba, C. C., Figlan, S., Shimelis, H. A., Motaung, T. E., Sydenham, S., Mwadzingeni, L., & Tsilo, T. J. (2017). Fusarium head blight of wheat: Pathogenesis and control strategies. Crop Protection, 91, 114– 122.doi:10.1016/j.cropro.2016.10.002.
  68. Djaenuddin N & Muis A. 2017. Efektivitas biopestisida Bacillus subtilis Bnt 8 dan pestisida nabati untuk pengendalian penyakit hawar pelepah dan upih daun jagung. J. HPT Tropika. 17(1): 53 – 61.
  69. Djaenuddin N, Muis, & Nurnina Nonci. 2018. Screen house test of eight biopesticide formulation Bacillus subtilis against downy mildew, Peronosclerospora Philipinensis, on corn plant. J. HPT Tropika. 18(1): 51–56. DOI : 10.23960/J.Hptt.11851-56
  70. Khairan, Aulina, Bahi M, Eriana CN, & Sriwati R. 2019. Fungicidal activity of garlic (Allium sativum) bulbs extracts against plants pathogenic fungi. J. HPT Tropika. 19(1): 23–32. DOI : 10.23960/J.Hptt.11923-32.
  71. Wuryandari Y, Wiyatiningsih S, & Maroeto. 2017. Introduksi formula pupuk hayati berbahan aktif Pseudomonad fluorescent isolat PF-122 untuk meningkatkan pertumbuhan dan produksi tanaman cabai di lapang. J. HPT Tropika. 17(1): 156 – 161.
  72. Singh A, Shukla N, Kabadwal BC, Tewari AK, & Kumar J. 2018. Review on plant-Trichodermapathogen interaction. Int.J.Curr.Microbiol. App.Sci. Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 131 7(2): 2382-2397. Doi: https://doi.org/10.20546/ijcmas.2018.702.291.
  73. Sumartini. 2016. Efikasi campuran minyak cengkeh dan ekstrak biji mimba untuk pengendalian penyakit karat (Phakopsorapachyrhizi) pada kedelai (Glycine max). J. HPT Tropika. 16(1): 82 – 89.
  74. Karuppiah V, Sun J, Li T, Vallikkannu M, & Chen J. 2019. Co-cultivation of Trichoderma asperellum GDFS1009 and Bacillus amyloliquefaciens 1841 causes differential gene expression and improvement in the wheat growth and biocontrol activity. Frontiers in Microbiology, 10.
  75. Hewedy OA, Abdel Lateif KS, Seleiman MF, Shami A, Albarakaty FM, & El-Meihy MR. 2020. Phylogenetic diversity of Trichoderma strains and their antagonistic potential against soil-borne pathogens under stress conditions. Biology 9(8), 189.
  76. Anam GB, Reddy MS, & Ahn YH. 2019. Characterization of Trichoderma asperellum RM-28 for its sodic/saline-alkali tolerance and plant growth promoting activities to alleviate toxicity of red mud. Sci. Total Environ. 662: 462–469.
  77. Shang J, Liu B, & Xu Z. 2020. Efficacy of Trichoderma asperellum TC01 against anthracnose and growth promotion of Camellia sinensis seedlings. Biol. Control. 143: 104205.
  78. Alimudin, Syamsiah M, & Raamli . 2017 Aplikasi pemberian ekstrak bawang merah (Allium cepa L.) terhadap pertumbuhan akar stek batang bawah mawar (Rosa sp.) varietas malltic. J. Agroscience. 17(1): 194 -202.
  79. Putri MM & Damayanti TA. 2020. Utilization of plant extracts to suppress Squash Mosaic Virus infection on ridged gourd (Luffa acutangula [L.Roxb]). J. HPT Tropika. 20(2): 108-115 . DOI : 10.23960/J.Hptt.220108-115. Buku Ajar PENGELOLAAN PENYAKIT TANAMAN TERPADU 132
  80. Hayati I, Wiyono S, Widodo, & Sobir. 2019. Organic fertilizer amendments reduce disease severity of Phytophthora palmivora root rot of duku (Lansium domesticum) seedlings. J. HPT Tropika. 19(2): 143– 148. DOI : 10.23960/J.Hptt.219143-148.
  81. Soesanto L, Mugiastuti E, Suyanto A, & Rahayuniati RF. 2020. Application of raw secondary metabolites from two isolates of Trichoderma harzianum against anthracnose on red chili pepper in the field. J. HPT Tropika. 20(1): 19–27. DOI : 10.23960/J.Hptt.12019-27.
  82. Kurniawati S, Mutaqin KH, & Giyanto. 2015. Eksplorasi dan uji senyawa bioaktif bakteri agensia hayati untuk pengendalian penyakit kresek pada padi. J. HPT Tropika. 15 (2): 170 – 179.