DAFTAR PUSTAKA

BAHAN DAN METODE

Agrios. 1996.Ilmupenyakittumbuhan.GadjahMada University Press Yogyakar- ta. Agrios GN.1997. Plant pathology 4th Ed. Academic Press.Inc. New York. USA.

502p

Aryantha INP, Nganro NR, Sukrasno,Nandina E. 2002. Pengembangan dan pene- rapan pupuk mikroba dalam sistem pertanian organik. diseminarkan pada seminar “The minimization of fertilizer usage”, Menristek-BPPT 6 Mei 2002. Jakarta.

[ATTRA] Appropriate technology transfer for rural area. 1998. Compost teas for plant disesase control. http//www.Attra.org/Attra-pub/PDF/Comptea.pdf. {Mei 2007}

Babadoost M. 2004. Phytophtora blight: a serious threat to cucurbit industries. American Phytopatological Society, St. Paul, MN.

Bintoro HMH, Saraswati R, ManoharaD, TaufikE, PurwaniJ. 2008. Pestisida organik pada tanaman lada. Laporan akhir Kerjasama Kemitraan Penelitian Pertanian antara Perguruan Tinggi dan Badan Litbang Pertanian (KKP3T). Bintoro HMH, ManoharaD, PurwaniJ. 2009. Pestisida organik pada tanaman lada.

Laporan akhir Kerjasama IPB dan Badan Litbang Pertanian (KKP3T). Bonanomi G,Antignani V,Pane C, dan Scala F.. 2007. Suppression of soilborne

fungal diseases with organic amendments. Journal Of Plant Pathology 89 (3):311-324.

Charles LB., Benny DB, Bruton, Marisa MW, Melinda R. 1995. Phytophthora capsici zoospore infection of pepper fruit in various physical enviroment. Departement of Agronomy and Horticulture, New Mexico State University, Las Cruces Nm 88003.

Chet I, Inbar J. 1994.Biological control of fungal pathogen. Appl.Biochem. Biotechnol 48: 7-43.

CPIS. 1992. Teknikpembuatankomposdarisampahrumahtangga. Buku pan- duanteoridanaplikasi.Hasilpenelitianpadapusatpercobaandanpelatihanpengo mposan, RangunanJakarta.

Dalzell, HW Biddlestone, AJ, Gray KR and. Thurairajan K. 1987. Soil management: compost production and use in tropical and sub tropical envi- roments. FAO, Rme. Soil Bull. (56):175-177.

Deng SP, Tabatabai A. 1997. Effect of tillage and residue management on enzyme activities in soils: III. Phosphatases and arylsulphatase. Biol. Fertil. Soil

24:141-146.

Djoefrie, HMH, Sudarman M. 1996. Pemanfaatan campuran ampas sagu dengan kotoran sapi sebagai media pembibitan kelapa sawit. Dalam H.N. Haska, A.

Rasyad, M.H.B. Djoefrie, B. Haryanto, A.Z.F. Yasin, H. Henanito, C. Jose, Dan F. Resthadi (Eds.). Presiding Simposium Nasional Sagu III. Pekanbaru,27-28 Februari 1996. 103-104.

Enari T M. 1983. Microbial cellulases.In M. Forgarty (Ed).Microbial enzymes and biotechonology.Appl Science. London.

Eriksson KEL, Blanchette RA,.Ander P. 1989. Microbial and enzymatic degradation of wood components. Spriger-verlag Heildeberg. New York.

Erwin DC, Ribeiro OK. 1996. Phytophthora: diseases worldwide. APS Press, StPaul, Minnesota.

Erwiyono R. 1994. Pengaruhpemberianpupukkandangdanaerasiterhadapmutukomposlimbahorg

anikpabrikkertas.PusatPenelitianBioteknologi Per-kebunan Bogor. J. Mikrobiologi Indonesia 2(2):30.

Flach, M. 1997. Sago palm, Metroxylon Sago Rottb. International Plant Genetic Resources Institute. Rome Italy. 76p.

Gaur A C.1982. Compost. Organic recycling improving soil fertility through organic recycling FAO/UNDP.Regional Project RAS/77/004. Project Field Document (13):7-14.

Goyal S. Dhull SK, Kapoor KK. 2005. Chemical and biological changes during composting of differentorganic wastes and assesment of compost maturity. Biores Tech 96: 1584-1591.

Gunalan. 1996. Penggunaan mikroba bermanfaat pada bioteknologi tanah berwa- wasan lingkungan. Majalah Sriwijaya 32 (2):1-9.

Hadipoentyanti E, Agus R,. Tombe M, Ludi M.,Manohara D, Rizal M. 2004. Hasil-hasil penelitian mendukung agribisnis panili. makalah utama. Prosi- ding Simposium IV Hasil Penelitian Tanaman Perkebunan. Bogor. 28- 30 Sept.2004.

Hakim, N dan Agustian. 2008. Budidaya Tithoniadan pemanfaatannya sebagai sumber bahan organik dan unsur hara untuk tanaman hortikultura di lapa- ngan. Laporan Penelitian Tahun II HB XI. Proyek Peningkatan Penelitian Perguruan Tinggi DP3M Ditjen Dikti. Unand. Padang.

Hardjo S, Indrasti NS, Bantacut T. 1989.Pemanfaatanlimbahindustripertanian.DepartemenPendidikandan

Kebudayaan.DirektoratJenderalPendidikanTinggi. PAU PangandanGizi IPB. Bogor.

Hartatik W, Widowati LR. 2006. Pupuk kandangdalam Simanungkalit RDM, Suriadikarta DA, Saraswati R, Setyorini D, Hartatik W, 2006. Pupuk or- anikdanpupukhayati.BalaiBesarLitbangSumberdayaLahanPertanian.

Hartatik W. 2007. Tithonia diversifolia sumber pupuk hijau. Warta Penelitian dan Pengembangan Pertanian 29 (5):3-5.

Heck JX. Plinho FH. Marco AZA. 2002. Cellulase and xylanase production by isolated amazon bacillus strain using soybean industrial residue based solid state cultivation. Brazil J Microbiol 33:213-218.

Heerden I, Cronje C, Swart SH, Kotze JM. 2002. Microbial chemical and physical aspects of citrus waste composting. BioresTechnol 81:71-76.

Ilmen MA, Saloheimo, Maija-Leena, Penttila ME. 1997. Regulation of cellulase gene expression in the filamentous fungus trichodermareesei. Appl Environ Microbio 63(4): 1208-1306.

Jagadeesh KS, Kulkarni JH, Krisharaj PU. 2001. Evaluation of role flourescenssiderophore in the biological control of bacterial wilt in tomato using Tn5 mutanst of flurescens Pseudomonas sp. Current Science, 81:882- 883.

Kaderi Husin. 2004. Teknik pengolahan pupuk pelet dari gulma sebagai pupuk majemuk dan pengaruhnya terhadap tanaman padi. Buletin Teknik Pertanian 9(2): 47-49.

Lei F, VandergheynstJS, Fei L. 2002.Community structure analysis of rice straw and grape pomace composting using phospolipid fatty acid analysis In: ASAE Annual International Meeting, Orlando FL, USA 12-16 July 1998. Lemos MA, Teixiera JA, Dominigues MRM, Mota M, Gama FM. 2003. The

Enhancement of cellulolytic activity of cellobiohydrolase and endoglu- canase by addition of cellulose binding domains derived from trichodermareesei. EnzymMicrobTecnol 32: 35-40.

Lizzi Y, Rogerro JP Coulomb, PJ. 1995. Quantitative resistance to

Phytophorainfestansin patato; A Case Study for QTL Mapping in Allogamous Plant Species. Genetics 137: 67-77.

Louws FJ, Holmes GJ, Ristaino. 2002. Phytophthora blight of pepper and cucurbits. vegetable disease information note 27. College of Agriculture and Life Science, Plant Pathology Extension, North California State Univer- sity:1-4.

Luther G, Palada M, Wang TC, Dibiyantoro J, Ameriana M, Sutoyo, Bimantoro. 2007. Chili integrate disease management rapid rural appraisal in centre Java, Indonesia 5-15 March 2007. AVRDC-The World Vegetable Centre.

Tech Bull. 38 AVRDC Pub.06: 678-253.

Manohara, MustikaIka, SupraptodanWayanLaba. 2003. Eksposedanpameran PHT, Teknologi PHT untukkomoditaslada. Seminar Pengendalian Hama Terpadu, Yogyakarta.

Murbandono. 2000. Membuat kompos. Edisi Revisi. Penebar swadaya, Jakarta. Michel FC, Marsh TJ, Reddy CA. 2002. Bacterial community structure during

yard trimmings composting inInsam H, RiddechN, Klammer S, editor.

Microbiology of composting. Berlin: Springer-Verlag Berlin Heiderberg 25- 42p.

Miller, F. 1991. Biodegradationof Solid Wasteby Composting.In: Martin A.M. Biological degradation of wastes, 1-30p. London:Elsevier.

Nasahi H,Ceppy. 2010. Peran mikroba dalam pertanian organik. Jurusan hama dan penyakit tumbuhan. Fakultas Padjadjaran, Bandung.

Nogochi HK. 2001. Assesment of the allelopathic potential of Ageratum conyzoi- desvarhirtum(Lam). BiologiaPlantarum 44 (2): 309-311.

Nurisamunandar, A. 1999. Pengomposan limbah ampas sagu (Metroxylon sago

rottb ) dengan aktivator dan waktu pengomposan yang berbeda pengaruhnya terhadap pertumbuhan selada (Lactuta Sativa) serta aspek sosial ekononi- nya. Tesis Pascasarjana IPB. Bogor.

Nyasim MA, Niang, AAmadalo B, Obonyo E, Jama B. 1997. Using the wild sunflower Tithonia in Kenya for soil fertility and crop yield improvement.ICRAF. Nairobi, Kenya.

Oelke LM, Bosland PW, Steiner R. 2003. Differentitation of race spesific resistance to Phytophthora root rot and foliar blight in Capsicum annum. J Am Soc Hortic Sci 128:213-218.

Parra G, Ristaino G. 1998. Intensitivity to redomil gold (mefenoxam) found among field isolated Phytophthora capsici causing phytophthora blight on bell paperin North Carolina and New Jersey. Plant Dis (82):701-711.

Pramono A, Mulyono S, Anshori A. 2003. PemanfaatanBahanOrganikdanMik-

robia Tanah UntukMeningkatkanProduktivitasLahanSawahTadahHujan.Prosiding

Seminar NasionalPengelollanLingkunganPertanian.Surakarta 21 Oktober 2003.

Rajbanshi SS, , Sakamoto Endo H, Inubushi K. 1998. Stabilization of chemical and biochemical characteristics of grass straw and leaf mix during in vessel composting with and without seeding material. Soil Sci Plant Nutrition 44: 485-195.

Rawiniwati W. 1998.Peranbeberapa fungi selulotikpadalajupengomposanlim-bah tanamanpadajagung (Zea mays).TesisPascasarjanaInstitutPertanian Bogor. Reese ET, Siu RGH, Levinson HS. 1950. The biological degradation of soluble

cellulose and derivates and its relationship to the mechanism of celullosehydrolisis. J. bacterial 59: 485-497.

Rochaeni A, Deni R, Karunia HP. 2003. Pengaruhagitasiterhadap proses pengomposan sampahorganik. Infomatek 5(4):177-186.

Rumawas F, Astono A, Aziz SA, Ririhena RE. 1996. Utilizing sago press cake as compost. In Proceeding of the 6th International Sago Symposium. Eds. Jose, C. and Rasyad, A. pp 165-169. Riau University, Pekan Baru, Indonesia. Sanchez-Monedero MA, Roig A, Paredes C, Bernal Mp. 2001. Nitrogen Trans-

formation during organic waste composting by the rutgers system and its effect on pH, EC and maturity of composting mixtures. Biores Technol78:301-308.

Saraswati R, Santosa E, Yuniarti E. 2006. Organisme perombak bahan organik

dalam Simanungkalit RDM, Suriadikarta DA, Saraswati R, Setyorini D,

Hartatik W, 2006. Pupukorganikdanpupukhayati.BalaiBesarLitbangSumberdayaLahanPertania

n. BalaiPenelitiandanPengembanganPertanian Bogor.

Sharma VK, Canditelli M, Fortuna F, Carnacchi G. 1997. Processing of urban and agroindustrial residues by aerobic composting.Energy Concerns.Mgmt 38:453-478.

Sinaga, MS. 2003. Dasar-dasarIlmupenyakittumbuhan.PenebarSwadaya Jakar-ta. Soulie MC, Tronton D, Malfatti P, Bompeix G, Laval-Martin D. 1989. Post-

infectional change of lipid and photosynthesis in Lycopersicumesculentum Susceptible to PPhytophthora.capsici. Plant Sci 61: 169-178.

Stevenson FJ. 1994. Humus chemistry, genesis, composition, reaction. John Wil- ley& Sons. New York.

Summers MD, Blunk SL, Jenkins BM. 2003. How straw decomposes: implication for straw bale construction. DRAFT 12/8/2003.

Suriadikarta DA, Setyorini D. 2006. Baku mutu pupuk organik

dalamSimanungkalit RDM, Suriadikarta DA, Saraswati R, Setyorini D,

Hartatik W, 2006. Pupukorganikdanpupukhayati.BalaiBesarLitbangSumberdayaLahanPertania

n. BalaiPenelitiandanPengembanganPertanian Bogor.

Sutedjo. 1999. Pupuk dan Cara Pemupukan. Penerbit Rineka Cipta, Jakarta.

Syamsuddin. 2010.Perlakuanbenihuntukpengendalianpenyakitbusukphyto-phora, peningkatanhasildanmutubenihcabaimerah (Capsicum annuum). Disertasi PascasarjanaInstitutPertanian Bogor.

Syamsudin I. 2002.PengaruhekstrakkomposbokasidankonvensionalterhadappatogenCollet

otrichumcapsici (Syd) Butler &Bisbypenyebabpenyakitantraksosapadacabai [skripsi]. Bogor: Jurusan Hama danPenyakit Tumbu-han, FakultasPertanian, IPB

Wiseman A. 1981. Tropics in enzyme and fermentation.Bio-technologyvol 4. Ellis Harwood Limited. John Willey and Sons. New York.

Yamaguchi I. 1996.Pesticides of microbial origin and application of moleculer biology. Crop protection agents from manure: natural products and analo- gues. The Royal Society Chemistry, London, United Kingdom: 27-49. Zang W, Dick WA, Hointik HAJ. 1996. compost-induceed system acquired

resistance in cucumber to Phytium root rot and antrachnose. Phytopathology 86 (9):1066-1070.

Zitter TA. 1989. Phytophthora blight of cucurbits, pepper, tomato, and egg plant. Departement of Plant Pathology, Cornell University Ithaca, New York. Fact Sheet Page: 736.20 Date 8-1989.

LAMPIRAN

Lampiran1.Hasilanalisisstatistik tinggitanamanumur 1,2,3 MST. Tests of Between-Subjects Effects

Dependent variabel:Tinggitanaman1 MST

Source

Type III Sum of

Squares df Mean Square F Sig.

Corrected Model 5373.754a 13 413.366 1.173 .358 Intercept 9028.167 1 9028.167 25.628 .000 Perlkn 3926.170 11 356.925 1.013 .467 Blok 1447.584 2 723.792 2.055 .152 Error 7750.109 22 352.278 Total 22152.030 36 Corrected Total 13123.863 35

a. R Squared = ,409 (Adjusted R Squared = ,061)

Tests of Between-Subjects Effects Dependent variabel:Tingitanaman 2 MST

Source

Type III Sum of

Squares df Mean Square F Sig.

Corrected Model 59.327a 13 4.564 7.102 .000 Intercept 8664.507 1 8664.507 13484.554 .000 Perlkn 57.910 11 5.265 8.193 .000 Blok 1.417 2 .709 1.103 .350 Error 14.136 22 .643 Total 8737.970 36 Corrected Total 73.463 35

Dependent variabel:Tinggitanaman3 MST

Source

Type III Sum of

Squares df Mean Square F Sig.

Corrected Model 17337.137a 13 1333.626 .780 .673 Intercept 36055.680 1 36055.680 21.079 .000 Perlkn 15647.963 11 1422.542 .832 .612 Blok 1689.174 2 844.587 .494 .617 Error 37630.953 22 1710.498 Total 91023.770 36 Corrected Total 54968.090 35

a. R Squared = ,315 (Adjusted R Squared = -,089)

Lampiran 2. Hasil analisis statistik jumlah daun tanaman cabai umur 1,2,3 MST

Tests of Between-Subjects Effects Dependent variabel:Jumlahdaun1 MST

Source

Type III Sum of

Squares df Mean Square F Sig.

Corrected Model 12.374a 13 .952 5.186 .000 Intercept 1351.788 1 1351.788 7365.272 .000 perlkn 10.839 11 .985 5.369 .000 blok 1.536 2 .768 4.183 .029 Error 4.038 22 .184 Total 1368.200 36 Corrected Total 16.412 35

Tests of Between-Subjects Effects Dependent variabel: Jumlahdaun 2 MST

Source

Type III Sum of

Squares df Mean Square F Sig.

Corrected Model 51.611a 13 3.970 6.367 .000 Intercept 3083.951 1 3083.951 4945.912 .000 perlkn 49.276 11 4.480 7.184 .000 blok 2.336 2 1.168 1.873 .177 Error 13.718 22 .624 Total 3149.280 36 Corrected Total 65.329 35

a. R Squared = ,790 (Adjusted R Squared = ,666)

Tests of Between-Subjects Effects Dependent variabel:Jumlahdaun3 MST

Source

Type III Sum of

Squares df Mean Square F Sig.

Corrected Model 124.038a 13 9.541 4.106 .002 Intercept 6001.084 1 6001.084 2582.739 .000 perlkn 119.929 11 10.903 4.692 .001 blok 4.109 2 2.054 .884 .427 Error 51.118 22 2.324 Total 6176.240 36 Corrected Total 175.156 35

a. R Squared = ,708 (Adjusted R Squared = ,536)

Lampiran3..Hasilanalisisstatistik Kejadianpenyakit (%)padatanamancabai.

Dependent Variable: Kejadianpenyakit

Source

Type III Sum

of Squares df Mean Square F Sig.

Corrected Model _9169,444(a) ₁₃ _705,342 _1,522 _,186

Intercept 52136,111 1 52136,111 112,512 ,000 kompos 6563,889 11 596,717 1,288 ,294 blok 2605,556 2 1302,778 2,811 ,082 Error _10194,444 ₂₂ _463,384 Total 71500,000 36 Corrected Total 19363,889 35

FENNY SALOMINA JENSANURA ASYEREM.The use of bioagentsTricho- dermaspp. and bacteria cellulotic.as decomposer of Ageratum conyzoides var

hirtum (Lam), Tithonia diversifolia (Hamsley) A. Gray and Sago Waste to produce organic fertilizer for Chili (Capsicum annuum L.).Under supervision of H.M.H BINTORODJOEFRIE and DYAH MANOHARA.

Ageratum conzoides var hirtum (Lam), Tithonia diversifolia (Hamsley) A. Gray and waster sago can be used as organic fertilizer or compost. Some isolates of Trichodermaspp. and bacteria cellulotic had been tested as the antagonize agent for controllingPhytophthora capsici(wilt disease on chili). These microorganism were used as decomposer of weeds, A.conyzoideshirtum var (Lam),

T.diversifolia(Hamsley) A. Gray, and sago waste. The aims of the study were to select microbes that has capability to degradation cellulose and able to accelerate the composting process of A.conyzoideshirtum var (Lam), T.diversifolia(Hamsley) A. Gray, and sago waste; and determine the effect of formula compost on plant growth of chili, resistance to infection of P. capsici L and yield of chili. This study was conducted in three phases: 1). Selection of Trichoderma spp and bacteria isolates on Carboxy methyl cellulose (CMC) media, 2). Composting A.cony- zoides var hirtum (Lam), T.diversifolia(Hamsley) A. Gray and sago waste by isolates ofTrichoderma spp and bacteria cellulotic which had been selected; 3). Application of compost formulas on chiliplants. The visualization of cellulase activities on CMC mediawere shown as the clear zone around the colony. Six isolates of Trichoderma spp (PO3, S1, N34, IU, PB 13, SKM) have the clear zone ratio range between 3.0 -5.3 and six isolates of bacteria (St109, Sk7, Cm58, Sk14, Sk 10 and St18) havethe clear zone ratio range between 2.6 to 5.4; were selected to decompose weeds and sago waste.The result showed that Trichoderma spp and bacteria cellulotic inoculantsor themixed of them were able to reduce the duration of composting process from 17–18 days to 13-15 days. The products of compost formula are appropriate with the SNI19-7030-2004 and standards minimumof technical organicfertilizer.Application of compost formulas and goat manure on chili plants affected the growth, the disease attacked and the yield of chili. The application of formula D{goat manure+A. conyzoides var hirtum (Lam)+ sago waste} caused the diseaseattacked about 33.3%but the yield was 524,56 g. While the diseaseattackedatgoat manuretreatment was 16.67% and the yield was 132.3 g. Formula D increased the yield of chili 3.96 times compare than goat manure only.

PENDAHULUAN

Dalam dokumen The use of bioagentsTrichodermaspp. and bacteria cellulotic.as decomposer of Ageratum conyzoides var hirtum (Lam), Tithonia diversifolia (Hamsley) A. Gray and Sago Waste to produce organic fertilizer for Chili (Capsicum annuum L.). (Halaman 63-73)