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All Journal Jurnal Ilmu Tanah dan Lingkungan (Journal of Soil Science and Environment) ComEngApp : Computer Engineering and Applications Journal TEKNIK INFORMATIKA Jurnal Akuakultur Rawa Indonesia AGRITROP Jurnal Ilmu Lingkungan Jurnal Lahan Suboptimal Jurnal Agrista Journal of Tropical Soils Sains Tanah Techno: Jurnal Penelitian Journal of Degraded and Mining Lands Management AGRIVITA, Journal of Agricultural Science Jurnal Agroekoteknologi Planta Tropika IJFAC (Indonesian Journal of Fundamental and Applied Chemistry) JPSriwijaya Science and Technology Indonesia JOURNAL OF INFORMATICS AND TELECOMMUNICATION ENGINEERING KACANEGARA Jurnal Pengabdian pada Masyarakat AGROMIX Seminar Nasional Lahan Suboptimal Klorofil: Jurnal Penelitian Ilmu-Ilmu Pertanian Jurnal ABDINUS : Jurnal Pengabdian Nusantara Buletin Palma Jurnal Tanah dan Iklim SRIWIJAYA JOURNAL OF ENVIRONMENT Jurnal AGRISEP: Kajian Masalah Sosial Ekonomi Pertanian dan Agribisnis Journal of Smart Agriculture and Environmental Technology
NUNI GOFAR
Universitas Sriwijaya
Agriculture, Biological Sciences & Forestry Biochemistry, Genetics & Molecular Biology Chemical Engineering, Chemistry & Bioengineering Chemistry Civil Engineering, Building, Construction & Architecture Computer Science & IT Earth & Planetary Sciences Economics, Econometrics & Finance Education Energy Engineering Environmental Science Immunology & microbiology Industrial & Manufacturing Engineering Law, Crime, Criminology & Criminal Justice Materials Science & Nanotechnology Neuroscience Physics Public Health Veterinary Other

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IMPROVEMENT OF RICE GROWTH AND PRODUCTIVITY THROUGH BALANCE APPLICATION OF INORGANIC FERTILIZER AND BIOFERTILIZER IN INCEPTISOL SOIL OF LOWLAND SWAMP AREA Marlina, Neni; Gofar, Nuni; Subakti, Abdullah Halim Perdana Kusuma; Rohim, Abdull Madjid
AGRIVITA, Journal of Agricultural Science Vol 36, No 1 (2014)
Publisher : Faculty of Agriculture University of Brawijaya and Indonesian Agronomic Assossiation

Show Abstract | Download Original | Original Source | Check in Google Scholar

Abstract

The objective of this study was to obtain a proper balance dose between biofertilizer and inorganic fertilizer in order to increase the growth and yield of rice in Inceptisol soil of lowland swamp origin. Biofertilizer was made by enriching straw compost with N2 interceptor bacteria, phosphate solvent bacteria and growth stimulator bacteria isolated from swamp lowland in South Sumatra. This study was conducted from November 2012 to March 2013 in a greenhouse. The design used was completely randomized design (CRD) factorial, with two treatment factors consisting of inorganic fertilizer (0,25, 50, 75 and 100% recommended dosage) and biofertilizer (0, 100, 200, 300, 400 and 500 kg.ha-1). The results showed that the best treatment in term of plant height at 8 weeks after planting (WAP), the maximum number of tillers, number of productive tillers, number of grains per panicle and weight of milled dry rice were obtained in combination of 75% inorganic fertilizer and 300 - 400 kg.ha-1biofertilizer.Keywords: biofertilizer, inorganic fertilizer, lowland rice
APLIKASI JENIS PUPUK ORGANIK PADA TANAMAN SAWI (Brassica juncea L.) Marlina, Neni; Rosmiah, Rosmiah; Gofar, Nuni Gofar
Klorofil: Jurnal Penelitian Ilmu-Ilmu Pertanian Vol 9, No 2 (2014): Jurnal Ilmu-Ilmu Agroteknologi Klorofil
Publisher : Universitas Muhammadiyah Palembang

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.32502/jk.v9i2.115

Abstract

Penelitian ini bertujuan untuk mendapatkan jenis pupuk organik yang tepat dalam meningkatkan tanaman sawi. Penelitian ini telah dilaksanakan di kebun petani Jalan Jenderal A Yani 13 Ulu Palembang pada bulan April sampai dengan Juli 2014. Rancangan yang digunakan pada penelitian ini adalah Rancangan Acak Kelompok (RAK) dengan lima perlakuan yang diulang lima kali. Perlakuannya adalah tanpa pupuk organik dan pupuk anorganik, pupuk anorganik (NPK dengan dosis 100 kg urea, 100 kg SP-36, dan 50 kg KCl ha-1), pupuk kandang kotoran ayam (3 ton ha-1) , kompos jerami (3 ton ha-1) dan pupuk organik hayati (300 kg ha-1). Hasil penelitian menunjukkan bahwa aplikasi jenis pupuk organik hayati sebanyak 300 kg ha-1 memberikan pertumbuhan dan produksi terbaik dengan ditunjukkan berat segar sebanyak 54,00 g per polybag.
KERAGAMAN BEBERAPA SIFAT KIMIA DAN BIOLOGI TANAH PADA BERBAGAI TIPE PENGGUNAAN LAHAN RAWA LEBAK GOFAR, NUNI
AGRITROP Vol. 26, No. 2 Juni 2007
Publisher : AGRITROP

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Abstract

The purposes of this study were to study: 1) the influence of agricultural land use on some swamp soil chemical (soil pH, Organic C content, N-total, and P-total) and biological (population of bacteria, fungi, and actinomycetes) properties, and 2) correlation between soil microbial population and Organic C content, N-total as well as P-total. Based on the results of field observation, it was determined 6 plant commodities with different length of land use as treatments and secondary forest as control. The results of this study showed that: 1) Differences in land use resulted in different soil chemical (soil pH, Organic C content, N-total, and P-total) and biological (population of bacteria, fungi, and actinomycetes) properties, 2) Soil organic C, N-total and P-total content together significantly affected on population of bacteria and fungi, but did not affected on actinomycetes population. The magnitudes of Soil organic C, N-total and P-total influence on bacteria, fungi, and actinomycetes population were 69,8 %, 59,8 % and 49,7 %, respectively, 3) as soil organic C and P-total contents were constant, soil N-total content significantly affected on population of bacteria and fungi, but did not affected on actinomycetes population, 4) Population of bacteria, fungi and actinomycetes was highly correlated with soil organic C and N-total content, but was not correlated with soil P-total content, 5) the most microbial variation was found on soil collected from rubber plantation, followed by orange and secondary forest.
N Absorption in Nontidal Rice Fields Treated with Microalgae and Nitrogen Fertilizer Application Buyana, Nova Tri; Gofar, Nuni; Rohim, A. Madjid
PLANTA TROPIKA: Jurnal Agrosains (Journal of Agro Science) Vol 7, No 1 (2019)
Publisher : Universitas Muhammadiyah Yogyakarta

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.18196/pt.2019.089.19-25

Abstract

Nutrient elements that are needed by plants during its growth and development is nitrogen. Nitrogen deficiency can cause plants to become necrosis so that plants are not able to photosynthesize well, thus result in lack of food needed by plants. Microalgae can provide nitrogen for rice crops due to its activity. The aim of this research was to know the effect of microalgae from nontidal swamp land to reduce the use of inorganic N fertilizer in paddy field. The study was conducted from January to April 2017, using factorial completely randomized design with two factors, namely isolate and dosage of nitrogen fertilizer. The first factor is the type of the isolate (I), consisting of cultures from the area of rice cultivation (I1), the culture originating from the area around the rice fields (I2) and the cultures of area without rice cultivation (I3) area. The second factor is the dose of nitrogen fertilizer (N) consisting of 0%, 50% and 100%. The results showed that the treatment of the isolate (I) or dosage of nitrogen fertilizer had a significant effect on the weight of 1000 filled grains and the weight of empty grains in the generative phase of rice plant. The interaction between both treatments had a significant effect on the generative (production) phase. The microalgae culture from area of rice cultivation (I1) can contribute nitrogen requirement of 16.23% - 48.71% with an abundance of 7.48 cells ml-1, with the requirement of rice plant nitrogen fertilizer of 45-135 kg ha-1.
N Absorption in Nontidal Rice Fields Treated with Microalgae and Nitrogen Fertilizer Application Buyana, Nova Tri; Gofar, Nuni; Rohim, A. Madjid
PLANTA TROPIKA: Jurnal Agrosains (Journal of Agro Science) Vol 7, No 1 (2019)
Publisher : Universitas Muhammadiyah Yogyakarta

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.18196/pt.2019.089.19-25

Abstract

Nutrient elements that are needed by plants during its growth and development is nitrogen. Nitrogen deficiency can cause plants to become necrosis so that plants are not able to photosynthesize well, thus result in lack of food needed by plants. Microalgae can provide nitrogen for rice crops due to its activity. The aim of this research was to know the effect of microalgae from nontidal swamp land to reduce the use of inorganic N fertilizer in paddy field. The study was conducted from January to April 2017, using factorial completely randomized design with two factors, namely isolate and dosage of nitrogen fertilizer. The first factor is the type of the isolate (I), consisting of cultures from the area of rice cultivation (I1), the culture originating from the area around the rice fields (I2) and the cultures of area without rice cultivation (I3) area. The second factor is the dose of nitrogen fertilizer (N) consisting of 0%, 50% and 100%. The results showed that the treatment of the isolate (I) or dosage of nitrogen fertilizer had a significant effect on the weight of 1000 filled grains and the weight of empty grains in the generative phase of rice plant. The interaction between both treatments had a significant effect on the generative (production) phase. The microalgae culture from area of rice cultivation (I1) can contribute nitrogen requirement of 16.23% - 48.71% with an abundance of 7.48 cells ml-1, with the requirement of rice plant nitrogen fertilizer of 45-135 kg ha-1.
Synergism of Wild Grass and Hydrocarbonoclastic Bacteria in Petroleum Biodegradation Gofar, Nuni
JOURNAL OF TROPICAL SOILS Vol 18, No 2: May 2013
Publisher : UNIVERSITY OF LAMPUNG

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.5400/jts.2013.v18i2.161-168

Abstract

The concept of plants and microbes utilization for remediation measure of pollutant contaminated soil is the newest development in term of petroleum waste management technique. The research objective was to obtain wild grass types and hydrocarbonoclastic bacteria which are capable to synergize in decreasing petroleum concentration within petroleum contaminated soil. This research was conducted by using randomized completely block design. This research was conducted by using randomized completely block design. The first factor treatments were consisted of without plant, Tridax procumbens grass and Lepironia mucronata grass. The second factor treatments were consisted of without bacterium, single bacterium of Alcaligenes faecalis, single bacterium of Pseudomonas alcaligenes, and mixed bacteria of Alcaligenes faecalis with P. alcaligenes. The results showed that mixed bacteria (A.  faecalis and P. alcaligenes) were capable to increase the crown and roots dry weights of these two grasses, bacteria population, percentage of TPH (total petroleum hydrocarbon) decrease as well as TPH decrease and better pH value than that of single bacterium. The highest TPH decrease with magnitude of 70.1% was obtained on treatment of L. mucronata grass in combination with mixed bacteria.[How to Cite: Gofar N. 2013.Synergism of Wild Grass and Hydrocarbonoclastic Bacteria in Petroleum Biodegradation. J Trop Soils 18 (2): 161-168. Doi: 10.5400/jts.2013.18.2.161][Permalink/DOI: www.dx.doi.org/10.5400/jts.2013.18.2.161]REFERENCESBello YM. 2007. Biodegradation of Lagoma crude oil using pig dung.  Afr J Biotechnol 6: 2821-2825.Gerhardt KE, XD Huang, BR Glick and BM Greenberg. 2009. Phytoremediation and rhizoremediation of organic soil contaminants: Potential and challenges. Plant Sci 176: 20-30.Glick BR. 2010. Using soil bacteria to facilitate phytoremediation.  Biotechnol Adv 28: 367-374. Gofar N. 2011.  Characterization of petroleum hydrocarbon decomposing fungi isolated from mangrove rhizosphere.  J Trop Soils 16(1): 39-45. doi: 10.5400/jts.2011.16.1.39Gofar N. 2012. Aplikasi isolat bakteri hidrokarbonoklastik asal rhizosfer mangrove pada tanah tercemar minyak bumi. J Lahan Suboptimal 1: 123-129 (in Indonesian). Hong WF, IJ Farmayan, CY Dortch, SK Chiang and JL Schnoor. 2001. Environ Sci Technol 35: 1231.Khashayar T and T Mahsa. 2010.  Biodegradation potential of petroleum hydrocarbons by bacterial diversity in soil. Morld App Sci J 8: 750-755.Lal B and S Khanna. 1996. Degradation of Crude Oil by Acinetobacter calcoaceticus and Alcaligenes odorans, J Appl Bacteriol 81: 355- 362.Mackova M, D Dowling and T Macek. 2006. Phytoremediation and rhizoremediation: Theoretical background. Springer, Dordrecht, Netherlands. 300 p. Malik ZA and S Ahmed.  2012. Degradation of petroleum hydrocarbons by oil field isolated bacterial consortium. Afr J Biotechnol 11: 650-658.Mendez MO and RM Maier. 2008. Phytostabilization of mine tailings in arid and semiarid environment an emerging remediation technology. Environ Health Prospect 116: 278-283.Milic JS, VP Beskoski, MV Ilic, SM Ali, GDJ Cvijovic and MM Vrvic.  2009.  Bioremediation of soil heavily contaminated with crude oil and its products: composition of the microbial consortium. J Serb Chem Soc  74: 455-460.Mukre AM, AA Hamid, A Hamzah and WM Yusoff.  2008.  Development of three bacteria consortium for the bioremediation of crude petroleum-oil in contaminated water. J Biol Sci 8: 73-79.Ndimele PE. 2010. A review on the phytioremediation of petroleum hydrocarbon. Pakistan J Biol Sci 12:  715-722.Newman LA and CM Reynolds.  2004.  Phytoremediation of organic compounds. Curr Opin Biotechnol  15: 225-230.Onwuka F, N Nwachoko, and E Anosike. 2012. Determination of total petroleum hydrocarbon (TPH) and some cations (Na+, Ca2+ and Mg2+) in a crude oil polluted soil and possible phytoremediation by Cynodon dactylon L (Bermuda grass). J Environ Earth Sci 2: 12-17.Pezeshki SR, MW Hester, Q Lin and JA Nyman.  2000.  The effect of oil spill and clean-up on dominant US Gulf Coast Marsh Macrophytes: a review.  Environ Pollution 108: 129-139.Pikoli MR, P Aditiawati and DI Astuti. 2000. Isolasi bertahap dan identifikasi isolat bakteri termofilik pendegradasi minyak bumi dari sumur bangko. Laporan Penelitian pada Jurusan Biologi, ITB, Bandung (unpublished, in Indonesian).Pilon-Smits E and JL Freeman. 2006. Environmental cleanup using plants: biotechnological advances and ecological considerations. Front Ecol Environ 4: 203-10. Rahman KSM, JT Rahman, P Lakshmanaperumalsamy, and IM Banat. 2002. Towards efficient crude oil degradation by a mixed bacterial consortium. Bioresource Technol 85: 257-261.Rossiana N.  2004. Oily Sludge Bioremediation with Zeolite and Microorganism and It’s Test with Albizia Plant (Paraserianthes falcataria) L (Nielsen). Laboratory of Environmental Microbiology, Department of Biology Padjadjaran University, Bandung (unpublished).Rossiana, N.  2005.  Penurunan Kandungan Logam Berat dan Pertumbuhan Tanaman Sengon (Paraserianthes falcataria L (Nielsen) Bermikoriza dalam Media Limbah Lumpur Minyak Hasil Ekstraksi. Laboratorium Mikrobiologi dan Biologi Lingkungan Jurusan Biologi Fakultas Matematika dan Ilmu Pengetahuan Alam Universitas Padjajaran, Bandung  (in Indonesian).Sathishkumar M, B Arthur Raj, B Sang-Ho, and Y Sei-Eok. 2008. Biodegradation of crude oil by individual bacterial strains and a mixed bacterial consortium isolated from hydrocarbon contaminated areas clean. Ind J Biotechnol 36: 92-96.Shirdam R, AD Zand, GN Bidhendi and N Mehrdadi.  2008. Phytoremediation of hydrocarbon-contaminated soils with emphasis on effect of petroleum hydrocarbons on the growth of plant species. Phytoprotection 89: 21-29.Singer AC, DE Crowley and IP Thompson.  2003.  Secondary plant metabolites in phytoremediation and biotransformation. Trends Biotechnol 21: 123-130.Singh A and OP Ward. 2004.  Applied Bioremediation and Phytoremediation. Springler, Berlin, 281p.Surtikanti H and W Surakusumah.  2004.  Peranan Tanaman dalam Proses Bioremediasi Oli Bekas dalam Tanah Tercemar.  Ekol Biodivers Trop  2: 48-52 (in Indonesian).Wenzel WW.  2009.  Rhizosphere processes and management in plant-assisted bioremediation (phytoremediation) of soil.  Plant Soil 321: 385-408.Widjajanti H, I Anas, N Gofar and MR Ridho.  2010.  Screening of petroleum hydrocarbons degrading bacteria as a bioremediating agents from mangrove areas. Proceeding of International Seminar, workshop on integrated lowland development and management, pp. C7 1-9.Widjajanti H.  2012. Bioremediasi Minyak Bumi Menggunakan Bakteri dan Kapang Hidrokarbonoklastik dari Kawasan Mangrove Tercemar Minyak Bumi. [Disertasi]. Universitas Sriwijaya (in Indonesian).
Stimulate The Growth of Rice Using Endophytic Bacteria from Lowland Rice Plant Tissue Nuni Gofar; Hary Widjajanti; Neni Marlina
Sains Tanah - Jurnal Ilmu Tanah dan Agroklimatologi Vol 12, No 2 (2015)
Publisher : Faculty of Agriculture, Universitas Sebelas Maret

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.15608/stjssa.v12i2.250

Abstract

Exploration and selection of endophytic bacteria from healthy food crops grown in lowland ecosystem is important to be conducted in order to get growth-stimulating endophytic bacteria at soil with low fertility level so that capable to optimize initial growth of food crops and subsequently can increase productivity level of lowland soil.The research objective was to isolate and to test the IAA-producing endophytic bacteria isolate in stimulating the rice crop growth at lowland area. Endophytic bacteria are isolated from tissues of rice, corn and peanut crops which grown at shallow swamp land in Ogan Ilir and Ogan Komering Ilir Districts, South Sumatra, Indonesia. There was nine isolates of nitrogen-fixer endophytic bacteria that capable to contribute IAA phytohormone into their growth media. The P31 isolate from rice crop tisssue of 2 months old produce the best rice sprouts than other isolates. This isolate can contribute of about 10 mg kg-1 IAA to its growth medium  and increase the crowns dry weight and the roots dry weight respectively with magnitudes of 133% and 225% compared to control treatment. Concentration and absorbtion of N for rice crops innoculated with P31 isolates had increased by 169% and 400%, recpectively. The P31 isolates had been identified as Burkholderia pseudomallei (also known as Pseudomonas pseudomallei).
EKSPLORASI BAKTERI ANTAGONIS ASAL JARINGAN DAN RIZOSFER TANAMAN KARET UNTUK MENEKAN PERTUMBUHAN BAKTERI PROTEOLITIK PADA BAHAN OLAHAN KARET (BOKAR) Nuni Gofar; Munawar Munawar; Hary Widjajanti; Angga Prasetya Mulya
Jurnal Ilmu Tanah dan Lingkungan Vol 16 No 2 (2014): Jurnal Tanah dan Lingkungan
Publisher : Departemen Ilmu Tanah dan Sumberdaya Lahan, Fakultas Pertanian, IPB University

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (432.176 KB) | DOI: 10.29244/jitl.16.2.61-66

Abstract

Lateks merupakan komoditas pertanian andalan dan merupakan sumber penerimaan devisa negara Indonesia yang cukup penting, namun pada saat penyimpanannya menyumbangkan bau tidak sedap ke udara. Penelitian ini bertujuan untuk mengeksplorasi bakteri antagonis asal jaringan dan rizosfer tanaman karet yang mampu menekan pertumbuhan mikroba proteolitik penyebab bau tidak sedap pada bahan olahan karet (bokar). Bakteri proteolitik penyebab bau tidak sedap diisolasi dari berbagai masa simpan bokar. Bakteri antagonis diisolasi dari jaringan dan rizosfer tanaman karet. Kemampuan bakteri antagonis menekan pertumbuhan bakteri proteolitik dilakukan dengan uji daya hambat dalam medium agar (NA). Diameter zona bening yang terbentuk merupakan indikasi kemampuan bakteri antagonis dalam menghambat aktivitas bakteri proteolitik. Dari hasil penelitian ini diperoleh 2 isolat bakteri yang berpotensi dikembangkan sebagai bakteri antagonis penghambat aktivitas bakteri proteolitik perombak bokar dalam proses penyimpanan. Kedua bakteri antagonis tersebut adalah isolat D1U1 yang berasal dari daun tanaman karet dan isolat A2U2 yang berasal dari akar tanaman karet, yang menghasilkan rata-rata zona hambat terluas berturut-turut berdiameter 11.37 dan 11.29 mm.
Pemanfaatan Berbagai Jenis Pupuk Hayati pada Budidaya Tanaman Jagung(Zea mays. L) Efisien Hara di Lahan Kering Marginal Yopie Moelyohadi; M. Umar Harun; Renih Hayati; Nuni Gofar
Jurnal Lahan Suboptimal : Journal of Suboptimal Lands Vol. 1 No. 1 (2012)
Publisher : Research Center for Sub-optimal Lands (PUR-PLSO), Universitas Sriwijaya

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (402.47 KB) | DOI: 10.33230/JLSO.1.1.2012.6

Abstract

Moelyohadi et al., 2012. The Use of  Various Types of Biofertilizers on Cultivation of  Nutrient Efficient Corn Genotypes(Zea mays L.  in Marginal Dry Land. JLSO 1(1):31-39.The study aimed at  obtaining nutrient efficient corn genotypes that give the best response to various types of biological fertilizers at low-level doses of chemical fertilizer in marginal drylands. This study was conducted in the field trials of Agro Techno Park (ATP), the Ministry of Research and Technology, South Sumatra from May to September 2011. The experimental design used was SplitPlotdesign  with three replications. The main plot treatments consisted of: (H0): without biofertilizer, (H1): biofertilizer:-mycorrhizae and (H2): BPF biological fertilizers. Subplot treatments, consisting of three corn genotypes for the selection of efficient nutrient properties, are genotypes  B-41 (G1), L-164 (G2), S-194 (G3)  and onehybrid variety:BISI-816 (G4) as agenotypecomparator. Alltreatmentunitswere givenlow dosesof chemicalfertilizerthat is 50% of theATPstandarddose(200kgUrea, SP-36 50kgand 25kgKClha-1).  The results showed that mycorrhizal fertilizer produced the highest corn production, which is 6.08 ton dry seed / acre and genotype B-41 shows a more adaptive growth in marginal dry land with a production  of 7.27 tons of dry  seed /acre  and the combined treatment of mycorrhizal fertilizer and genotype B-41 gave the highest production  of 8.57 tons of dry seed / acre 
Aplikasi Isolat Bakteri Hidrokarbonoklastik asal Rizosfer Mangrove pada Tanah Tercemar Minyak Bumi Nuni Gofar
Jurnal Lahan Suboptimal : Journal of Suboptimal Lands Vol. 1 No. 2 (2012)
Publisher : Research Center for Sub-optimal Lands (PUR-PLSO), Universitas Sriwijaya

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (535.076 KB) | DOI: 10.33230/JLSO.1.2.2012.17

Abstract

Gofar. 2012. Application of Hydrocarbonoclastic Bacteria Isolates from Mangrove Rhizosphere on Petroleum Polluted Soil. JLSO 1(2):123-129.This research was aimed at studying the ability of hydrocarbonoclastic bacteria to reduce total petroleum hydrocarbon of petroleum polluted soil. The hydrocarbonoclastic bacteria were isolated from rhizosphere of mangrove grown on petroleum contaminated soil in Sungsang, Sumatra Selatan. The samples were taken using a defined sampling method from the oil contaminated areas. Soil samples around the roots of mangrove plants were randomly taken in the contaminated    area.  Isolates obtained from the isolation and selection of bacteria from mangrove forests were overhauled at the laboratory-scale using oil-enriched medium following  a completely randomized design. Nine isolates of hydrocarbonoclastic bacteria were found to be  capable of growing on petroleum contained medium in vitro. Two best isolates in degrading petroleum hydrocarbon compound were Pseudomonas alcaligenes (I5) and Alcaligenes facealis (I8). P. alcaligenes and A. facealis were able to decrease TPH up to 63% and 70% respectively. The ability of these isolates in degrading hydrocarbon compound was 6.5-7.0 times higher than the control. 
Co-Authors Abdul Madjid Abdull Madjid Rohim Abdullah Halim Perdana Kusuma Subakti Ace Baehaki Adi Supriyadi Adipati Napoleon Agus Hermawan Albertus Fajar Irawan Albertus Fajar Irawan Ali Amran Andi Diana Andika, Gusti Aditya ANDY MULYANA Angga Prasetya Mulya Anita Desiani Anjastari, Devi ANNISA NABILA Asmak Asmak Ayuputri, Niken Bambang Suprihatin Budi Untari Buyana, Nova Tri Chairu Nisa Apriyani Dade Jubaedah Dade Jubaedah Dedik Budianta Devi Anjastari Diana Sinurat Diana Utama Diana Utama Diana Utama DWI ANDREAS SANTOSA Eka Setianingsih Eli Sahara Ermatita - Erra Kartika Erra Kartika, Erra Erwin Saputra Fadjar Sidiq Hidayahtullah Fathona Nur Muzayyadah Fauzi Yusuf Syarifuddin fitra yosi, fitra Fitralia Elyza Fitri Siti Nurul Aidil Geovani, Dite Gusti Aditya Andika Hary Widjajanti Irmeilyana Kerenila Agustin Lestari, Primastya Ayu Lestari, Primastya Ayu M Kahfi Aldi Kurnia M. Umar Harun M. Umar Harun Maria Lusia Marini Wijayanti Marsi Meisji Liana Sari Miksusanti Miksusanti Muhammad Wahyu Ilahi Muhammat Rio Halim Munandar Munandar Munawar Munawar Nasrul Harahap Neni Marlina Ni Luh Putu SR Novi Wulandari Mustika Nyayu Nurul Husna Primastya Ayu Lestari Redina An Fadhila Chaniago Renih Hayati Rodiana Nopianti Rohim, A. Madjid Rosmiah Rosmiah, Rosmiah Satria Jaya Priatna, Satria Jaya Siti Komariah Hildayanti Siti Nurul Aidil Fitri Siti Nurul Aidil Fitri Siti Nurul Aidil, Fitri Sofia Sandi Sriati Sriati Sugandi Yahdin Susilawati Tanbiyaskur Tanbiyaskur Teguh Randi Pradana Tri Putri Nur Utama, Diana Utama, Diana wahyu tri patria Widya Irmawati Wuriesyliane Wuriesyliane Yopie Moelyohadi Yopie Moelyohadi Yuli Andriani