Journal of Degraded and Mining Lands Management

Biofertilizer production in Indonesia should fulfil the minimum requirement for being produced and released to the market. Problems occurred when those products are being absent on informing those expiration dates and the viability of microbial activity which then closely related to the quality of the product. Seaweed composted material are potential resources for producing Biofertilizer, but lacking on the optimization on their process as this material contain a various important component for soil and environment. The production of Biofertilizer from seaweed waste required an optimum condition, i.e.: pH and typical microbe which could germinate under specific formulation and temperature. This study aimed to determine the optimum pH in liquid fertilizer formulations made from seaweed waste in the form of composted material, to test the viability of three bacterial isolates and those pathogenicity properties, to examine the effect of metabolites release from bacterial isolates to green bean seed germination. The experimental design used was a completely randomized design with four treatments, which were as follow: P0 as a control (Peptone), RP1 (seaweed waste), RP2 (seaweed waste and glycerol), and RP3 (seaweed waste and PEG). The three bacterial isolates used were: (1) Bacillus licheniformis, (2) Psudomonas plecoglossicida and (3) Pantoea ananatis. This liquid fertilizer biological formulation was stored for 8 weeks at pH 5.5 and temperature 25^oC. The results showed that the treatment of RP1 (seaweed waste) had high bacterial viability and could stimulate growth for green bean sprouts. The carrier material for seaweed waste with the addition of glycerol and PEG showed no effect of the disease and symptoms of a pathogenic bacterial consortium on germination of green beans.

biofertilizer; microbe; compost; pathogenity; seaweed waste

Advinda, L., Fifendy, M. and Rahmadeni, Y. 2014. The potency of Pseudomonad fluorescent isolates CAS3 on various formulation with the addition of glycerol stabilizer for controlling blood disease bacteria (BDB) under in-vitro condition. Jurnal Sainstek 6(2): 102-109 (in Indonesian).

Arfarita, N., Hidayati, N., Rosyidah, A., Machfudz, M. and Higuchi, T. 2016. Exploration of indigenous soil bacteria producing-exopolysaccharides for stabilizing of aggregates land potential as biofertilizer. Journal of Degraded and Mining Lands Management. 4(1): 697-702.

Arfarita, N., Lestari, M.W., Murwani, I. and Higuchi, T. 2017. Isolation of indigenous phosphate solubilizing bacteria from green bean rhizospheres. Journal of Degraded and Mining Lands Management 4(3): 845-851.

Arfarita, N., Muhibuddin, M. and Imai, T. 2019. Exploration of indigenous free nitrogen-fixing bacteria from rhizosphere of Vigna radiate. Journal of Degraded and Mining Lands Management 6(2): 1617-1623.

Astuti. W.R.E. 2014. Application of peptone from the rotten side fish catching raw material (HTS) as a component of bacterial and yeast media. Fisheries and marine science. Bogor Agricultural Institute (IPB). Bogor (in Indonesian).

Borica. H. and Fulekar, M.H. 2009. Pseudomonas plecoglossicida as a novel organism for the bioremediation of cypermethrin. Department of Life Sciences, University of Mumbai.

Cocozza, C.A., Parente, C. Zaccone, C. Mininni, P. Santamaria, T. and Miano. 2011. Comparative management of offshore Posidonia residues: composting vs. energy recovery. Waste Management (Oxford). 31: 78-84.

Collin, C.H. and Lyne, P.M. 1987. Microbiological Methods, 5th Edition. Butterworths, London. 419-431p.

Deepa. 2009. Isolation and characterization of plant growth-promoting strain Pantoea NII-186. From Western Ghat Forest soil, India.

Fornes, F., Sanchez, P.M. and Guadiola, J.L. 2002. Effect of a seaweed extract on the productivity of ‘de Nules’ Clementinemdanarinnavelina orange. Botanica Marina. 45:486–489.

Fujikawa, H., Kai, A. and Morozumi, S. 2004. A new logistic model for Escherichia coli growth at constant and dynamic temperatures. Food Microbiology 21:501-509.

Hadioetomo, R.S. 1993. The basic of Microbiology in Practices. Gramedia. Jakarta (in Indonesian).

Haslam, S.F.I. and Hopkins, D.W. 1996. Physical and biological effects of kelp (seaweed) added to soil. Applied Soil Ecology 3:257-261.

Husen, E., Simanungkalit, R.D.M. dan Irawan. 2007. Characterization and quality assessment of Indonesian commercial biofertilizers. Indonesian Journal of Agricultural Science 8: 31-38.

Kern, J. 1966. Glycerol. Encyclopedia of Chemical Technology, Vol. 10. Interscience Publishers, New York.

Lingga, P. and Marsono. 2000. Guidelines for Fertilizer Application. Penebar Swadaya, Jakarta. Pp. 80 (in Indonesian).

McHugh, D.J. 2003. A Guide to Seaweed Industry. Food and Agriculture Oganization of the UN, Rome. 88p.

Padhi, S.B. and Swain, P.K. 2006. Effective Role of Microorganism dan Seaweed as Biofertilizer in Organic Farming for a Sustainable Environment. http://wgbis.ces.iisc .rne t.in /energy/lake 2006 /programme/programme/ procee/fullpaper_pdfs/Sailabala%20Padhi.pdf. Akses on 13 October 2016.

Pepe O., Blaiotta, G. Moschetti, G. Greco, T. and Villani, F. 2003. Rope-producing strains of Bacillus spp. from wheat bread and strategy for their control by lactic acid bacteria. Applied Environmental Microbiology 69(4):2321.

Purwoko, T. 2009. Fisiology of Microbes. Jakarta (ID): Bumi Aksara. pp. 199-201 (in Indonesian).

Sedayu, B.B., Basmal, J. and Utomo. B.S.B. 2013. Identification of growth hormone from urine extract (cow) Eucheuma cottonii. Journal of Postharvest dan Marine Biotechnology and Fisheries. 8(1): 1–8 (in Indonesian)

Sivasankari, S., Venkatesalu, V. Anantharaj, M. and Chdanrasekaran M. 2006. Effect of seaweed extract on the growth and biochemical constituents of Vigna sinensis. Bioresource Technology 97: 1745–1751.

Winarwi, 2006. Viability test of Bacteria dan Activity of Proteolytic bacterial enzyme on carrier media Carrier of bekatul. Thesis. Faculty of teacher training and educational sciences. The University of Sebelas Maret, Surakarta (in Indonesian).

Wiranti, N.G. 2014. Manufacturing of peanut Pepton by rough Papain enzyme for bacterial growth media. Bogor Agricultural Institut Bogor (in Indonesian).