Testing of Bacterial and Fungal Isolates from Rumen Fluid Used in Inoculants in the Fermentation of Feed from Agro-Industrial Waste

Mustabi, Jamila; Zulkharnaim; Kuswinanti, Tutik; Sirajuddin, Sitti Nurani; Al-Tawaha, Abdel Razzaq

doi:10.12911/22998993/145319

Artykuł - szczegóły

Tytuł artykułu

Testing of Bacterial and Fungal Isolates from Rumen Fluid Used in Inoculants in the Fermentation of Feed from Agro-Industrial Waste

Autorzy

Mustabi Jamila , Zulkharnaim , Kuswinanti Tutik , Sirajuddin Sitti Nurani , Al-Tawaha Abdel Razzaq

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.12911/22998993/145319

Warianty tytułu

Języki publikacji

Abstrakty

The addition of the inoculant can accelerate the fermentation process and improve the quality of the feed material in fermentation. This study aimed to isolate, test and select the rumen microorganisms that have high ability to degrade the fiber and improve the quality of materials used in inoculants to ferment agricultural wastes as alternative feed. Microbial isolate was extracted from cattle rumen fluid. The isolates type of fungus were grown on Potato Dextrose Agar (PDA) while the bacteria was grown on Nutrient Agar (NA) medium. Microbes of fungi were tested and selected based on their ability to produce ligninase, cellulase and hemicellulase enzymes. Bacteria were grown on MRS broth media as a confirmation for LAB colonies, then tested for gram staining, catalase test, growth on different NaCl levels (4 and 6.5%) and growth at various pH (3, 4, and 5). The results showed that five fungal isolates had a growth diameter of 0.1–0.37 mm on lignin, cellulose and hemicellulose media after seven days. Eleven bacterial isolates were indicated as lactic acid bacteria; almost all isolates could grow on NaCl 6.5%, but only four bacterial isolates could grow on NaCl 4% and five bacterial isolates could grow at pH 3. In conclusion, three isolates of fungi have a remarkable ability to degrade lignin. Five isolates of lactic acid bacteria have a comprehensive ability as a preservative in fermentation, so eight microbial isolates from rumen fluid can be used as inoculants in fermenting the feed material from agro-industrial waste.

Słowa kluczowe

rumen fluid microorganism fiber decomposing fungi lactic acid bacteria

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2022

Tom

Vol. 23, nr 3

Strony

92--99

Opis fizyczny

Bibliogr. 38 poz., tab.

Twórcy

autor

Mustabi Jamila

jamila@unhas.ac.id

Nutrition and Feed Department, Faculty of Animal Science, Hasanuddin University, Makassar, Indonesia

autor

Zulkharnaim

Animal Production Department, Faculty of Animal Science, Hasanuddin University Makassar, Indonesia

autor

Kuswinanti Tutik

Pest and Plant Diseases Department, Faculty of Agriculture, Makassar, Hasanuddin University, Indonesia

autor

Sirajuddin Sitti Nurani

Socio-Economics Husbadry Department, Faculty of Animal Science, Hasanuddin University Makassar, Indonesia

autor

Al-Tawaha Abdel Razzaq

Department of Crop Science, Faculty of Agriculture, Universiti Putra Malaysia 43400 UPM Serdang, Selangor, Malaysia

https://orcid.org/0000-0003-0826-0942

Bibliografia

1. Abdullah H., Ho Y.W., Jalaludin. 1990. Role of Rumen Microbes in the Breakdown of agricultural by products. Proceeding of workshop pn Research Methologies, 115–125.
2. Adlini N.I. 2014. Seleksi mikroba seluloitik dalam mendegradasi lignin asal tanah gambut Desa Rimbo Panjang Kampar Riau. Jurusan Biologi. Fakultas Matematika dan Ilmu Pengetahuan Alam. Universitas Riau. Riau.
3. Ali M.K., Rudolph F.B., Bennet G.N. 2004. Thermostable xyla-nases 10B from Clostridium acetobotylicum ATCC824. J. Ind. Micro-biol. Technol., 31, 229–234.
4. Baldwin R.L., Allison M.J. 1983. Rumen metabolism. Journal Animal Science, 57(2), 461–477.
5. Bolsen K.K., Ashbell M.G., Wilkinnson J.M. 1995. Silage Aditifs in Biotechnology in Animal Feeding. R.J. Wallace & A. Chesson (Eds). VCH, Weinheim.
6. Coughlan M.P. 1988. Staining Tecniques for The Detection of The Individual Components of Cellulolytic Enzyme Systemes. In: Wood, W.A. and Kellogg. S.T. (Eds) Methods In Enzymology, Academic Press, London, 160, 135–144.
7. Dashtban M., Schraft H., Qin W. 2009. Fungal Bioconversion of Lignocellulosic Residue: Opportunities & Perspectives. Int. J. Biol. Sci., 578–595.
8. Delfahedah Y., Syukur S., dan Jamsari. 2013. Isolasi karakterisasi dan identifikasi DNA Ciprofloxacin FBK 3 FBK 1 FBK 1 FBK 2 FBK 3 Ciprofloxacin BIOLEUSER, bakteri asam laktat (BAL) yang berpotensi sebagai antimikroba dari Fermentasi kakao varietas hibrid (Trinitario). Jurnal Kimia Unand, 2(4).
9. Edwin. 2011. Materi Kuliah Mikrobiologi. Banjarbaru (ID): Universitas Lambung Mangkurat.
10. Fonty G. 1991. The Rumen Anaerobic Fungi. In: Rumen Microbial Metabolism and Ruminant Digestion. Institut national De La Recherche Agronomique Paris.
11. Hadioetomo R.S. 1985. Mikrobiologi dasar-dasar praktik. PT. Gramedia, Jakarta.
12. Hartana S.N. 2014. Keanekaragaman Cendawan yang Diisolasi di Lokasi Perkandangan Ayam. Institut Pertanian Bogor. Bogor.
13. Jalil A.A.K. 2004. Enzim Mikroba dan Bahan Penguraian Berselulosa. Departemen Biologi. Jakarta.
14. Jasin I., dan Bachrudin Z. 2013. Pengaruh isolate bakteri asam laktat dari feses pedet sapi perah baru lahir terhadap produksi asam laktat dan perubahan pH pada ampas tahu. J. Agripet., 13(2), 36–40.
15. Jouany J.P. 1991. Rumen Microbial Metabolism and Ruminant Digestion. Institute National De La Recherche Agronomique, 147, Rue De I’Universite-75338 Paris Cedex 07.
16. Kasana R.C., Salwan R., Dhar H., Dutt S., Gulati A. 2008. A. Rapid and easy method for detection of microbial cellulases on agar plates using Gram’s iodine. Curr. Microbiol., 57, 503–507.
17. Kluepfel D. 1988. Screening Of Prokaryotes For Cellulose And Lignocellulose as A Sources of Inoculum Fermented to High Fibre Feed. Pakistan Journal of Nutrition, 12(9), 851–853.
18. Kubata B.K., Suzuki T., Horitsu H., Kawal K., Takamizawa K. 1994. Purification and characterization of Aeromonas caviae ME-1 xylanases V, which produces exclusively xylobiose from xylan. Applied & Environmental Microbiology, 60, 531–535.
19. Kurnia K., Sadi N.H., dan Jumianto S. 2016. Isolasi bakteri heterotrof di situ cibuntu, jawa barat dan karakterisasi resistensi asam dan logam. http://journal.uinjkt.ac.id/index.php/kauniyah AL-KAUNIYAH; Journal of Biology, 9(2), 2016, 74–79.
20. Kusnadi. 2010. Keanekaragaman Jamur Selulolitik Dan Amilolitik Pengurai Sampah Organik Dari Berbagai Substrat. Jurusan Pendidikan Biologi Fpmipa Universitas Pendidikan Indonesia, 1–10.
21. Lay B.W. 1994. Analisa Mikroba Di Laboratorium. Edisi 1. Cetakan 1. Raja Grafindo Persada. Jakarta
22. Murni R., Suparjo, Akmal, dan Ginting B.L. 2008. Buku Ajar Teknologi Pemanfaatan Limbah untuk Pakan. Laboratorium Makanan Ternak. Fakultas Peternakan universitas Jambi.
23. Nurhalimah H., Wijayanti N., Widyaningsih T.D. 2015. Efek Antidiare Ekstrak Daun Beluntas (Pluchea indica L.) Terhadap Mencit Jantan yang Diinduksi Bakteri Salmonella Thypimurium Antidiarrheal. Jurnal Pangan Dan Agroindustri, 3(3), 1083–1094.
24. Orskov E.R., Ryle M. 1990 Energy nutrition in ruminants. Elsevier Applied Science. London, 149.
25. Parakkasi,A.1999. Ilmu Nutrisi dan Makanan Ternak Ruminansia.Universitas Indonesia Press. Jakarta.
26. Rahayu A.G., Haryani Y., Fifi P. 2014. Uji aktivitas selulolitik dari tiga isolat bakteri bacillus sp. galur lokal riau. JOM FMIPA, 1(2).
27. Ray B. 1992. Nisin of Lactococcus lactissubsp. lactis as a Food Biopre-servative, 207–264. In: B. Ray andM. Daeschel (ed). Food Biopreser-vatives of Microbial Origin. CRC Press. Boca Raton.
28. Respati N.Y. 2017. Optimasi suhu dan pH media pertumbuhan bakteri pelarut fosfat dari isolat bakteri termofilik. Jurnal Prodi Biologi, 6(7).
29. Saha B.C. 2002. Purification and charachterization of an extracellular â- xylosidase from newly isolated Fu- sarium verticilloides. J. Ind. Micro- biol. Biotechnol., 27, 241–245.
30. Salminen S., Wright A. 1998. Lactic Acid Bacteria. Edisi ke-2. Marcel Dekker. Inc. New York. Basel.
31. Stalpers J.A. 1978. Identification of wood-inhabiting Aphyllophorales in pure culture. Centraalbureau Voor Schimmelcultures. Baarn. Studies in Mycology, 16, 1–248.
32. Suardana I.W., Suada I.K., Sukada I.M., Suarsana I.N. 2009. Isolasi danidentifikasi bakteri asam laktat SR9 asal cairan rumen sapi bali sebagai kandidat probiotik. J.Medicina., 40(2), 100–103.
33. Suryadi Y., Priyatno T.P., Samudra M., Susilowati D.N., Lawati N., dan Kustaman E. Pemurnian parsial dan karakterisasi kitinase asal jamur entomopatogen beauveria bassiana isolat BB200109 2013. J. Agro Biogen., 9(2).
34. Susilawati S. 2016. Isolasi dan Karakterisasi Bakteri Asam Laktat (BAL) dari Fermentasi Air Cucian Beras. Skripsi. Jakarta: Fakultas Kedokteran dan Ilmu Kesehatan UIN Syarif Hidayatullah.
35. Thakkar P., Modi H.A., Prajapati J.B. 2015. Isolation, characterization and safety assessment of lactic acid bacterial isolates from fermented food products. International Journal of Current Microbiology and Applied Sciences, 4(4).
36. Van Soest P.J. 1994. Nutitional Ecology of The Ruminant. Cornell University Press. Ithaca. New York.
37. Yokoyama M.T., Johnson K.A. 1988. Microbiology of the rumen digestive physiology and nutrition. In: D.C. Church (Ed.), The Ruminant animal. Printice Hall, Englewood Cliifs, New Jersey, 125–144.
38. Zhang G.-L., Wu Y.-T., Qian X.-P., Meng Q. 2005. Biodegradation of crude oil by Pseudomonas aeruginosa in the presence of rhamnolipids. Journal of Zhejiang University Science, 6B, 725–730.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-0933d9f5-7d11-4063-8ab3-9136cdf5dbdb