Influence of Fermentation Conditions on Humic Acids Production by Trichoderma viride Using an Oil Palm Empty Fruit Bunch as the Substrate
Humic acids (HA) were produced by a Trichoderma
viride strain under submerged fermentation in a medium based on the
oil palm empty fruit bunch (EFB) and the main variables of the
process were optimized by using response surface methodology. A
temperature of 40°C and concentrations of 50g/L EFB, 5.7g/L potato
peptone and 0.11g/L (NH4)2SO4 were the optimum levels of the
variables that maximize the HA production, within the
physicochemical and biological limits of the process. The optimized
conditions led to an experimental HA concentration of 428.4±17.5
mg/L, which validated the prediction from the statistical model of
412.0mg/L. This optimization increased about 7–fold the HA
production previously reported in the literature. Additionally, the
time profiles of HA production and fungal growth confirmed our
previous findings that HA production preferably occurs during fungal
sporulation. The present study demonstrated that T. viride
successfully produced HA via the submerged fermentation of EFB
and the process parameters were successfully optimized using a
statistics-based response surface model. To the best of our
knowledge, the present work is the first report on the optimization of
HA production from EFB by a biotechnological process, whose
feasibility was only pointed out in previous works.
[1] G. R. Aiken, D. M. Mcknight,R. L. Wershaw and P. Mac-
Carthy,"Humic substances in soil, sediment, and water: geochemistry,
isolation and characterization”. Wiley, 1985, 692 p.
[2] Y. P. Chin, S. J Traina,C. R. Swank and D. Backhus, "Abundance and
properties of dissolved organic matter in pore waters of a freshwater
wetland”. Limnology and Oceanography, vol. 43, no. 6, p. 1287-1296,
1998.
[3] E. Cameron, N. How, S.Saggar and C. Ross, "The cost-benefits of
applying biosolid composts for vegetables, fruit and maize/sweetcorn
production systems in New Zealand”. Manaaki Whenua Press. 33 p.,
2004.
[4] E. Yamada, T. Ozaki and M. Kimura,"Determination and behavior of
humic substances as precursors of trihalomethane in environmental
water”. Analytical Sciences, vol. 14, no. 2, p. 327-332, 1998.
[5] J. Asing, N. C. Wong and S. Lau, "Optimization of extraction method
and characterization of humic acid derived from coals and composts”.
Journal of Tropical Agriculture and Food Science, vol. 37, no. 2, p. 211–
223, 2011.
[6] H. Joosten,M. Tapio-Bistrom and S. Tol,"Peatlands – guidance for
climate change mitigation through conservation, rehabilitation and
sustainable use”. 114p., 2012.
[7] F. Hamzah,A. Idris and T. K.Shuan,“Preliminary study on enzymatic
hydrolysis of treated oil palm (Elaeis) empty fruit bunches fibre (EFB)
by using combination of cellulase and ȕ 1-4 glucosidase”. Biomass and
Bioenergy, vol. 35, no. 3, p. 1055-1059, 2011.
[8] N. A. F. Harun,A. S. Baharuddin,M. H. M. Zainudin,E. K. Bahrin M. N.
Naimand R. Zakaria,“Cellulase production from treated oil palm empty
fruit bunch degradation by locally isolated Thermobifidafusca”.
BioResources, vol. 8, no. 1, p. 676-68, 2013.
[9] S. Vermeulen and G. Nathalie,“Towards better practice in smallholder
palm oil production”. Oldacres. 57 p., 2006.
[10] P. O. Oviasogie, N. O. Aisueni and G. E. Brown,“Oil palm composted
biomass: A review of the preparation, utilization, handling and storage”.
African Journal of Agricultural Research, vol. 5, no. 13, p. 1553-1571,
2010.
[11] I.S. Druzhinina,V. Seidl-Seiboth,A. Herrera-Estrella,B. A. Horwitz, C.
M. Kenerley, E. Monte, P. K. Mukherjee,S. Zenlinger,I. V. Grigoriev
and C. P. Kubicek,“Trichoderma: the genomics of opportunistic
success”. Nature Reviews Microbiology, vol. 9, no. 10, p. 749-759,
2011.
[12] H. I. Al-Taweil, M. B. Osman, A. H. Aidil, and W. M. W. Yussof,
“Optimizing of Trichodermaviride cultivation in submerged state
fermentation”. American Journal of Applied Sciences, vol. 6, no. 7, p.
1284-1288, 2009.
[13] M. Verma,S. K. Brar, R. D. Tyagi, R. Y. Surampalliand J. R. Valero,
“Dissolved oxygen as principal parameter for conidia production of
biocontrol fungi Trichodermaviride in non-Newtonian wastewater”.
Journal of Industrial Microbiology and Biotechnology, vol. 33, no. 11, p.
941-952, 2006
[14] P. Tauro, K. K. Kapoor, K. S. Yadav,“An introduction to microbiology”.
New Age International. 412 p. 2004.
[15] M. A. Jackson,“Optimizing nutritional conditions for the liquid culture
production of effective fungal biological control agents”. Journal of
Industrial Microbiology and Biotechnology, vol. 19, no. 3, p. 180-187,
1997.
[16] C. R. Soccol, A. Pandey and C, Larroche,“Fermentation Processes
Engineering in the Food Industry”. CRC Press. 510 p, 2013.
[17] F. L. Motta and M. H. A. Santana,“Production of humic acids from oil
palm empty fruit bunch by submerged fermentation with
Trichodermaviride: cellulosic substrates and nitrogen sources”.
Biotechnology Progress, vol. 29, no. 3, p. 631-637, 2013.
[18] R. L. Plackett and J. P Burman, “The design of optimum multifactorial
experiments”. Biometrika, vol. 33, no. 4, p. 305-325, 1946
[19] F. L. Motta and M. H. A. Santana,“Biomass production from
Trichodermaviride in non-conventional oat medium”. Biotechnology
Progress, vol. 28, no. 5, p. 1245-1250, 2012.
[20] A. Badis, F. Z. Ferradji, A. Boucherit, D. Fodil and H. Boutoumi,
“Removal of natural humic acids by decolorizing actinomycetes isolated
from different soils (Algeria) for application in water purification”.
Desalination, vol. 259, no. 1-3, p. 216-222, 2010.
[21] N. Callow and L. Ju,“Promoting pellet growth of Trichodermareesei Rut
C30 by surfactants for easy separation and enhanced cellulase
production”. Enzyme and Microbial Technology, vol. 50, no. 6-7, p.
311-317, 2012.
[22] P. K. Smith,R. I. Krohn, G. T.Hermanson, A. K. Mallia, F. H. Gartner,
M. D. Frovenzano, E. K. Fujimoto, N. M. Goeke, B. J. Olson and D. C.
Klenk, “Measurement of protein using bicinchoninic acid”. Analytical
Biochemistry, vol. 150, no. 1, p. 76-85, 1985.
[23] S. L. Bhattiprolu, “Growth of Trichodermaviride as influenced by ph,
temperature, botanicals, fungicides and mutagenic agent”. Indian Journal
of Plant Protection, vol. 36: no. 2, p. 279-282, 2008.
[24] M. Schintzer and S. U. Khan,“Soil Organic Matter”. Elsevier. 319 p.,
1978.
[25] S. Anastassiadisand H. J. Rehm, “Oxygen and temperature effect on
continuous citric acid secretion in Candida oleophila”. Electronic
Journal of Biotechnology, vol. 9, no. 4, p. 341-350, 2006.
[26] A. D., Juwonans O. F. Emmanuel, “Experimental investigations on the
effects of carbon and nitrogen sources on concomitant amylase and
polygalacturonase production by Trichodermaviride BITRS-1001 in
submerged fermentation”. Biotechnology Research International, 2012.
[27] R. R. Singhania, R. K. Sukumaran and A. Pandey,“Improved cellulase
production by Trichodermareesei RUT C30 under SSF through process
optimization. Applied Biochemistry and Biotechnology, vol. 142, no. 1,
p. 60-70, 2007.
[28] A. S. A. El-Sayed, “L-glutaminase production by Trichodermakoningii
under solid state fermentation”. Indian Journal of Microbiology, vol. 49,
no. 3, p. 243-250, 2009.
[29] M. Z. Alam, S. A. Muyibi and R. Wahid, “Statistical optimization of
process conditions for cellulase production by liquid state bioconversion
of domestic wastewater sludge”. Bioresource Technology, vol. 99, no.
11, p. 4709-4716, 2008.
[30] C. Christias, C. Couvaraki, S. G.Georgopoulos,B. Macris and V.
Vomvoyanni,“Protein Content and Amino Acid Composition of Certain
Fungi Evaluated for Microbial Protein Production”. Journal of Applied
Microbiology, vol. 29, no. 2, p. 250-254, 1975.
[31] Y. Siddiqui,S. Meon,R. Ismail, M. Rahmani and A. Ali, “In vitro
fungicidal activity of humic acid fraction from oil palm compost”.
International Journal of Agriculture and Biology, vol. 11, no. 4, p. 448-
452, 2009.
[1] G. R. Aiken, D. M. Mcknight,R. L. Wershaw and P. Mac-
Carthy,"Humic substances in soil, sediment, and water: geochemistry,
isolation and characterization”. Wiley, 1985, 692 p.
[2] Y. P. Chin, S. J Traina,C. R. Swank and D. Backhus, "Abundance and
properties of dissolved organic matter in pore waters of a freshwater
wetland”. Limnology and Oceanography, vol. 43, no. 6, p. 1287-1296,
1998.
[3] E. Cameron, N. How, S.Saggar and C. Ross, "The cost-benefits of
applying biosolid composts for vegetables, fruit and maize/sweetcorn
production systems in New Zealand”. Manaaki Whenua Press. 33 p.,
2004.
[4] E. Yamada, T. Ozaki and M. Kimura,"Determination and behavior of
humic substances as precursors of trihalomethane in environmental
water”. Analytical Sciences, vol. 14, no. 2, p. 327-332, 1998.
[5] J. Asing, N. C. Wong and S. Lau, "Optimization of extraction method
and characterization of humic acid derived from coals and composts”.
Journal of Tropical Agriculture and Food Science, vol. 37, no. 2, p. 211–
223, 2011.
[6] H. Joosten,M. Tapio-Bistrom and S. Tol,"Peatlands – guidance for
climate change mitigation through conservation, rehabilitation and
sustainable use”. 114p., 2012.
[7] F. Hamzah,A. Idris and T. K.Shuan,“Preliminary study on enzymatic
hydrolysis of treated oil palm (Elaeis) empty fruit bunches fibre (EFB)
by using combination of cellulase and ȕ 1-4 glucosidase”. Biomass and
Bioenergy, vol. 35, no. 3, p. 1055-1059, 2011.
[8] N. A. F. Harun,A. S. Baharuddin,M. H. M. Zainudin,E. K. Bahrin M. N.
Naimand R. Zakaria,“Cellulase production from treated oil palm empty
fruit bunch degradation by locally isolated Thermobifidafusca”.
BioResources, vol. 8, no. 1, p. 676-68, 2013.
[9] S. Vermeulen and G. Nathalie,“Towards better practice in smallholder
palm oil production”. Oldacres. 57 p., 2006.
[10] P. O. Oviasogie, N. O. Aisueni and G. E. Brown,“Oil palm composted
biomass: A review of the preparation, utilization, handling and storage”.
African Journal of Agricultural Research, vol. 5, no. 13, p. 1553-1571,
2010.
[11] I.S. Druzhinina,V. Seidl-Seiboth,A. Herrera-Estrella,B. A. Horwitz, C.
M. Kenerley, E. Monte, P. K. Mukherjee,S. Zenlinger,I. V. Grigoriev
and C. P. Kubicek,“Trichoderma: the genomics of opportunistic
success”. Nature Reviews Microbiology, vol. 9, no. 10, p. 749-759,
2011.
[12] H. I. Al-Taweil, M. B. Osman, A. H. Aidil, and W. M. W. Yussof,
“Optimizing of Trichodermaviride cultivation in submerged state
fermentation”. American Journal of Applied Sciences, vol. 6, no. 7, p.
1284-1288, 2009.
[13] M. Verma,S. K. Brar, R. D. Tyagi, R. Y. Surampalliand J. R. Valero,
“Dissolved oxygen as principal parameter for conidia production of
biocontrol fungi Trichodermaviride in non-Newtonian wastewater”.
Journal of Industrial Microbiology and Biotechnology, vol. 33, no. 11, p.
941-952, 2006
[14] P. Tauro, K. K. Kapoor, K. S. Yadav,“An introduction to microbiology”.
New Age International. 412 p. 2004.
[15] M. A. Jackson,“Optimizing nutritional conditions for the liquid culture
production of effective fungal biological control agents”. Journal of
Industrial Microbiology and Biotechnology, vol. 19, no. 3, p. 180-187,
1997.
[16] C. R. Soccol, A. Pandey and C, Larroche,“Fermentation Processes
Engineering in the Food Industry”. CRC Press. 510 p, 2013.
[17] F. L. Motta and M. H. A. Santana,“Production of humic acids from oil
palm empty fruit bunch by submerged fermentation with
Trichodermaviride: cellulosic substrates and nitrogen sources”.
Biotechnology Progress, vol. 29, no. 3, p. 631-637, 2013.
[18] R. L. Plackett and J. P Burman, “The design of optimum multifactorial
experiments”. Biometrika, vol. 33, no. 4, p. 305-325, 1946
[19] F. L. Motta and M. H. A. Santana,“Biomass production from
Trichodermaviride in non-conventional oat medium”. Biotechnology
Progress, vol. 28, no. 5, p. 1245-1250, 2012.
[20] A. Badis, F. Z. Ferradji, A. Boucherit, D. Fodil and H. Boutoumi,
“Removal of natural humic acids by decolorizing actinomycetes isolated
from different soils (Algeria) for application in water purification”.
Desalination, vol. 259, no. 1-3, p. 216-222, 2010.
[21] N. Callow and L. Ju,“Promoting pellet growth of Trichodermareesei Rut
C30 by surfactants for easy separation and enhanced cellulase
production”. Enzyme and Microbial Technology, vol. 50, no. 6-7, p.
311-317, 2012.
[22] P. K. Smith,R. I. Krohn, G. T.Hermanson, A. K. Mallia, F. H. Gartner,
M. D. Frovenzano, E. K. Fujimoto, N. M. Goeke, B. J. Olson and D. C.
Klenk, “Measurement of protein using bicinchoninic acid”. Analytical
Biochemistry, vol. 150, no. 1, p. 76-85, 1985.
[23] S. L. Bhattiprolu, “Growth of Trichodermaviride as influenced by ph,
temperature, botanicals, fungicides and mutagenic agent”. Indian Journal
of Plant Protection, vol. 36: no. 2, p. 279-282, 2008.
[24] M. Schintzer and S. U. Khan,“Soil Organic Matter”. Elsevier. 319 p.,
1978.
[25] S. Anastassiadisand H. J. Rehm, “Oxygen and temperature effect on
continuous citric acid secretion in Candida oleophila”. Electronic
Journal of Biotechnology, vol. 9, no. 4, p. 341-350, 2006.
[26] A. D., Juwonans O. F. Emmanuel, “Experimental investigations on the
effects of carbon and nitrogen sources on concomitant amylase and
polygalacturonase production by Trichodermaviride BITRS-1001 in
submerged fermentation”. Biotechnology Research International, 2012.
[27] R. R. Singhania, R. K. Sukumaran and A. Pandey,“Improved cellulase
production by Trichodermareesei RUT C30 under SSF through process
optimization. Applied Biochemistry and Biotechnology, vol. 142, no. 1,
p. 60-70, 2007.
[28] A. S. A. El-Sayed, “L-glutaminase production by Trichodermakoningii
under solid state fermentation”. Indian Journal of Microbiology, vol. 49,
no. 3, p. 243-250, 2009.
[29] M. Z. Alam, S. A. Muyibi and R. Wahid, “Statistical optimization of
process conditions for cellulase production by liquid state bioconversion
of domestic wastewater sludge”. Bioresource Technology, vol. 99, no.
11, p. 4709-4716, 2008.
[30] C. Christias, C. Couvaraki, S. G.Georgopoulos,B. Macris and V.
Vomvoyanni,“Protein Content and Amino Acid Composition of Certain
Fungi Evaluated for Microbial Protein Production”. Journal of Applied
Microbiology, vol. 29, no. 2, p. 250-254, 1975.
[31] Y. Siddiqui,S. Meon,R. Ismail, M. Rahmani and A. Ali, “In vitro
fungicidal activity of humic acid fraction from oil palm compost”.
International Journal of Agriculture and Biology, vol. 11, no. 4, p. 448-
452, 2009.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:67043", author = "F. L. Motta and M. H. A. Santana", title = "Influence of Fermentation Conditions on Humic Acids Production by Trichoderma viride Using an Oil Palm Empty Fruit Bunch as the Substrate", abstract = "Humic acids (HA) were produced by a Trichoderma
viride strain under submerged fermentation in a medium based on the
oil palm empty fruit bunch (EFB) and the main variables of the
process were optimized by using response surface methodology. A
temperature of 40°C and concentrations of 50g/L EFB, 5.7g/L potato
peptone and 0.11g/L (NH4)2SO4 were the optimum levels of the
variables that maximize the HA production, within the
physicochemical and biological limits of the process. The optimized
conditions led to an experimental HA concentration of 428.4±17.5
mg/L, which validated the prediction from the statistical model of
412.0mg/L. This optimization increased about 7–fold the HA
production previously reported in the literature. Additionally, the
time profiles of HA production and fungal growth confirmed our
previous findings that HA production preferably occurs during fungal
sporulation. The present study demonstrated that T. viride
successfully produced HA via the submerged fermentation of EFB
and the process parameters were successfully optimized using a
statistics-based response surface model. To the best of our
knowledge, the present work is the first report on the optimization of
HA production from EFB by a biotechnological process, whose
feasibility was only pointed out in previous works.
", keywords = "Empty fruit bunch, humic acids, submerged
fermentation, Trichoderma viride.", volume = "8", number = "5", pages = "381-9", }
