Effects of Xylanase and Cellulase Production during Composting of EFB and POME using Fungi
Empty Fruit Bunches (EFB) and Palm Oil Mill
Effluent (POME) are two main wastes from oil palm industries which
contain rich lignocellulose. Degradation of EFB and POME by
microorganisms will produce hydrolytic enzyme which will degrade
cellulose and hemicellulose during composting process. However,
normal composting takes about four to six months to reach maturity.
Hence, application of fungi into compost can shorten the period of
composting. This study identifies the effect of xylanase and cellulase
produced by Aspergillus niger and Trichoderma virens on
composting process using EFB and POME. The degradation of EFB
and POME indicates the lignocellulolytic capacity of Aspergillus
niger and Trichoderma virens with more than 7% decrease in
hemicellulose and more than 25% decrease in cellulose for both
inoculated compost. Inoculation of Aspergillus niger and
Trichoderma virens also increased the enzyme activities during the
composting period compared to the control compost by 21% for both
xylanase and cellulase. Rapid rise in the activities of cellulase and
xylanase was observed by Aspergillus niger with the highest
activities of 14.41 FPU/mg and 3.89 IU/mg, respectively. Increased
activities of cellulase and xylanase also occurred in inoculation of
Trichoderma virens with the highest activities obtained at 13.21
FPU/mg and 4.43 IU/mg, respectively. Therefore, it is evident that
the inoculation of fungi can increase the enzyme activities hence
effectively degrading the EFB and POME.
[1] Albrecht A., Fischer G., Brunnemann-Stubbe G., Jäckel U., and
Kämpfer P., " Recommendations for study design and sampling
strategies for airborne microorganisms, MVOC and odours in the
surrounding of composting facilities". Int. J. Hyg. Environ. Health
211(2008) 121-131.
[2] Zahangir Alam M., Mamun A. A., Qudsieh I. Y., Muyibi S. A., Salleh
H. M., Omar N. M., "slid state bioconversion of oil palm empty fruit
bunches for cellulase enzyme production using a rotary drum
bioreactor". Biochemical Engineering Journal 46 (2009) 61-64.
[3] Song J. and Wei D., "Production and characterization of cellulases and
xylanases of Cellulosimicrobium cellulans grown in pretreated and
extracted bagasse and minimal nutrient medium M9-. Biomass and
Bioenergy 34 (2010) 1930-1934.
[4] Seyis I., and Aksoz N., "Effect of carbon and nitrogen sources on
xylanase production by Trichoderma harzianum 1073 D3".
International Biodeterioration & Biodegradation 55 (2005) 115-119.
[5] Gutierrez-Correa M., portal L., Moreno P., and Tengerdy R. P., "Mixed
culture solid substrate fermentation of Trichoderma reesei with
Aspergillus niger on sugar cane bagasse". Bioresource Technology 68
(1999) 173-178.
[6] Tengerdy R. P., and Szakacs G., "Bioconversion of lignocellulose in
solid substrate fermentation". Biochemical Engineering Journal 13
(2003) 169-179.
[7] Liu D., Zhang R., Yang X., Wu H., Xu D.,Tang Z., and Shen Q,
"Thermostable cellulase production of Aspergillus fumigatus Z5 under
solid-state fermentation and its application in degradation of agricultural
wastes". International Biodeterioration & Biodegradation 65 (2011)
717-725.
[8] Sonia K.G., Chadha B.S., and Saini H.S., "Sorghum straw for xylanase
hyper-production by Thermomyces lanuginosus (D2W3) under solidstate
fermentation". Bioresource Technology 96 (2005) 1561-1569.
[9] Datta R., "Acidogenic Fermentation of Lignocellulosic Acid Yield and
Conversion of Components". Biotechnol. Lett. 161(12), 1317-1322.
[10] Ghose T.K. and V.S. Bisaria, "Measurement of Hemicellulase Activities
Part 1: Xylanases". Pure & Appl. Chem., Vol. 59, No. 12, pp. 1739-
1752.
[11] B. Adney and J. Baker, "Measurement of Cellulase Activities". National
Renewable Energy Laboratory, 2008. Issue date: 08/12/1996. Pp. 1-8.
[12] Zhang Z. Y., Jin B., Bai Z. H., and Wang X.Y., "Production of fungal
biomass protein using microfungi from winery wastewater treatment".
Bioresource Technology 99 (2008) 3871-3876.
[13] Singh A. and Sharma S., "Composting of a Crop Residue through
Treatment with Microorganisms and Subsequent Vermicomposting".
Bioresource Technology. 85(2002) 107-111.
[14] Brookes P.C., "The use of microbial parameters in monitoring soil
pollution by heavy metals". Biology and Fertility of Soil (1995) 19:269-
279.
[15] Mondini C., Fornasier F., and Sinicco T., "Enzymatic activity as a
parameter for the characterization of the composting process". Soil
Biology & Biochemistry 36(2004) 1587-1594.
[16] Wong Ken K.Y. and Saddler John N., "Trichoderma Xylanase, Their
Properties and Application" Biotechnology. 1992, Vol. 12, No. 5-6 ,
413-435.
[17] Lakshmi G. S., Rao C. S., Rao R. S., Hobbs P. J., Prakasham R. S.,
"Enhanced production of xylanase by a newly isolated Aspergillus
terreus under solid state fermentation using palm industrial waste: A
statistical optimization". Biochemical Engineering Journal 48 (2009)
51-57.
[18] Wen Z., Liao W., and Chen S., "Production of cellulase/β-glucosidase
by the mixed fungi culture of Trichoderma reesei and Aspergillus
phoenicis on dairy manure". Applied Biochem. Biotechnol., (2005) 121:
93-104.
[19] Sherief A. A., El-Tanash A.B., and Atia N., "Cellulase Production
by Aspergillus fumigatus Grown on Mixed Substrate of Rice Straw and
Wheat Bran". Research Journal of Microbiology (2010) 5(3):199-211.
[20] Adsul M.G., Ghule J.E., Singh R., Shaikh H., Bastawde K.B., Gokhale
D.V., and Varma A.J., "Polysaccharides from bagasse: applications in
cellulase and xylanase production". Carbohydrate Polymers 57 (2004)
67-72.
[21] Castaldi P., Garau G., and Melis P., "Maturity assessment of compost
from municipal solid waste through the study of enzyme activities and
water soluble fractions". Waste manage (2008) 28, 534-540.
[1] Albrecht A., Fischer G., Brunnemann-Stubbe G., Jäckel U., and
Kämpfer P., " Recommendations for study design and sampling
strategies for airborne microorganisms, MVOC and odours in the
surrounding of composting facilities". Int. J. Hyg. Environ. Health
211(2008) 121-131.
[2] Zahangir Alam M., Mamun A. A., Qudsieh I. Y., Muyibi S. A., Salleh
H. M., Omar N. M., "slid state bioconversion of oil palm empty fruit
bunches for cellulase enzyme production using a rotary drum
bioreactor". Biochemical Engineering Journal 46 (2009) 61-64.
[3] Song J. and Wei D., "Production and characterization of cellulases and
xylanases of Cellulosimicrobium cellulans grown in pretreated and
extracted bagasse and minimal nutrient medium M9-. Biomass and
Bioenergy 34 (2010) 1930-1934.
[4] Seyis I., and Aksoz N., "Effect of carbon and nitrogen sources on
xylanase production by Trichoderma harzianum 1073 D3".
International Biodeterioration & Biodegradation 55 (2005) 115-119.
[5] Gutierrez-Correa M., portal L., Moreno P., and Tengerdy R. P., "Mixed
culture solid substrate fermentation of Trichoderma reesei with
Aspergillus niger on sugar cane bagasse". Bioresource Technology 68
(1999) 173-178.
[6] Tengerdy R. P., and Szakacs G., "Bioconversion of lignocellulose in
solid substrate fermentation". Biochemical Engineering Journal 13
(2003) 169-179.
[7] Liu D., Zhang R., Yang X., Wu H., Xu D.,Tang Z., and Shen Q,
"Thermostable cellulase production of Aspergillus fumigatus Z5 under
solid-state fermentation and its application in degradation of agricultural
wastes". International Biodeterioration & Biodegradation 65 (2011)
717-725.
[8] Sonia K.G., Chadha B.S., and Saini H.S., "Sorghum straw for xylanase
hyper-production by Thermomyces lanuginosus (D2W3) under solidstate
fermentation". Bioresource Technology 96 (2005) 1561-1569.
[9] Datta R., "Acidogenic Fermentation of Lignocellulosic Acid Yield and
Conversion of Components". Biotechnol. Lett. 161(12), 1317-1322.
[10] Ghose T.K. and V.S. Bisaria, "Measurement of Hemicellulase Activities
Part 1: Xylanases". Pure & Appl. Chem., Vol. 59, No. 12, pp. 1739-
1752.
[11] B. Adney and J. Baker, "Measurement of Cellulase Activities". National
Renewable Energy Laboratory, 2008. Issue date: 08/12/1996. Pp. 1-8.
[12] Zhang Z. Y., Jin B., Bai Z. H., and Wang X.Y., "Production of fungal
biomass protein using microfungi from winery wastewater treatment".
Bioresource Technology 99 (2008) 3871-3876.
[13] Singh A. and Sharma S., "Composting of a Crop Residue through
Treatment with Microorganisms and Subsequent Vermicomposting".
Bioresource Technology. 85(2002) 107-111.
[14] Brookes P.C., "The use of microbial parameters in monitoring soil
pollution by heavy metals". Biology and Fertility of Soil (1995) 19:269-
279.
[15] Mondini C., Fornasier F., and Sinicco T., "Enzymatic activity as a
parameter for the characterization of the composting process". Soil
Biology & Biochemistry 36(2004) 1587-1594.
[16] Wong Ken K.Y. and Saddler John N., "Trichoderma Xylanase, Their
Properties and Application" Biotechnology. 1992, Vol. 12, No. 5-6 ,
413-435.
[17] Lakshmi G. S., Rao C. S., Rao R. S., Hobbs P. J., Prakasham R. S.,
"Enhanced production of xylanase by a newly isolated Aspergillus
terreus under solid state fermentation using palm industrial waste: A
statistical optimization". Biochemical Engineering Journal 48 (2009)
51-57.
[18] Wen Z., Liao W., and Chen S., "Production of cellulase/β-glucosidase
by the mixed fungi culture of Trichoderma reesei and Aspergillus
phoenicis on dairy manure". Applied Biochem. Biotechnol., (2005) 121:
93-104.
[19] Sherief A. A., El-Tanash A.B., and Atia N., "Cellulase Production
by Aspergillus fumigatus Grown on Mixed Substrate of Rice Straw and
Wheat Bran". Research Journal of Microbiology (2010) 5(3):199-211.
[20] Adsul M.G., Ghule J.E., Singh R., Shaikh H., Bastawde K.B., Gokhale
D.V., and Varma A.J., "Polysaccharides from bagasse: applications in
cellulase and xylanase production". Carbohydrate Polymers 57 (2004)
67-72.
[21] Castaldi P., Garau G., and Melis P., "Maturity assessment of compost
from municipal solid waste through the study of enzyme activities and
water soluble fractions". Waste manage (2008) 28, 534-540.
@article{"International Journal of Biological, Life and Agricultural Sciences:56044", author = "Dayana Amira R. and Roshanida A.R. and Rosli M.I.", title = "Effects of Xylanase and Cellulase Production during Composting of EFB and POME using Fungi", abstract = "Empty Fruit Bunches (EFB) and Palm Oil Mill
Effluent (POME) are two main wastes from oil palm industries which
contain rich lignocellulose. Degradation of EFB and POME by
microorganisms will produce hydrolytic enzyme which will degrade
cellulose and hemicellulose during composting process. However,
normal composting takes about four to six months to reach maturity.
Hence, application of fungi into compost can shorten the period of
composting. This study identifies the effect of xylanase and cellulase
produced by Aspergillus niger and Trichoderma virens on
composting process using EFB and POME. The degradation of EFB
and POME indicates the lignocellulolytic capacity of Aspergillus
niger and Trichoderma virens with more than 7% decrease in
hemicellulose and more than 25% decrease in cellulose for both
inoculated compost. Inoculation of Aspergillus niger and
Trichoderma virens also increased the enzyme activities during the
composting period compared to the control compost by 21% for both
xylanase and cellulase. Rapid rise in the activities of cellulase and
xylanase was observed by Aspergillus niger with the highest
activities of 14.41 FPU/mg and 3.89 IU/mg, respectively. Increased
activities of cellulase and xylanase also occurred in inoculation of
Trichoderma virens with the highest activities obtained at 13.21
FPU/mg and 4.43 IU/mg, respectively. Therefore, it is evident that
the inoculation of fungi can increase the enzyme activities hence
effectively degrading the EFB and POME.", keywords = "EFB, cellulase, POME, xylanase", volume = "6", number = "8", pages = "594-4", }
