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Electronic Journal of Biotechnology, Vol. 9, No. 3, Special Issue, 2006, pg. 215-220 RESEARCH ARTICLE Biodegradation of agroindustrial wastes by Pleurotus spp for its use as ruminant feed Silvana Alborés*1, María Julia Pianzzola2, Matilde Soubes3, María Pía Cerdeiras4 1Departamento
de Biociencias,
Facultad de Química,
Universidad de Financial
support: Project INIA-LIA 057, CSIC 308 and by the Maestría en Biotecnología,
Facultad de Ciencias, Universidad de Code Number: ej06028 The increasing expansion of agro-industrial activity has led to the accumulation of a large quantity of lignocellulosic residues all over the world. In particular, large quantities of rice straw (300.000 t) and citric bagasse (50.000 t) are annually produced in Uruguay. In this work we present the study of the bioconversion of these substrates with the edible mushroom Pleurotus spp so as to increase nutritional values and digestibility for its use as animal feed. The SSF process was optimized and the products after different periods of mushroom growth were evaluated. The microbial counts (cfu/g) for the inoculated substrates 44 days after incubation were 15 x 104, < 10 and < 10 for aerobic microorganisms, coliforms and E. coli, respectively. After 14 days of SSF the percentage of dry matter, ADF and NDF decreased, and the content of protein increased. These results show that vegetal cell-wall components were degraded during the period of mushroom incubation. PCR RFLP analysis of the ITS region was used to characterize the Pleurotus species produced in Uruguay and discriminate between DNAs of Pleurotus ostreatus 814 and other fungi from the different substrates. Keywords: agroindustry, basidiomycetes, ruminant feed.
From the
production, processing and consumption of agricultural products, there are
a great variety of remainders, which create increasing problems of elimination.
In Uruguay, the great majority of the industries that process agricultural
products discard their remainders with no treatment, implying a huge aggression
to the environment. For example, the citrus processing plants produce 50,000
tons per year of citric bagasse which represents 40-50% in weight of the
fresh fruit. Its composition is relatively adequate for the feeding of ruminants,
but present palatability problems and is contaminated with normal flora of
the rinds, some of which are mycotoxin producers. With respect to rice straw
it is obtained at the rate of Other authors have shown that some fungi, particularly some species of Pleurotus are able to colonize different types of vegetable wastes, increasing their digestibility (Platt et al. 1984; Commanday and Macy, 1985; Rajarathnam and Bano, 1989; Villas-Boas et al. 2002; Zhang et al. 2002; Mukherjee and Nandi, 2004; Salmones et al. 2005). Previous studies have shown the feasibility of using these kind of wastes to produce animal feed (Calzada et al. 1987; Adamovic et al. 1998), and as substrate for mushroom production (Breene, 1990; Sermanni et al. 1994; Kakkar and Dañad, 1998; Yildiz et al. 2002). In the present work, we study the biodegradation of these wastes by P. ostreatus 814 for its use as ruminant feed. Determination of the capacity to grow on the wastes under study The strains
used in this study (P. ostreatus 814, P. ostreatus 816, P.
cornucopiae and P. djmour) were provided by Trinidad Mushrooms. They
were grown in malt agar (1,25% malt extract, 1,5% agar, Oxoid) at From these experiments, P. ostreatus 814 was the most promising strain. Evaluation of the characteristics of the fermentation products 1. Determination of the microbiological quality was performed using Petrifilm (3M). Total aerobes, total coliforms and E. coli were determined on the substrates without inoculation and after 44 days of fermentation with P. ostreatus 814. 2. Analysis of the chemical composition of the fermentation product consisted in the analysis of dry weight (AOAC, 1990), proteins (AOAC, 1990) and neutral and acid detergent fiber (AOAC, 1996) of the different substrates without inoculating and on different days of fermentation with P. ostreatus 814. The results were analyzed using t-Student test with P < 0.001. The significance of the differences were estimated by using the Mann-Whitney U test (Mann and Whitney, 1947), with the limit of significance set at P < 0,05. Statistical analyses were performed on SPSS 9.0 Windows. DNA extraction. Genomic DNA was obtained from pure cultures of fungi belonging to the mushroom producers Trinidad Mushrooms (Pleurotus ostreatus 814, Pleurotus ostreatus 816, Pleurotus cornucopiae y Pleurotus djmour) or from the fermentation product after inoculation of wheat seeds or citrus bagasse. Fresh mycelia or the corresponding fermentation product was grounded under liquid nitrogen in a sterile mortar, to obtain a fine powder. The extraction technique performed followed (Jasalavich et al. 2000), and is based in the classical extraction with cetyltrimethylammonium bromide (CTAB) in the presence of β-mercaptoethanol, followed by organic extractions and isopropanol precipitation of the DNA. DNA was quantified by spectrophotometrical measurement at 260 and 280 nm and its integrity was evaluated in 0,8% agarose gels, using ethidium bromide (EtBr). DNA bands were visualized by the fluorescence of the intercalated EtBr under UV light. PCR
amplification. The ITS region was amplified by PCR from DNA isolated
from pure cultures of each of the fungi under study and from the corresponding
fermentation product. Primers ITS1-F (CTT GGT CAT TTA GAG GAA GTA A) which
is specific for the higher fungi, and ITS4 (TCC TCC GCT TAT TGA TAT GC)
the universal primer, were used together to amplify the ITS region from
higher fungi. The primer pair ITS1-F and ITS4-B (CAG GAG ACT TGT ACA CGG
TCC AG), which is specific for basidiomycetes, were used to specifically
amplify the ITS region from only basidiomycetes. Amplification were performed
in 50 μl reactions of PCR buffer (Invitrogen), Restriction
digestion of PCR products. PCR reaction products were digested directly
without further purification with restriction endonucleases to obtain RFLPs;
each sample was digested with AluI (Biolabs), HaeIII (Biolabs) and TaqI (Biolabs) in single-enzyme
digests. 10 μl of amplified PCR reaction was mixed with the appropriate
restriction reaction buffer and 10 U of the appropriate enzyme and then
incubated for 6 hrs at Determination of the capacity to grow on the wastes At 7 days of fermentation fungal growth is already appreciated on all the substrates under study, with all the strains assayed. A greater colonization is achieved at day 21 with P. ostreatus 814 (Figure 1). Determination of the microbiological quality Although an increase in the total aerobic count is seen for citrus bagasse with respect to day 0, no appreciable increase in total coliforms or E. coli is appreciated (Table 1).
Analysis of the chemical composition After fermentation, a decrease in the dry weight, increase in the levels of proteins and a decrease in the values of neutral detergent fiber (hemicellulose, cellulose and lignin) and acid detergent fiber (lignin and cellulose) were detected (Table 2). These last determinations could be indicative of the degradation of the cell wall components of the substrates produced by the extracellular enzymes of P. ostreatus. Previous authors concluded that lignification of structural polysaccharides not only inhibited ruminal microbial digestion of polysaccharides by forming 3-D matrix, but also that the presence of highly lignified tissues formed a physical barrier preventing the accessibility of the otherwise highly digestible tissues to the action of hydrolytic enzyme of the rumen microorganisms (Karunanandaa et al. 1995), and have shown that increased digestibility was associated with the degradation of structural carbohydrates (Mukherjee and Nandi, 2004).
No nitrogen source was added, as previous work showed that the in vitro digestibility of the fermented substrate was decreased as compared with fermentation substrate not amended with nitrogen. Molecular characterization of the strains under study When using primers ITS1F and ITS4B, specific for basidiomycetes, an interspecies polymorphism is observed in the band profile obtained, whilst there is no difference observed within a same species (Figure 2a). When making the amplification with primers ITS1F and ITS4, general for higher fungi, the same restriction profile for fungi of the same species (P. ostreatus 814 and 816) is obtained. This same profile is obtained when DNA is extracted from the substrates under study colonized by P. ostreatus 814. It is important to emphasize that when using these general primers no additional bands, that could correspond to other fungi, were obtained (Figure 2b). These results show not only that strain in use in the mushroom producing industry can be identified to species level using molecular techniques, but also that it is plausible to carry out a molecular characterization of the fermentation products (Villas-Boas et al. 2002). From the results obtained, we can conclude that P. ostreatus 814 is an appropriate strain to use as inocula of the agroindustrial wastes under study. Higher protein levels, better conservation of the substrate and an increase in in vitro digestibility is observed. A scale up process, using rice straw bales in the open, is under way.
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