Bioconversion and biotransformation of coir pith for economic production of Pleurotus florida: chemical and biochemical changes in coir pith during the mushroom growth and fructification

Coir pith represents ∼50% of the waste from the coir industries and was tested for its potential in serving as a growth substrate for the production of species of oyster mushroom, Pleurotus florida. Due to its high lignin (∼48%) content and amorphous powdery nature, coir pith supported poor mushroom mycelial growth and yields were considerably low (∼25% bioconversion efficiency). Pre-treating coir pith with hot water did not prove economical to produce the mushroom yields. Acid swelling and alkali delignification of coir pith though served to change the structure of coir pith; the mushroom yields were not improved. Amendment of coir pith with rice (Oryza sativa) straw and horse gram (Dolichos biflorus) plant residue tended to greatly modify the physical characteristics of the inoculated mushroom bed. Such a supplementation of coir pith growth substrate resulted in production of mushroom yields with 110–125% bioconversion efficiency. Implications of supplementing coir pith with rice straw/horse gram plant residue in terms of holocellulose:lignin ratio are discussed. Sensorially, the mushrooms so produced did not differ from that on rice straw, the economic growth substrate recommended for production of the mushroom yields on commercial scale. Changes in cellulose, hemicellulose and lignin contents of coir pith amended with rice straw were studied. Cellulase, hemicellulase and protease enzyme activities in the amended coir pith substrate showed a continuous increase from inoculation till the end of fructification, whereas laccase activity decreased during fructification, in consonance with decreased lignin degradation during fructification.     

Degradation dynamics of lignocellulose materials by wood-rottingPleurotus fungi

When grown on wheat straw,Pleurotus decomposes both the lignin and the cellulose components of the substrate. The course of degradation differs during growth and fructification. The losses of dry mass during growth were about 20 %. The absolute amount of hemicelluloses, cellulose and lignin was decreasing. Hemicelluloses and lignin were degraded at a higher rate than cellulose. The total mass losses of the substrate after fructification were 32 to 45 %. Cellulose was consumed at a higher rate than lignin.     

Production of extracellular enzymes by two Pleurotus species using banana pseudostem biomass

The degradation of lignocellulosic biomass of banana pseudoste was investigated during solid state fermentation (SSF) by P. ostreatus and P. sajor-caju. Both organisms proved to be efficient degraders of banana pseudostem biomass. P.ostreatus degraded hemicellulose (40% of dry weight, d.w.) better than cellulose (17.5% of d.w.) and lignin (10% of d.w.). P. sajor-caju also degraded hemicellulose (31% of d.w.) better than cellulose (12.4% of d.w.) and lignin (6% of d.w.). In both cases, a preferential removal of hemicellulose during the initial growth period and a delayed degradation of lignin were observed. The kinetics of cellulolytic, hemicellulolytic and lignolytic enzyme production in liquid culture were also examined. The activities of CMCase and β-glucosidase were highest at 16 days of growth and avicelase activity was at its maximum after 24 days (CMCase - 1.1 IU/ml, β-glucosidase - 0.09 IU/ml in the case of P. ostreatus; CMCase - 1.0 IU/ml, β-glucosidase - 0.087 - IU/ml in the case of P. sajor-caju.). Xylanase and laccase activity reached their maximum after day 16 and day 24 of incubation, respectively. (Xylanase - 1.1 IU/ml and laccase 3.0 IU/ml in the case of P. ostreatus; xylanase - 1.0 IU/ml and laccase - 3.6 IU/ml in the case of P. sajor-caju.). The efficient degrading capacity of test fungi demonstrated their potential use in the conversion of banana pseudostem biomass into mycelial protein-rich fermented animal feed.     

玉蕈降解木质纤维素的生理生化基础

本文研究了玉蕈在纤维废弃物上生长期间,培养基中主要成分的降解规律及有关的酶学分析。实验结果表明:1.玉蕈分解纤维素和半纤维素的能力较强,分解木素的能力很弱。因此,玉蕈是褐腐型木腐菌。2.纤维素是玉蕈子实体生长阶段的主要碳源。3.玉蕈生长期间可向培养基中释放羧甲基纤维素酶、滤纸纤维素酶、半纤维素酶、淀粉酶和蛋白酶。酶活性在子实体生长阶段显著增加。进一步证明了子实体阶段酶活性增加与培养温度和子实体形成有密切关系。     

Role of cell-wall biogenesis in the initiation of auxin-mediated growth in coleoptiles of Zea mays L.

The involvement of cell-wall polymer synthesis in auxin-mediated elongation of coleoptile segments from Zea mays L. was investigated with particular regard to the growth-limiting outer epidermis. There was no effect of indole acetic acid (IAA) on the incorporation of labeled glucose into the major polysaccharide wall fractions (cellulose, hemicellulose) within the first 2 h of IAA-induced growth. 2,6-Dichlorobenzonitrile inhibited cellulose synthesis strongly but had no effect on IAA-induced segment elongation even after a pretreatment period of 24 h, indicating that the growth response is independent of the apposition of new cellulose microfibrils at the epidermal cell wall. The incorporation of labeled leucine into total and cell-wall protein of the epidermis was promoted by IAA during the first 30 min of IAA-induced growth. Inhibition of IAA-induced growth by protein and RNA-synthesis inhibitors (cycloheximide, cordycepin) was accompanied by an inhibition of leucine incorporation into the epidermal cell wall during the first 30 min of induced growth but had no effect on the concomitant incorporation of monosaccharide precursors into the cellulose or hemicellulose fractions of this wall. It is concluded that at least one of the epidermal cell-wall proteins fulfills the criteria for a growth-limiting protein induced by IAA at the onset of the growth response. In contrast, the synthesis of the polysaccharide wall fractions cellulose and hemicellulose, as well as their transport and integration into the growing epidermal wall, appears to be independent of growth-limiting protein and these processes are therefore no part of the mechanism of growth control by IAA.Abbreviations CHI cycloheximide - COR cordycepin - DCB 2,6-dichlorobenzonitrile - GLP growth-limiting protein(s) - IAA indole-3-acetic acid     

Utilization of spent agro-residues from mushroom cultivation for biogas production

Summary Various spent agro-residues obtained after cultivation of the edible mushroom Pleurotus sajor-caju were used in anaerobic digestors for production of biogas. The changes that take place in the residues during bioconversion were quantified in terms of composition of cellulose, hemicellulose, lignin, carbon and nitrogen. These mycostraws resulted in increased biogas production over the untreated ones, which varied from 21.5% in the case of spent bagasse to 38.8% in the case of spent paddy straw. The increased biogas generation by the spent residues seems to be due to the increased susceptibility to digestion and more favourable C/N ratio of the residues. Offprint requests to: V. S. Bisaria     

Influence of biochemical quality on C and N mineralisation from a broad variety of plant materials in soil

We studied C and N mineralisation patterns from a large number of plant materials (76 samples, covering 37 species and several plant parts), and quantified how these patterns related to biological origin and selected indicators of chemical composition. We determined C and N contents of whole plant material, in water soluble material and in fractions (neutral detergent soluble material, cellulose, hemicellulose and lignin) obtained by stepwise chemical digestion (modified van Soest method). Plant materials were incubated in a sandy soil under standardised conditions (15 °C, optimal water content, no N limitation) for 217days, and CO₂ evolution and soil mineral N contents were monitored regularly. The chemical composition of the plant materials was very diverse, as indicated by total N ranging from 2 to 59 mg N g^–1, (i.e. C/N-ratios between 7 and 227). Few materials were lignified (median lignin=4% of total C). A large proportion of plant N was found in the neutral detergent soluble (NDS) fraction (average 84%) but less of the plant C (average 46%). Over the entire incubation period, holocellulose C content was the single factor that best explained the variability of C mineralisation (r=–0.73 to –0.82). Overall, lignin C explained only a small proportion of the variability in C mineralisation (r=–0.44 to –0.51), but the higher the lignin content, the narrower the range of cumulative C mineralisation. Initial net N mineralisation rate was most closely correlated (r=0.76) to water soluble N content of the plant materials, but from Day 22, net N mineralisation was most closely correlated to total plant N and NDS-N contents (r varied between 0.90 and 0.94). The NDS-N content could thus be used to roughly categorise the net N mineralisation patterns into (i) sustained net N immobilisation for several months; (ii) initial net N immobilisation, followed by some re-mineralisation; and (iii) initially rapid and substantial net N mineralisation. Contrary to other studies, we did not find plant residue C/N or lignin/N-ratio to be closely correlated to decomposition and N mineralisation.     

Biodegradation of lignin-carbohydrate complexes

Covalent lignin-carbohydrate (LC) linkages exist in lignocellulose from wood and groups herbaceous plants. In wood, they consist of ester and ether linkages through sugar hydroxyl to the -carbanol of phenylpropane subunits in lignin. In grasses, ferulic and p-coumaric acids are esterified to hemicelluloses and lignin, respectively. Hemicelluloses also contain substitutents and side groups that restrict enzymatic attack. Watersoluble lignin-carbohydrate complexes (LCCs) often precipitate during digestion with polysaccharidases, and the residual sugars are more diverse than the bulk hemicellulose. A number of microbial esterases and hemicellulose polysaccharidases including acetyl xylan esterase, ferulic acid esterase, and p-coumaric esterase attack hemicellulose side chains. Accessory hemicellulases include -l-arabinofuranosidase and -methyl-glucuranosidase. Both of these side chains are involved in LC bonds. -Glucosidase will attach sugar residues to lignin degradation products and when carbohydrate is attached to lignin, lignin peroxidase will depolymerize the lignin more readily.Abbreviations APPL acid precipitable polymeric lignin - CBQase cellobioquinone oxidoreductase - LC lignincarbohydrate - LCC(s) lignin-carbohydrate complex - DHP Dehydrogenative polymerisate - DMSO dimethylsulfoxide - DP degree of polymerisation - MWEL milled wood enzyme lignin - MWL milled wood lignin (not digested with carbohydrases)     

Utilization of sugarcane bagasse cellulose for producing cellulose acetates: Novel use of residual hemicellulose as plasticizer

Sugarcane bagasse was fractionated to cellulose, hemicellulose and lignin by a proprietary steam explosion process, followed by downstream purifications, developed in our laboratory. The fractionated cellulose contained ～94% cellulose, about ～5% hemicellulose, traces of lignin (～0.2%), and ～1% ash. The cellulose was acetylated under heterogeneous conditions to obtain cellulose acetates. These were extensively characterized using FTIR, TGA, DSC, GPC, HPIC, WAXRD, and viscometry. The novel feature of this study was the utilization of the hemicellulose content (5%) of bagasse cellulose as an internal plasticizer. Through kinetic experimentation, we have demonstrated that the residual hemicellulose need not be considered as an impurity; rather it can be used in acetylated form as a plasticizer as well as a biodegradable additive for cellulose acetates made from slightly impure cellulose produced from non-wood origin. Our results therefore show how lignocellulosic agricultural wastes can be utilized to produce high value plastics.     

Assessment of the biochemical composition of oilseed rape (Brassica napus L.) 13C-labelled residues by global methods,FTIR and 13C NMR CP/MAS

The biochemical composition of stems, pod walls and roots of oilseed rape (Brassica napus L.) plants, grown in a growth chamber with two levels of N fertiliser, was assessed by two global methods, i.e., serial extraction with the Van Soest's technique and temperature-programmed pyroanalysis (TP-Py). Statistical analysis of the effect of various parameters on the proportion of soluble components, hemicellulose, cellulose and lignin-like components in oilseed rape organs showed that the composition of plant materials depended on the N nutrition conditions during plant growth. Contents of soluble and hemicellulose fractions were affected by the technique used. Elsewhere, both global techniques resulted in similar proportions of skeletal cellulose (respectively 41 and 36% in low and high N stems, 37 and 30% in low and high N pod walls, 32 and 29% in low and high N roots) and of lignin-like components which ranged from about 7% in high N stems and pod walls to 16% in low N roots. Spectroscopy by FTIR showed a significant band at 1650 cm^–1 (amide I in proteins) in the root material (organ with the lowest C/N ratio) and the absence of lignin-specific bands. Carbon distribution by ¹³C NMR CP/MAS of labelled plants indicated that 60–64% was (cellulose + hemicellulose)-C, close to the values obtained by global methods. The proportion of aromatic-C (110–160 ppm) and phenolic ether was higher in roots than in stems and pod walls. Organs from oilseed rape plants with higher N contents exhibited a larger proportion of C in the 171 ppm chemical shift attributed to the peptide bond. The concomitance of a high level of aromatic and proteinaceous components in roots would reveal the presence of tannin–protein complexes in addition with true lignin.     

Growth,fruiting and lignocellulolytic enzyme production by the edible mushroom <Emphasis Type="Italic">Grifola frondosa</Emphasis> (maitake)

Cultivation of specialty mushrooms on lignocellulosic wastes represents one of the most economical organic recycling processes. Compared with other cultivated mushrooms, very little is known about the nature of the lignocellulolytic enzymes produced by the edible and medicinal fungus Grifola frondosa, the parameters affecting their production, and enzyme activity profiles during different stages of the developmental cycle. In this work we investigated the enzymes that enable G. frondosa, to colonize and deconstruct two formulations based on industrial lignocellulosic by-products. G. frondosa degraded both substrates (oak-sawdust plus corn bran, and oak/corn bran supplemented with coffee spent-ground) decreasing 67 and 50% of their lignin content, along with 44 and 37% of the polysaccharides (hemicellulose and cellulose) respectively. 35.3% biological efficiency was obtained when using oak sawdust plus corn bran as substrate. Coffee spent-ground addition inhibited mushroom production, decreased growth, xylanase and cellulase activities. However, taking into account that G. frondosa successfully colonized this residue; this substrate formula might be considered for its growth and medicinal polysaccharide production. Although G. frondosa tested positive for Azure B plate degradation, a qualitative assay for lignin-peroxidase, attempts to detect this activity during solid state fermentation were unsuccessful. Enzyme activities peaked during colonization but declined drastically during fruiting body formation. Highest activities achieved were: endoglucanase 12.3, exoglucanase 16.2, β-glucosidase 2.3, endoxylanase 20.3, amylase 0.26, laccase 14.8 and Mn-peroxidase 7.4 U/g dry substrate.     

Sugarcane Internode Composition During Crop Development

Sugarcane sugar and bagasse can be utilized for the production of ethanol or other biofuels. A better understanding of the changes in composition with development along the stalk and with crop development will maximize the usage of sugarcane for this purpose. Two experiments were designed to elucidate internode composition changes during the growing season. In experiment 1, an internode of stalks of 5 modern cultivars were marked at the start of elongation, and then sampled every 1 to 2?weeks from July until October. Sugars were extracted and assayed, and a sequential detergent method was used to estimate hemicellulose, cellulose, and lignin contents. In experiment 2, internodes 1, 3, 5, 7, 9, and 11 down the stalk were sampled in late July (grand growth) and late September (ripening). Internode length, fresh weight, dry weight, water content, and sugar contents were determined as well as cell wall composition. Both experiments were repeated in 2?years. As internodes elongated, total sugar increased, and hemicellulose decreased as a proportion of neutral detergent fiber, while cellulose and lignin increased. After elongation, sucrose and lignin increased, and cellulose content decreased with internode age. The variability in cell wall composition among the five cultivars suggests that selection for desirable composition may be possible. In Experiment 2, hemicellulose contents were lower, and lignin and ash contents were higher at ripening than during grand growth. Delaying sugarcane harvest to maximize sucrose content may decrease bagasse suitability for cellulosic ethanol production because of the increased lignin content.     

糙皮侧耳（平菇）菌株CCEF89的生理生化研究

基于5mg/kg Cu²⁺以及1mL/L愈创木酚处理下的栽培料,通过对糙皮侧耳（平菇）菌株CCEF89的生长特性、降解过程、酶活产量以及胞外蛋白质含量的测定与分析,揭示了该菌株在营养生长和子实体形成过程中的生理生化变化。生长特性测定表明,2,2’-连氮基-双-(3-乙基苯并二氢噻唑啉-6-磺酸)二铵盐（ABTS）、愈创木酚、MnCl₂使菌丝生长变慢。菌丝在前10d主要对酸不溶木质素和半纤维素进行降解,20d开始利用纤维素和酸溶木质素。5mg/kg Cu²⁺处理的栽培料会促进菌丝生长,出菇期提前并促进漆酶分泌,而1mL/L愈创木酚的处理则在某种程度上对营养生长和子实体发育有抑制作用。12d后,羧甲基纤维素酶活与木聚糖酶具有极显著正相关性,且羧甲基纤维素酶活与胞外蛋白质含量也存在相关性。     

Succession and activity of microorganisms in stored bagasse

Summary Fresh sugarcane bagasse was fermented under defined conditions and investigated regarding a microbial succession during fermentation, in view of the enzyme activities of microorganisms against the main bagasse components: sucrose, pectin, hemicellulose, cellulose, and lignin.Altogether, 400 pure cultures of microorganisms were obtained from 8 g bagasse during 6.5 days of storage. This flora consists of bacteria (74%), actinomycetes (6%), yeasts (13%), and fungi (7%). The yeasts dominate in early fermentation, followed by bacteria, and then by actinomycetes and fungi.This succession coincides with the enzymic activities of the isolated organisms during fermentation. At first, residual sugar is consumed predominantly by the yeasts. Then the bacteria degrade the pectin, the hemicellulose, and in parts, the cellulose. Later, the actinomycetes and the fungi imperfecti attack the hemicellulose, the cellulose, and, partly, the lignin within the bagasse fiber.These results are corroborated by investigations using bagasse from bulk storage.     

Bioalteration of Kraft pine lignin byPhanerochaete chrysosporium

Bioalteration of the organic-soluble ether-insoluble fraction of Kraft pine lignin (KL-O) was studied. Various types of inocula ofPhanerochaeta chrysosporium were compared using a standing mode of cultivation under nitrogen limitation. Pellet inoculated and mycelial cultures required a period of about 10 days to become ligninolytically active. When spores were used as inoculum the bioalteration of lignin commenced earlier but the rate was considerably less. The total decrease in absorbance measured amounted to 61% within 20 days after addition of lignin to active mycelial cultures. This corresponded to a reduction of 50% in Klason lignin. Further reduction was possible only when the free lignin was extracted from the culture, purified and mixed with new active cells. Elemental analysis, Klason lignin content, absorptivity coefficient, molecular weight distribution and the presence of saccharides and proteins for free and cell recovered lignin were compared with KL-O. Microscopic observation showed the formation of new out-growths in the form of short hyphae appearing concurrently with ligninolytic activity.Abbreviations GPC Gel Permeation Chromatography - TLC Thin Layer Chromatography - rpm revolutions per minute - vvm volume per volume per minute     

Recycling of spent shiitake substrate for production of the oyster mushroom,Pleurotus sajor-caju

Pleurotus sajor-caju was produced on a basal medium containing spent shiitake substrate plus 10% wheat bran and 10% millet. An analysis of the fibrous composition of the spent shiitake substrate revealed that 85% of the original hemicellulose, 44% of the original cellulose and 77% of the original lignin was not consumed during production of a full crop (78% biological efficiency) of shiitake (63-day harvest period). To produce P. sajor-caju, the spent shiitake substrate was ground, air dried, supplemented, pasteurized with live steam and spawned. Highest yields (79% biological efficiency) of P. sajor-caju were obtained by supplementing the spent shiitake basal medium with 12% soybean and 1% CaCO₃. Increases in percentage biological efficiency and mushroom size were positively correlated with increasing levels of CaCO₃ added to the basal medium.     

鸡腿菇对棉籽壳的降解与转化

栽培在棉籽壳培养基中的鸡腿菇具有较强的木质纤维素降解能力和较高的绝对生物学效率;木质纤维素是子实体生长阶段的主要碳源;CMC酶、FP酶和HC酶的活性变化与纤维素、半纤维素的降解速率正相关,漆酶的活性变化与木质素的降解速率正相关,而过氧化物酶的活性变化与木质素的降解速率没有相关性;淀粉酶在菌丝生长阶段活性较高,蛋白酶的活性高峰出现在子实体生长发育期。     

RNA复合物对松茸子实体的作用

施用核糖核酸和5,-核苷酸试验,其对生长于林间的松茸子实体的活化作用。在形成子实体之前将RNA关联物的水溶液直接洒入带有菌丝群落的松树林地表层。为了估计处于生长和形成子实体时期菌丝的状况对高菌根含量根中核苷、麦角固醇和磷脂的含量进行分析。与对照相比,RNA关联物的水溶液对提高核苷、麦角固醇和磷脂含量有作用,施用RNA关联物后9天磷脂含量迅速增加,RNA关联物有助于形成密集的菌丝群落。试验最后结果表明在形成子实体的两周时间内关联物使松茸子实体的产量和数量显著增加。     

Comparative ligninolytic and polysaccharolytic potentials of an alkaliphilic basidiomycete on native ligninocellulose

A comparison of the ligninolytic, cellulolytic and hemicellulolytic abilities of an alkaliphilic white-rot fungus. Coprinus fimetarius, on wheat straw under varying conditions of solid-substrate fermentation is presented. The extent of fractional degradation (percentage of the original dry weight of the fraction) of straw under an optimized set of cultural conditions (pH 9·0, moisture 65%, temperature 37°C, period 21 days) was in the following order: lignin (45%), cellulose (42%), hemicellulose (27%). Urea nitrogen favoured the degradation of lignin as well as cellulose and hemicellulose up to a certain level (1·5% sterile urea or 3% unsterile urea on a dry weight basis) beyond which the degradation of lignin was relatively more adversely affected than cellulose. The addition of phosphorus and sulphur was found essential for selective lignin removal. Increasing the C:N ratio by addition of free carbohydrates resulted in an overall decrease in the degradation wherein cellulose utilization was the most affected event. The pre-treatment (physical or chemical) of the substrate caused a general increase in biodegradation of lignin, cellulose and hemicellulose. The degrading activity of the fungus declined with the scaling-up of the fermentation particularly under non-sterile conditions.     

Litter decay rates are determined by lignin chemistry

Litter decay rates are often correlated with the initial lignin:N or lignin:cellulose content of litter, suggesting that interactions between lignin and more labile compounds are important controls over litter decomposition. The chemical composition of lignin may influence these interactions, if lignin physically or chemically protects labile components from microbial attack. We tested the effect of lignin chemical composition on litter decay in the field during a year-long litterbag study using the model system Arabidopsis thaliana. Three Arabidopsis plant types were used, including one with high amounts of guaiacyl-type lignin, one with high aldehyde- and p-hydroxyphenyl-type lignin, and a wild type control with high syringyl-type lignin. The high aldehyde litter lost significantly more mass than the other plant types, due to greater losses of cellulose, hemicellulose, and N. Aldehyde-rich lignins and p-hydroxyphenyl-type lignins have low levels of cross-linking between lignins and polysaccharides, supporting the hypothesis that chemical protection of labile polysaccharides and N is a mechanism by which lignin controls total litter decay rates. 2D NMR of litters showed that lignin losses were associated with the ratio of guaiacyl-to-p-hydroxyphenyl units in lignin, because these units polymerize to form different amounts of labile- and recalcitrant-linkages within the lignin polymer. Different controls over lignin decay and polysaccharide and N decay may explain why lignin:N and lignin:cellulose ratios can be better predictors of decay rates than lignin content alone.