An investigation of the microbial hydrolysis of the lignin carbohydrate complex of grasses

Stevens, Gary Grant

03 1900

Thesis (MSc)--University of Stellenbosch, 2004. / ENGLISH ABSTRACT: The microbial degradation of the lignin carbohydrate complex of plant material is only partially understood. Lignin carbohydrate complex was extracted from wheat straw and subsequently analysed. An adjustment to the standard protocol was required to increase the amount of lignin carbohydrate complex extracted from wheat straw. Characterization of the lignin carbohydrate complex after trifluoacetic acid hydrolysis was done by capillary electrophoresis. HPLC proved ineffective, as baseline separation could not be achieved. Characterization of the lignin carbohydrate complex revealed that a large portion (68 %) consisted of carbohydrate and lignin (20 %). Capillary electrophoresis of the trifluoroacetic acid hydrolysates of the lignin carbohydrate complex revealed that the carbohydrates consisted of mannose, xylose, arabinose, galactose, glucose and rhamnose. The major monosaccharide present in the lignin carbohydrate complex was mannose which made up 34 % of the total carbohydrate composition. Ferulic and p-coumaric acid were present in the lignin carbohydrate complex, but in concentrations less than 1 % of the lignin carbohydrate complex. The lignin carbohydrate complex of wheat straw probably had a heterogenous structure consisting of a variety of molecules, as molecular weight determination could not be accurately determined. An estimated molecular weight of 5.9 kOa was determined. Ten fungal strains (Aspergillus niger, Aureobasidium pul/u/ans, Bjerkandera adusta, Corio/us versicolor, Lenzitus betu/ina, Phanerochaete chrysosporium, Pycnoporus coccineus, Pycnoporus sanguineus 294, Pycnoporus sanguineus K5-2-3 and Trichoderma reeseï; were evaluated for growth on the lignin carbohydrate complex. All strains except B. adusta showed growth after 5 days with A. niger, A. pul/u/ans, C. versicolor, P. chrysosoporium and T. reesei showing the best growth on the lignin carbohydrate complex. The culture fluid revealed a number of proteins secreted by these organisms. The protein determination was confirmed by SOS-PAGE which revealed an array of proteins ranging from 8 kOa to 180 kOA. Prominent bands between 26 kOa and 80 kOa could be observed in the culture fluid of A. niger, A. pul/ulans and T. reesei, but not in C. versicolor. Activity studies on the culture fluid of these four strains revealed activity for xylanase, xylosidase, arabinofuranosidase, ferulic acid esterase and laccase, with vast differences between the activities of the various fungi. The enzymes of these fungal strains were also evaluated for their ability to degrade xylan and sugar cane bagasse using capillary electrophoresis. It appeared that all the organisms produced enzymes to degrade birchwood xylan. However, the electropherograms revealed that the degradation patterns of birchwood xylan differed among these organisms over the same time interval, as xylotetraose, xylotriose, xylobiose and xylose were released in various concentrations. The electropherograms obtained from the enzyme hydrolysates of sugar cane bagasse, pointed to the substrate being inaccessible. Electropherograms of the culture fluid of A. niger, A. pul/ulans, C. versicolor and T. reesei, when incubated on the lignin carbohydrate complex indicated similar peaks to those obtained and identified in the trifluoroacetic acid hydrolysates. However, the electropherograms of the culture fluid of these organisms revealed additional smaller peaks which could not be identified. The electropherograms of the culture fluid of the various organisms also indicated a complete release of some sugars, using the trifluoacetic acid hydrolysate of the lignin carbohydrate complex as a control for the amount of sugars present. HPLC analyses revealed that after 72 h, no apparent degradation of the lignin carbohydrate complex took place as peak height and areas appeared to be similar. These peaks could however not be identified due to a lack of standards as well as baseline separation which could not be achieved. / AFRIKAANSE OPSOMMING: Tans word die mikrobiese afbraak van die lignienkoolhidraatkompleks van plant materiaal slegs gedeeltelik verstaan. Lignienkoolhidraatkompleks was vanaf koringstrooi geïsoleer en gevolglik geanaliseer. Daar moes van die standaard prosedure vir die ekstraksie van lignienkoolhidraatkompleks afgewyk word ten einde beter lignienkoolhidraatkompleks opbrengs te lewer. Karakterisering van die lignienkoolhidraatkompleks na trifluoroasynsuurvertering was deur kapillêre elektroforese bepaal. Dit wou voorkom asof kapillêre elektroforese "n beter opsie vir die analise van die verteerde monster van lignienkoolhidraatkompleks is, vergeleke met hoëdruk vloeistof chromatografie. Daar was gevind dat die lignienkoolhidraatkompleks uit 68 % koolhidraat en 20 % lignien bestaan. Kapillêre elektroforese het die teenwoordigheid van die volgende suikers bevestig naamlik, mannose, xilose, arabinose, glukose, galaktose en ramnose. Mannose was die dominerende suiker in die lignienkoolhidraatkompleks wat 34 % van die totale koolhidraat opbrengs uitgemaak het. Ferulien- en p-kumaarsuur kon ook identifiseer word, maar die twee sure het minder as 1 % van die totale inhoud van die lignienkoolhidraatkompleks uitgemaak. Vanuit resultate bekom wil dit voorkom dat die lignienkoolhidraatkompleks "n heterogene molekuul is omdat die molekulêre gewig daarvan nie akkuraat bepaal kon word nie. 'n Geskatte molekulêre grootte van ongeveer 5.9 kDa was bepaal met verwysing na die hoogste piek wat in die chromatogram waargeneem was. Tien fungus kulture was in die studie gebruik om hul vermoë te toets om op die lignienkoolhidraatkompleks te groei, naamlik Aspergillus niger, Aureobasidium pullulans, Bjerkandera adusfa, Goriolus versicolor, Lenziius betuline. Phanerochaefe chrysosporium, Pycnoporus coccineus, Pycnoporus sanguineus 294, Pycnoporus sanguineus K5-2-3 en Trichoderma reesei. B. eauste het nie groei na 5 dae getoon nie, en dit wou voorkom asof A. niger, A. pul/ulans, G. versicolor, P. chrysosoporium en T. reesei die beste kon groei op die substraat na 5 dae. Die kultuurvloeistof van die vier kulture het getoon dat proteïene deur hierdie organisms uitgeskei was. Hierdie proteinbepaling was ook bevestig deur SOS-PAGE, wat bande tussen 8 kDa en 180 kDa gelewer het. Prominente bande tussen 26 kDa en 80 kDa kon waargeneem word in die kultuurvloeistof van A. niger, A. pul/ulans, en T. reesei, maar nie in die kultuurvloeistof van C. versicolor nie. Aktiwiteitstudies op die kultuur vloeistowwe het getoon dat daar aktiwiteit was vir die volgende ensieme, naamlik xilanase, xilosidase, arabinofuranosidase en feruliensuur esterase. Hierdie aktiwiteit het aansienlik verskil tussen die verskillende organismes. Die ensieme van die vier organismes was ook gebruik om hul vermoë te toets om xilaan en suikerriet af te breek. Daar was gevind dat xilaanafbraak verskillend was vir die organisms oor dieselfde tydperk. Xilotetraose, xilotriose, xilobiose en xilose was in verskillende konsentrasies gevind vir die verskillende organismes. Die elektroferogramme van die kultuurvloeistof op suikerriet van die verskillende organismes het getoon dat die substraat nie toeganklik vir die ensieme was nie. Die elektroferogramme van die kultuurvloeistof op lignienkoolhidraatkompleks van die verskillende organismes het dieselfde pieke getoon soos geïdentifiseer in die elektroferogramme van die trifluoroasynsuur vertering. Die elektroferogramme met die ensiem vertering het egter addisionele pieke getoon wat nie sigbaar op die elektroferogramme van die trifluoroasynsuur vertering was nie. Hierdie pieke het min of meer dieselfde tyd ge-elueer as die monosakkariede. Kapillêre elektroforese het ook getoon dat die ensiematiese afbraak van die lignienkoolhidraatkompleks gelei het tot algehele vrystelling van sommige suikers, wanneer die trifluoroasynsuur vertering as maatstaaf dien vir die hoeveelheid suikers teenwoordig in die lignienkoolhidraatkompleks. Hoëdruk vloeistof chromatografie het getoon dat geen sigbare afbraak na 72 h van inkubasie met die ensieme op die lignienkoolhidraatkompleks plaasgevind het nie aangesien die piek hoogtes konstant gebly het. Hierdie pieke kon egter nie geïdentifiseer word nie as gevolg van lae resolusie van die pieke asook standaarde wat nie beskikbaar was nie.

Wheat straw -- Microbiology

Straw -- Biodegradation

Grasses -- Microbiology

Lignin -- Biodegradation

Hydrolysis

Linking soluble C to microbial community composition and dynamics during decomposition of ����C-labeled ryegrass

McMahon, Shawna K.

13 January 2004

Ryegrass residue consists of three main C fractions: readily available soluble C, intermediately available cellulose and hemicellulose, and slowly available lignin. Changes in chemical composition during decomposition influence rate of degradation as well as composition of the microbial community involved. Use of ����C-labeled plant material coupled with analysis of phospholipid fatty acids (PLEA) by isotope ratio mass spectrometry results in a powerful tool for linking microbial community structure and C cycling processes during decomposition. The objective was to investigate the role of soluble C in the decomposition of ryegrass straw. We wanted to determine (i) if the presence or absence of labile C in straw affects C mineralization by the microbial community, (ii) if community structure would differ based on the presence of labile C, and (iii) if community structure would shift as decomposition progressed. Residue was added to soil microcosms at rates that reflect field loads. Treatments were unleached straw (US), leached straw (LS), and leachate (L), plus an unamended control (C). Added substrates had ������C values between 120% and 180% the native soil signature was 26%. Respiration was measured every 4 to 6 hours for the first 5 d, and weekly thereafter. Destructive sampling took place after 0.6, 1 .6, 1 5, 1 8. 50, and 80 d of incubation and microbial biomass '��C (MBC) and PLFAs were analyzed. The soluble component of ryegrass straw strongly influenced C mineralization and assimilation, as well as microbial community composition and dynamics. CO2 evolution rates and ����C signatures were similar in US and L during the first 3 d of incubation. Most soluble C from leachate was consumed during that time, indicated by the rapid decrease in ������C value of CO2 evolved from L treatment. Substrate-derived C moved quickly into and through the microbial biomass. Distinct temporal shifts occurred in community composition. Early communities in amended soils were dominated by short and branched-chain PLFAs such as 15:Oa. Later samples contained more complex and longer PLFAs. 19:Ocy was an indicator for late succession communities in US and L, and 18:2w6,9 characterized late samples in LS. Soluble C affected when the temporal shift occurred in LS and L, communities shifted earlier than in US. Lipids were differentially enriched with ����C. Fungi, as indicated by 18:2w6,9, were more effective at incorporating substrate C into cellular lipids, as this was the most highly labeled of all PLFAs. / Graduation date: 2004

Ryegrasses

Straw -- Biodegradation

Carbon cycle (Biogeochemistry)

Microbial ecology

The influence of inorganic matrices on the decomposition of organic materials

Skene, Trudi Marie.

January 1997

Bibliography: leaves 134-148. The objectives of this study are to determine if and how inorganic matrices influence organic matter decomposition with particular emphasis on the biochemical changes which occur as decomposition progresses. The influence of inorganic matrices (sand, sand + kaolin and loamy sand) on the decomposition of straw and Eucalyptus litter during incubations was followed by various chemical and spectroscopic methods to aid in the understanding of the mechanism of physical protection of organic matter in soils.

Soil biochemistry

Humus Biodegradation

Straw Biodegradation

Eucalyptus

Organic compounds Biodegradation

Forest litter Biodegradation

The influence of inorganic matrices on the decomposition of organic materials / by Trudi Marie Skene.

Skene, Trudi Marie

January 1997

Bibliography: leaves 134-148. / xi, 148 leaves : ill. ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / The objectives of this study are to determine if and how inorganic matrices influence organic matter decomposition with particular emphasis on the biochemical changes which occur as decomposition progresses. The influence of inorganic matrices (sand, sand + kaolin and loamy sand) on the decomposition of straw and Eucalyptus litter during incubations was followed by various chemical and spectroscopic methods to aid in the understanding of the mechanism of physical protection of organic matter in soils. / Thesis (Ph.D.)--University of Adelaide, Dept. of Soil Science, 1997

Soil biochemistry.

Humus Biodegradation.

Straw Biodegradation.

Eucalyptus.

Organic compounds Biodegradation.

Forest litter Biodegradation.