Richard Lab:Enzymatic Hydrolysis of Biomass

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#Weigh out a biomass sample equal to the equivalent of 0.15 g dry biomass (calculated based on the results of the previous step) and add to a 15mL centrifuge tube.  It is assumed that this is roughly equivalent to 0.1g cellulose.  
#Weigh out a biomass sample equal to the equivalent of 0.15 g dry biomass (calculated based on the results of the previous step) and add to a 15mL centrifuge tube.  It is assumed that this is roughly equivalent to 0.1g cellulose.  
#To each vial, add:
#To each vial, add:
-
##5.0mL sodium citrate buffer(0.1 M, pH 4.8)
+
##500μL sodium citrate buffer(1 M, pH 4.8)
##40μL tetracycline solution (400 μg  
##40μL tetracycline solution (400 μg  
##30μL cycloheximide solution (300 μg)  
##30μL cycloheximide solution (300 μg)  
Line 46: Line 46:
##All solutions and the biomass are assumed to have a specific gravity of 1.000 g/mL. Thus, if 0.200 g of biomass was added to the vial, it is assumed to occupy 0.200 mL and 9.733 mL of liquid is to be added.  
##All solutions and the biomass are assumed to have a specific gravity of 1.000 g/mL. Thus, if 0.200 g of biomass was added to the vial, it is assumed to occupy 0.200 mL and 9.733 mL of liquid is to be added.  
#Add the following to each tube:
#Add the following to each tube:
-
##an appropriate volume of the cellulase enzyme preparation to equal approximately 60 FPU/g cellulose and  
+
##an appropriate volume of the cellulase enzyme preparation to equal approximately 5 FPU/dry g cellulose(low enzyme loading) or 15 FPU/dry g cellulose (high enzyme loading)and  
-
##the appropriate volume of β-glucosidase enzyme to equal 64 pNPGU/g cellulose.  
+
##the appropriate volume of β-glucosidase enzyme to equal 20 CBU/dry g cellulose or 60 CBU/dry g cellulose.  
##Xylase may be added at the same time (if desired).  
##Xylase may be added at the same time (if desired).  
#Prepare control blanks  
#Prepare control blanks  

Revision as of 15:56, 4 February 2011

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Enzymatic Saccharification of Lignocellulosic Biomass
Laboratory Analytical Procedure for 0.15 g of dry mass

Contents

Introduction

This procedure describes the enzymatic saccharification of cellulose from native or pretreated lignocellulosic biomass to glucose in order to determine the maximum extent of digestibility possible. A saturating level of a commercially available cellulase preparation and hydrolysis times up to one week are used. This procedure is appropriate for lignocellulosic biomass. This procedure can also be used to measure the efficacy of a given pretreatment based on a maximum enzyme loading.

Interferences

Unwashed acid- and alkaline-pretreated biomass samples may change solution pH to values outside the range of enzymatic activity; and the unwashed glucose in the biomass may influence the final result.

Materials

Equipment

  1. A suitable shaking or static incubator set at 50°C ± 1°C
  2. A fixed speed rotator that can hold vials and operate in a static incubator.
  3. 5ml or 30ml centrifuge tubes
  4. pH meter
  5. Analytical balance, accurate to 1 mg or 0.1 mg
  6. YSI analyzer with appropriate membranes or equivalent glucose quantification method such as HPLC or IC
  7. pipet with tips

Reagents

  1. Antibiotics
    1. Tetracycline stock solution (10 mg/mL in 70% ethanol). (light sensitive, wrap in foil)
    2. Cycloheximide stock solution (1 mg/mL in distilled water).
    3. Alternate antibiotic – Sodium Azide (20 mg/ml in distilled water)
  2. Sodium citrate buffer (1 M, pH 4.80).
  3. Cellulase enzyme of known activity, FPU/mL. (we use spezyme)
  4. Beta-glucosidase enzyme of known activity, pNPGU/mL (we use novozme)
  • (If necessary) Xylanase enzyme of known protein concentration, mg/ml

Procedure

  1. Determine the solids content for all cellulose containing samples to be digested.
    1. label metal trays
    2. mass of metal tray
    3. mass of tray plus about 1 gram of material
    4. oven dry at 105 C for 24 hours
    5. mass of tray and material
    6. calculate percent solids
  2. Weigh out a biomass sample equal to the equivalent of 0.15 g dry biomass (calculated based on the results of the previous step) and add to a 15mL centrifuge tube. It is assumed that this is roughly equivalent to 0.1g cellulose.
  3. To each vial, add:
    1. 500μL sodium citrate buffer(1 M, pH 4.8)
    2. 40μL tetracycline solution (400 μg
    3. 30μL cycloheximide solution (300 μg)
  4. Add the appropriate calculated volume of water to each tube to bring the total volume to 10.00 mL after addition of the enzymes specified in the following step.
    1. All solutions and the biomass are assumed to have a specific gravity of 1.000 g/mL. Thus, if 0.200 g of biomass was added to the vial, it is assumed to occupy 0.200 mL and 9.733 mL of liquid is to be added.
  5. Add the following to each tube:
    1. an appropriate volume of the cellulase enzyme preparation to equal approximately 5 FPU/dry g cellulose(low enzyme loading) or 15 FPU/dry g cellulose (high enzyme loading)and
    2. the appropriate volume of β-glucosidase enzyme to equal 20 CBU/dry g cellulose or 60 CBU/dry g cellulose.
    3. Xylase may be added at the same time (if desired).
  6. Prepare control blanks
    1. The substrate blank contains buffer, water, and the identical amount of substrate in 10.00 mL volume.
    2. Enzyme blanks for cellulase, β-glucosidase, and xylanase with buffer, water, and the identical amount of the enzyme.
  7. Close the tubes tightly and place them in a shaking incubator or fixed speed rotator that has been placed in the incubator at 50°C.
  8. Shake or rotate sufficiently enough to keep solids in constant suspension for a period of 72 to 168 hours or until the release of soluble sugars from the sample(s) becomes negligible when measured by YSI, as described in the next step.
  9. If the progress of the reaction is to be measured:
    1. A 0.3-0.5 mL aliquot is removed at each predetermined time interval after the tube contents have been well mixed by shaking.
      1. Use a 1-mL plastic syringe or 1ml pipette with tip cut off to draw a representative sample while constantly suspending the contents of the vial.
      2. This will allow solids, as well as liquid, to be withdrawn into the orifice.
    2. The sample is filtered through a 0.45 μm filter
  10. Analyze the glucose concentration using the YSI glucose analyzer or appropriate HPLC method.

Calculations

  1. To calculate the percent digestibility of the cellulose
    1. Determine glucose concentration in the centrifuged supernatant by YSI.
    2. Subtract the glucose concentrations, if any, from the substrates and enzyme blanks.
    3. Correct for hydration (multiply the glucose reading by 0.9 to correct for the water molecule added upon hydrolysis of the cellulose polymer)
    4. Multiply by 10mL total volume of assay.
    5. Example: If the glucose analyzer reading (corrected with blanks) is 9.9 mg/mL, then the amount of cellulose digested is:

0.0099 g/mL x 10 mL x 0.9 = 0.0891 g

  1. Calculate percent digestion:
    1. %digestion= 100 X (grams cellulose digested/grams cellulose added)

Notes

  • There is an Excel spreadsheet posted of Penn State Angel as a companion to this procedure (for Richard Lab students).
  • Terminology*
  1. Pretreated biomass: biomass that has been chemically or thermally altered, changing the structural composition
  2. Cellulase enzyme: an enzyme preparation exhibiting all three synergistic cellulolytic activities: endo-1,4-β-D-glucanase, exo-1,4-β-glucosidase, and β-D-glucosidase activities, which are present to different extents in different cellulose preparations.
  3. Batch: Any number of samples which are analyzed and recorded together.
  • If the biomass is suspected to have some starch content, dry weight percent cellulose calculated from total glucan must be corrected to subtract the starch contribution to total dry weight percent glucose.
  • All lignocellulosic materials which have undergone some aqueous pretreatment must never be air-dried prior to enzyme digestibility, since irreversible pore collapse can occur in the micro-structure of the biomass leading to decreased enzymatic release of glucose from the cellulose.
  • Cycloheximide, tetracycline and sodium azide are hazardous and must be handled with appropriate care.
  • If the rate of enzymatic release of glucose is to be measured, all contents of the tube prior to the addition of the enzyme must be at 50°C.
  • The enzymes are always added last since the reaction is initiated by the addition of enzyme.
  • The precision of this protocol is dependent upon cellulase source and substrate composition.
  • Different preparations of cellulase hydrolyze identical substrates to different extents, and different preparations of pretreated biomass exhibit different amounts of homogeneity.
  • Typically results are reported as percentages, calculated to two decimal places, along with the standard deviation and RPD. The assay conditions, specifically digestion time, must be defined when reporting the results.
  • It is recommended the samples be run in duplicate to verify reproducibility.
  • Enzyme and substrate blanks are run to correct for glucose contributions other than that produced by cellulose hydrolysis.
  • Relative percent difference criteria: Not defined; dependent on the substrate being tested. Different preparations of pretreated biomass will exhibit different amounts of homogeneity, which will influence the extent to which they are hydrolyzed.
  • Method verification standard: Solka Floc 200 NF is digested alongside the samples. Hydrolysis is expected to be in the range of 94.00 - 96.00%.
  • Calibration verification standard: None.
  • Sample size: Dependent upon percent dry weight cellulose composition. Typically between 0.10 and 1.00 grams of sample will be required.
  • Pretreated samples should be stored moist, or frozen not longer than one month.
  • The maximum size of a batch will be limited by equipment constraints. 14.12Control charts: Percent hydrolysis of Solka Floc 200 NF will be charted; use of different preparations of cellulase enzyme and total hydrolysis time will be noted.

References

  1. NREL Ethanol Project CAT Task Laboratory Analytical Procedure #009, “Enzymatic Saccharification of Lignocellulosic Biomass”, 8/19/96.
  2. Grohmann, K., Torget, R., and Himmel, M. (1986), Biotech. Bioeng. Symp. No. 17, 135-151.
  3. Ghose, T.K. (1987), Pure & Appl. Chem., 59, 257-268.
  4. Stockton, B.C., Mitchell, D.J., Grohmann, K., and Himmel, M.E. (1991), Biotech. Let., 13, 57-62.
  5. Adney, B. and Baker, J. (1993), Ethanol Project Laboratory Analytical Procedures, LAP006, National Renewable Energy Laboratory, Golden, CO, 80401.
  6. Ehrman, C. I. (1996), Ethnaol Project Laboratory Analytical Procedures, LAP-016, National Renewable Energy Laboratory, Golden, CO, 80401.

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