Cellulase

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Cellulase
260px
Model of cellulase enzyme, produced by T. fusca, based on PDB structure 1JS4
Identifiers
EC number 3.2.1.4
CAS number Template:CAS
Databases
IntEnz IntEnz view
BRENDA BRENDA entry
ExPASy NiceZyme view
KEGG KEGG entry
MetaCyc metabolic pathway
PRIAM profile
PDB structures RCSB PDB PDBe PDBsum
Gene Ontology AmiGO / EGO
File:1NLRribbon.png
Ribbon representation of the Streptomyces lividans beta-1,4-endoglucanase catalytic domain - an example from the family 12 glycoside hydrolases[1]

Cellulase is any of several enzymes produced chiefly by fungi, bacteria, and protozoans that catalyze cellulolysis, the decomposition of cellulose and of some related polysaccharides; specifically, the hydrolysis of the 1,4-beta-D-glycosidic linkages in cellulose, hemicellulose, lichenin, and cereal beta-D-glucans. Cellulases break down the cellulose molecule into monosaccharides ("simple sugars") such as beta-glucose, or shorter polysaccharides and oligosaccharides. The name is also used for any naturally occurring mixture or complex of various such enzymes, that act serially or synergistically to decompose cellulosic material.[2]

Most mammals have only very limited ability to digest dietary fibres such as cellulose, by themselves. Important example are, the cellulase produced mainly by symbiotic bacteria in ruminants like cattle and sheep and in hindgut fermenters like horses that allows them to digest the cellulose from their grass diet. Cellulases are also produced by a few other types of organisms, such as some termites.[3][4]

Several different kinds of cellulases are known, which differ structurally and mechanistically. Synonyms, derivatives, and specific enzymes associated with the name "cellulase" include endo-1,4-beta-D-glucanase (beta-1,4-glucanase, beta-1,4-endoglucan hydrolase, endoglucanase D, 1,4-(1,3,1,4)-beta-D-glucan 4-glucanohydrolase), carboxymethyl cellulase (CMCase), avicelase, celludextrinase, cellulase A, cellulosin AP, alkali cellulase, cellulase A 3, 9.5 cellulase, and pancellase SS. Enzymes that cleave lignin are occasionally called cellulases, but this is usually considered erroneous.

Types and action

Five general types of cellulases based on the type of reaction catalyzed:

Avicelase has almost exclusively exo-cellulase activity, since avicel is a highly micro-crystalline substrate.

Within the above types there are also progressive (also known as processive) and nonprogressive types. Progressive cellulase will continue to interact with a single polysaccharide strand, nonprogressive cellulase will interact once then disengage and engage another polysaccharide strand.

Cellulase action is considered to be synergistic as all three classes of cellulase can yield much more sugar than the addition of all three separately. Aside from ruminants, most animals (including humans) do not produce cellulase in their bodies and can only partially break down cellulose through fermentation, limiting their ability to use energy in fibrous plant material.

Structure

Most fungal cellulases have a two-domain structure, with one catalytic domain and one cellulose binding domain, that are connected by a flexible linker. This structure is adapted for working on an insoluble substrate, and it allows the enzyme to diffuse two-dimensionally on a surface in a caterpillar-like fashion. However, there are also cellulases (mostly endoglucanases) that lack cellulose binding domains. These enzymes might have a swelling function.

Cellulase complexes

In many bacteria, cellulases in-vivo are complex enzyme structures organized in supramolecular complexes, the cellulosomes. They contain roughly five different enzymatic subunits representing namely endocellulases, exocellulases, cellobiases, oxidative cellulases and cellulose phosphorylases wherein only endocellulases and cellobiases participate in the actual hydrolysis of the β(1→ 4) linkage.

The cellulase complex from Trichoderma reesei, for example, comprises a component labeled C1 (57,000 daltons) that separates the chains of crystalline cellulose, an endoglucanase (about 52,000 daltons), an exoglucanase (about 61,000 dalton), and a beta-glucosidase (76,000 daltons).[2]

Numerous "signature" sequences known as dockerins and cohesins have been identified in the genomes of bacteria that produce cellulosomes. Depending on their amino acid sequence and tertiary structures, cellulases are divided into clans and families.[6]

Mechanism of cellulolysis

File:Types of Cellulase2.png
The three types of reaction catalyzed by cellulases:1. Breakage of the noncovalent interactions present in the amorphous structure of cellulose (endocellulase) 2. Hydrolysis of chain ends to break the polymer into smaller sugars (exocellulase) 3. Hydrolysis of disaccharides and tetrasaccharides into glucose (beta-glucosidase).
File:Cellulase Mech.jpg
Mechanistic details of beta-glucosidase activity of cellulase

Uses

Cellulase is used for commercial food processing in coffee. It performs hydrolysis of cellulose during drying of beans. Furthermore, cellulases are widely used in textile industry and in laundry detergents. They have also been used in the pulp and paper industry for various purposes, and they are even used for pharmaceutical applications. Cellulase is used in the fermentation of biomass into biofuels, although this process is relatively experimental at present. Cellulase is used as a treatment for phytobezoars, a form of cellulose bezoar found in the human stomach.

Measurement of cellulase

As the native substrate, cellulose, is a water-insoluble polymer, traditional reducing sugar assays using this substrate can not be employed for the measurement of cellulase activity. Analytical scientists have developed a number of alternative methods.

Viscometric substrates

A viscometer can be used to measure the decrease in viscosity of a solution containing a water-soluble cellulose derivative such as carboxymethyl cellulose upon incubation with a cellulase sample.[7] The decrease in viscosity is directly proportional to the cellulase activity. While such assays are very sensitive and specific for endo-cellulase (exo-acting cellulase enzymes produce little or no change in viscosity), they are limited by the fact that it is hard to define activity in conventional enzyme units (micromoles of substrate hydrolyzed or product produced per minute).

Cellooligosaccharide substrates

The lower DP cello-oligosaccharides (DP2-6) are sufficiently soluble in water to act as viable substrates for cellulase enzymes.[8] However, as these substrates are themselves 'reducing sugars', they are not suitable for use in traditional reducing sugar assays because they generate a high 'blank' value. However their cellulase mediated hydrolysis can be monitored by HPLC or IC methods to gain valuable information on the substrate requirements of a particular cellulase enzyme.

Reduced cellooligosaccharide substrates

Cello-oligosaccharides can be chemically reduced through the action of sodium borohydride to produce their corresponding sugar alcohols. These compounds do not react in reducing sugar assays but their hydrolysis products do. This makes borohydride reduced cello-oligosaccharides valuable substrates for the assay of cellulase using traditional reducing sugar assays such as the Nelson-Symogyi method.[9][10]

Dyed polysaccharide substrates[11]

These substrates can be subdivided into two classes-

  • Insoluble chromogenic substrates: An insoluble cellulase substrate such as AZCL-HE-cellulose absorbs water to create gelatinous particles when placed in solution. This substrate is gradually depolymerised and solubilised by the action of cellulase. The reaction is terminated by adding an alkaline solution to stop enzyme activity and the reaction slurry is filtered or centrifuged. The colour in the filtrate or supernatant is measured and can be related to enzyme activity.
  • Soluble chromogenic substrates: A cellulase sample is incubated with a water-soluble substrate such as azo-CM-cellulose, the reaction is terminated and high molecular weight, partially hydrolysed fragments are precipitated from solution with an organic solvent such as ethanol or methoxyethanol. The suspension is mixed thoroughly, centrifuged, and the colour in the supernatant solution (due to small, soluble, dyed fragments) is measured. With the aid of a standard curve, the enzyme activity can be determined.

Enzyme coupled reagents

File:Use of enzyme coupled reagents for the measurement of endo-cellulase.svg
Colourimetric and fluorimetric cellulase substrates can be used in the presence of ancillary β-glucosidase for the specific measurement of endo-cellulase activity

Recently, new reagents have been developed that allow for the specific measurement of endo-cellulase.[12][13] These methods involve the use of functionalised oligosaccharide substrates in the presence of an ancillary enzyme. In the example shown, a cellulase enzyme is able to recognise the trisaccharide fragment of cellulose and cleave this unit. The ancillary enzyme present in the reagent mixture (β-glucosidase) then acts to hydrolyse the fragment containing the chromophore or fluorophore. The assay is terminated by the addition of a basic solution that stops the enzymatic reaction and deprotonates the liberated phenolic compound to produce the phenolate species. The cellulase activity of a given sample is directly proportional to the quantity of phenolate liberated which can be measured using a spectrophotometer. The acetal functionalisation on the non-reducing end of the trisaccharide substrate prevents the action of the ancillary β-glucosidase on the parent substrate.

References

  1. PDB: 1NLR​; Lua error in package.lua at line 80: module 'strict' not found.; rendered with PyMOL
  2. 2.0 2.1 Worthington Biochemical Corporation (2014), Cellulase. Accessed on 2014-07-03
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[1]

Further reading

  • Lua error in package.lua at line 80: module 'strict' not found.
  • The Merck Manual of Diagnosis and Therapy, Chapter 24
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See also

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