Mechanisms and Experimental Applications of Cell Wall Polysaccharide-Degrading Enzymes: Plant Cell Walls, Fungal Cell Walls, and Bacterial Peptidoglycan Systems
Mechanisms and Experimental Applications of Cell Wall Polysaccharide-Degrading Enzymes: Plant Cell Walls, Fungal Cell Walls, and Bacterial Peptidoglycan Systems
Cell wall polysaccharide-degrading enzymes are mainly used to lyse plant cell walls, fungal cell walls, bacterial peptidoglycan, and microbial extracellular polysaccharide matrices. Common enzyme types include cellulase, pectinase, xylanase, chitinase, β-glucanase, lysozyme, and various debranching enzymes.
Keywords: cell wall polysaccharide-degrading enzymes; plant cell wall; microbial cell wall; cellulase; pectinase; xylanase; hemicellulase; β-glucanase; chitinase; lysozyme; peptidoglycan hydrolase
1 Research Positioning of Cell Wall Polysaccharide-Degrading Enzymes
1.1 Plant Cell Wall Polysaccharide Substrates
(1) Cellulose
Cellulose is composed of β-1,4-glucose chains and is the main structural polysaccharide of plant cell walls. Its crystalline regions are structurally stable, and a single endoglucanase usually cannot achieve complete hydrolysis. Synergistic action among endoglucanases, exocellobiohydrolases, and β-glucosidases is required. Cellulose degradation experiments are commonly used for lignocellulose saccharification, plant tissue digestion, cell wall structural analysis, and optimization of protoplast preparation conditions.
(2) Hemicellulose
Hemicellulose includes xylan, arabinoxylan, mannan, glucomannan, and xyloglucan. Its main-chain and side-chain structures vary considerably, so multiple enzymes such as xylanase, β-xylosidase, arabinofuranosidase, acetylxylan esterase, and mannanase are usually required for complete degradation. Hemicellulose degradation not only releases products such as xylose, but also improves the accessibility of cellulases to the cell wall framework.
(3) Pectin
Pectin is rich in galacturonic acid residues and is mainly distributed in the primary cell wall and middle lamella. It participates in intercellular adhesion, tissue firmness, and regulation of cell wall porosity. Pectin degradation often involves polygalacturonase, pectin lyase, pectate lyase, and pectin methylesterase. In plant tissue dissociation, fruit softening, juice clarification, and protoplast preparation, the pectinase system is usually a key variable.
(4) Lignocellulosic Composite Structures
In plant secondary walls, cellulose, hemicellulose, and lignin are highly interwoven. Lignin is not a polysaccharide, but it significantly restricts polysaccharide-degrading enzymes from entering the substrate interior. Lignocellulose degradation research often needs to combine pretreatment, hemicellulose debranching, cellulase formulation, and oxidative auxiliary enzymes to improve the hydrolysis efficiency of polysaccharide chains.
1.2 Microbial Cell Wall Polysaccharide Substrates
(1) Fungal Cell Wall
The fungal cell wall is mainly composed of chitin, β-glucan, mannan, and glycoproteins. Chitinases cleave β-1,4-N-acetylglucosamine chains, β-1,3-glucanases act on the glucan backbone, and mannanases participate in mannan hydrolysis. Fungal cell wall degradation is commonly used for mycelial lysis, yeast protoplast preparation, antifungal mechanism research, and cell wall remodeling analysis.
(2) Bacterial Cell Wall
The core structure of the bacterial cell wall is peptidoglycan. Its glycan chains are composed of alternating N-acetylglucosamine and N-acetylmuramic acid residues and are cross-linked by short peptides to form a network structure. Lysozyme mainly cleaves β-1,4-glycosidic bonds in the peptidoglycan glycan chain, while other peptidoglycan hydrolases may act on amide bonds or peptide bridges. Bacterial lysis experiments should consider differences between Gram-positive and Gram-negative bacteria in outer membrane structure, peptidoglycan thickness, and cross-linking degree.
(3) Extracellular Polysaccharides and Biofilm Matrix
Many bacteria and fungi secrete extracellular polysaccharides to form biofilm matrices, such as glucans, alginates, dextran, cellulose-like polysaccharides, and heteropolysaccharides. Extracellular polysaccharide-degrading enzymes can disrupt biofilm spatial structure and improve antimicrobial penetration. They can also be used for extracellular polysaccharide structural analysis. These experiments should distinguish among cell wall lysis, extracellular matrix degradation, and cell death.
Table 1 Cell Wall Polysaccharide Substrates and Representative Degrading Enzymes
Substrate type | Main structural features | Representative degrading enzymes | Typical experimental applications |
Cellulose | β-1,4-glucose chains, partially crystalline | Cellulase, β-glucosidase | Lignocellulose saccharification, plant tissue digestion |
Xylan | Hemicellulose main chain, often with arabinose or acetyl side chains | Xylanase, β-xylosidase, debranching enzymes | Hemicellulose degradation, enzymatic sugar profile analysis |
Pectin | Galacturonic acid backbone with variable methyl esterification | Pectinase, pectin lyase, pectin methylesterase | Tissue softening, protoplast preparation, pectin structural analysis |
Chitin | β-1,4-N-acetylglucosamine chains | Chitinase, N-acetylglucosaminidase | Fungal cell wall lysis, antifungal research |
β-Glucan | β-1,3 or β-1,6 glucan structures | β-Glucanase | Fungal cell wall degradation, yeast lysis |
Peptidoglycan | Network structure of glycan chains and peptide bridges | Lysozyme, peptidoglycan hydrolases | Bacterial lysis, cell wall structural research |
Extracellular polysaccharides | Complex composition, often forming biofilm matrix | Dextranase, alginate lyase, glucanase | Biofilm matrix degradation, extracellular polysaccharide analysis |
2 Mechanisms of Polysaccharide-Degrading Enzymes
2.1 Glycoside Hydrolase Mechanisms
(1) Endo-Hydrolysis
Endo-acting enzymes randomly cleave glycosidic bonds within polysaccharide chains, rapidly fragmenting long-chain polysaccharides. This is reflected by decreased substrate viscosity, increased soluble oligosaccharides, and reducing sugar release. Endoglucanases, endoxylanases, and some β-glucanases belong to this category. Endo-enzymes are more sensitive to structurally loose regions but have limited ability to hydrolyze highly crystalline or cross-linked regions.
(2) Exo-Hydrolysis
Exo-acting enzymes gradually release disaccharides or monosaccharides from the non-reducing or reducing ends of polysaccharide chains. Cellobiohydrolases, β-glucosidases, and β-xylosidases commonly participate in exo- or terminal hydrolysis. During cellulose saccharification, insufficient β-glucosidase causes cellobiose accumulation, which inhibits upstream cellulases and reduces overall saccharification efficiency.
(3) Enzyme System Synergy
Natural cell walls usually cannot be fully degraded by a single enzyme. Cellulase systems require synergy among endo-, exo-, and terminal hydrolases. Hemicellulose degradation requires cooperation between main-chain hydrolases and debranching enzymes. Fungal cell wall lysis often requires chitinase, β-glucanase, and mannanase together. Composite enzyme systems are closer to actual degradation processes, but mechanism interpretation requires single-enzyme and combination controls.
2.2 Lyases, Esterases, and Debranching Enzymes
(1) Polysaccharide Lyases
Polysaccharide lyases usually cleave uronic acid-containing polysaccharides through mechanisms such as β-elimination rather than conventional hydrolysis. Pectin lyase, pectate lyase, and alginate lyase are common examples and often generate unsaturated oligosaccharides. These enzymes are suitable for pectin structural analysis, alginate degradation, and extracellular polysaccharide matrix disruption research.
(2) Carbohydrate Esterases
Plant cell wall polysaccharides often contain methyl esterification, acetylation, or feruloylation modifications. Pectin methylesterase, acetylxylan esterase, and feruloyl esterase can remove substituent groups and improve substrate accessibility for main-chain hydrolases. For natural plant cell wall samples, adding only main-chain hydrolases often fails to release structural sugars sufficiently.
(3) Debranching Enzymes
Arabinofuranosidase, galactosidase, rhamnosidase, and similar enzymes remove polysaccharide side chains, exposing the main chain and improving subsequent hydrolysis efficiency. Debranching reactions may not significantly increase total reducing sugar readings, but they change oligosaccharide composition, branching ratio, and the depth of main-chain degradation.
2.3 Oxidative Auxiliary Mechanisms
(1) LPMO Activity
Lytic polysaccharide monooxygenases (LPMOs) can act on crystalline cellulose and chitin through oxidative mechanisms, increasing polysaccharide chain cleavage sites and improving the subsequent efficiency of glycoside hydrolases. LPMO reactions depend on metal centers, electron donors, and redox conditions. Experiments should control reductants, oxygen, and peroxide levels to avoid nonspecific oxidative damage.
(2) Removal of the Lignin Barrier
Laccases and peroxidases mainly act on lignin or phenolic structures and are not polysaccharide hydrolases. However, they can improve polysaccharide accessibility by reducing the lignin barrier. In lignocellulosic systems, “lignin modification” and “polysaccharide chain hydrolysis” should be interpreted separately.
(3) Pretreatment Synergy
Acid, alkali, steam explosion, ionic liquids, and mechanical milling can disrupt compact cell wall structures and increase the probability of enzyme-substrate contact. Stronger pretreatment usually increases enzymatic hydrolysis efficiency, but it may also generate inhibitors or alter native structures. Therefore, conditions should be selected according to whether the purpose is mechanism research or applied saccharification.
Table 2 Modes of Action of Cell Wall Polysaccharide-Degrading Enzymes and Experimental Readouts
Mode of action | Representative enzymes | Main result | Recommended readouts |
Endo-hydrolysis | Endoglucanase, endoxylanase, β-glucanase | Polysaccharide chain cleavage, viscosity reduction | Reducing sugars, viscosity, oligosaccharide profile |
Exo-hydrolysis | Exocellulase, β-glucosidase, β-xylosidase | Release of disaccharides or monosaccharides | Glucose, xylose, cellobiose |
Lyase reaction | Pectin lyase, alginate lyase | Formation of unsaturated oligosaccharides | Absorbance at 235 nm, oligosaccharide structural analysis |
De-esterification | Pectin methylesterase, acetylxylan esterase | Removal of methyl or acetyl groups | Methanol release, acetic acid release, degree of esterification |
Debranching | Arabinofuranosidase, galactosidase | Side-chain removal and improved main-chain accessibility | Monosaccharide composition, oligosaccharide profile |
Oxidative assistance | LPMO | Increased cleavage sites in crystalline polysaccharides | Oxidized oligosaccharides, saccharification efficiency, LC-MS |
3 Experimental Application Scenarios
3.1 Plant Cell Wall Research
(1) Cell Wall Component Analysis
Plant cell wall polysaccharide composition can be verified through sequential extraction, monosaccharide composition analysis, and specific enzymatic hydrolysis. Cellulase, xylanase, pectinase, and mannanase can be used to determine the presence and structural accessibility of different polysaccharide components. If the contributions of cellulose, hemicellulose, and pectin need to be distinguished, broad-spectrum crude enzyme preparations should not be used as the only evidence.
(2) Protoplast Preparation
Plant protoplast preparation usually requires a combination of cellulase and pectinase. Cellulase weakens the cell wall framework, while pectinase disrupts the middle lamella and intercellular adhesion. Different plant tissues vary greatly in lignification degree, pectin content, and cell wall thickness. Enzyme concentration, osmotic pressure, pH, digestion time, and tissue cutting method all need optimization.
(3) Lignocellulose Saccharification
Saccharification of straw, wood powder, herbaceous plants, and agricultural by-products usually relies on synergy among cellulases, hemicellulases, and auxiliary enzymes. Evaluation indicators should not be limited to total reducing sugars; glucose, xylose, arabinose, and oligosaccharide composition should also be analyzed to determine hydrolysis depth.
3.2 Microbial Cell Wall and Biofilm Research
(1) Fungal Cell Wall Lysis
Fungal cell wall lysis commonly uses chitinase, β-glucanase, mannanase, or composite lytic enzymes. Yeasts and filamentous fungi differ in cell wall composition, and enzymatic lysis conditions also vary. If the goal is nucleic acid or protein extraction, lysis efficiency, target molecule integrity, and protease contamination risk should all be considered.
(2) Bacterial Cell Wall Degradation
Gram-positive bacteria have a thick peptidoglycan layer, so lysozyme is usually more effective. In Gram-negative bacteria, the outer membrane restricts lysozyme access to the peptidoglycan layer, so EDTA, surfactants, heat treatment, or mechanical disruption is often needed. If the research focuses on antimicrobial mechanisms, peptidoglycan hydrolysis, membrane permeability changes, and cell death must be distinguished.
(3) Biofilm Extracellular Matrix Degradation
Biofilm degradation experiments often focus on whether the extracellular polysaccharide matrix is disrupted. Dextranase, alginate lyase, glucanase, or DNase can act on different matrix components. A decrease in biofilm biomass does not directly prove cell death. Viable cell counts, extracellular polysaccharide content, and microscopic imaging should be interpreted together.
3.3 Industrial and Applied Research
(1) Food Processing
Pectinase, cellulase, and hemicellulase can be used for juice clarification, plant tissue softening, extraction efficiency improvement, and viscosity control. In food systems, attention should be paid to enzyme source, optimal pH, optimal temperature, flavor effects, and residual enzyme activity control.
(2) Biomass Conversion
Lignocellulosic biorefining requires converting complex cell wall polysaccharides into fermentable sugars. Enzyme system design should consider cellulose crystallinity, hemicellulose side chains, lignin barriers, and product inhibition. Simply increasing the dosage of one cellulase usually cannot resolve all limitations of complex substrates.
(3) Antibacterial and Antifungal Research
Lysozyme, chitinase, and β-glucanase can be used for cell wall-targeted antibacterial or antifungal research. These experiments should simultaneously assess cell wall integrity, cell membrane permeability, viability, and morphological changes to avoid directly equating structural damage with bactericidal or fungicidal effects.
Table 3 Applications of Cell Wall Polysaccharide-Degrading Enzymes in Different Experimental Systems
Application direction | Common enzymes | Recommended samples or substrates | Core readouts |
Plant protoplast preparation | Cellulase, pectinase, hemicellulase | Leaves, roots, callus tissue | Protoplast yield, viability, integrity |
Lignocellulose saccharification | Cellulase, xylanase, β-glucosidase, LPMO | Straw, wood powder, pretreated biomass | Reducing sugars, glucose, xylose, saccharification rate |
Pectin structural analysis | Pectinase, pectin lyase, pectin methylesterase | Pectin, plant middle lamella | Galacturonic acid, degree of methyl esterification, oligosaccharide profile |
Fungal cell wall lysis | Chitinase, β-glucanase, mannanase | Yeast, filamentous fungal mycelia | Lysis rate, protoplast formation, residual cell wall |
Bacterial lysis | Lysozyme, peptidoglycan hydrolases | Gram-positive bacteria, pretreated Gram-negative bacteria | OD reduction, viable count, cell wall integrity |
Biofilm matrix degradation | Glucanase, alginate lyase, dextranase | Bacterial or fungal biofilms | Biofilm biomass, EPS content, microscopic imaging |
4 Experimental Design and Result Interpretation
4.1 Substrate Selection and Pretreatment
(1) Purified Substrates
Carboxymethyl cellulose, microcrystalline cellulose, xylan, pectin, chitin, β-glucan, and peptidoglycan can be used for single-enzyme activity assays. Purified substrates are useful for assessing basic catalytic ability, but they cannot fully represent native cell wall structures.
(2) Natural Substrates
Plant cell walls, fungal mycelia, bacterial cell walls, and biofilm matrices are closer to actual application scenarios but have complex compositions. In natural substrate experiments, enzymatic hydrolysis results are strongly affected by substrate particle size, pretreatment degree, cross-linking strength, sample water content, and inhibitors.
(3) Pretreatment Conditions
Mechanical grinding, freeze-thawing, heat treatment, alkaline treatment, or chelator treatment can improve substrate accessibility. If the research goal is enzymatic hydrolysis in native structures, excessive pretreatment should be avoided. If the goal is maximal saccharification efficiency, stronger pretreatment can be used, but the conditions must be fully recorded.
4.2 Enzyme Combinations and Control Systems
(1) Single Enzymes and Composite Enzymes
Single-enzyme experiments are suitable for determining substrate specificity and catalytic mechanism, whereas composite enzyme experiments are more suitable for simulating actual degradation processes. Plant and fungal cell walls usually require composite enzyme systems. A single-enzyme reaction often reveals only part of the structural contribution.
(2) Negative Controls
No-enzyme controls, heat-inactivated enzyme controls, and substrate blanks should be included. For reducing sugar detection, it is necessary to confirm whether the substrate itself releases background sugars. For cell lysis experiments, nonspecific lysis caused by mechanical damage, osmotic pressure changes, or surfactants must be excluded.
(3) Positive Controls
Positive controls may use known substrates and standard enzyme systems, such as cellulase acting on carboxymethyl cellulose, chitinase acting on colloidal chitin, and lysozyme acting on sensitive Gram-positive bacteria. Positive controls validate the detection system but should not replace mechanism interpretation for the experimental sample itself.
4.3 Detection Methods and Result Interpretation
(1) Reducing Sugar Detection
DNS, PAHBAH, and Nelson-Somogyi methods can be used for total reducing sugar detection and are suitable for rapid comparison of enzymatic hydrolysis intensity. However, reducing sugar assays cannot distinguish whether the signal comes from glucose, xylose, galacturonic acid, or oligosaccharides, so they should not be used alone for structural analysis.
(2) Monosaccharide and Oligosaccharide Analysis
HPLC, HPAEC-PAD, GC-MS, and LC-MS can be used to analyze monosaccharide composition, oligosaccharide chain length, and specific cleavage products. If the research focuses on enzyme cleavage sites, debranching effects, or cleavage mechanisms, glycan profiling methods should be prioritized.
(3) Morphological and Structural Observation
Light microscopy, scanning electron microscopy, fluorescence staining, and immunolabeling can be used to observe cell wall structural changes. In studies of plant protoplasts, fungal mycelial lysis, and bacterial cell wall disruption, morphological evidence helps distinguish partial degradation, structural loosening, and complete lysis.
Table 4 Common Readouts in Polysaccharide Degradation Experiments and Their Applicability
Detection readout | Applicable question | Advantage | Limitation |
Total reducing sugars | Whether overall hydrolysis occurs | Simple operation, suitable for initial screening | Cannot distinguish sugar source or product structure |
Monosaccharide composition | Which polysaccharides the hydrolysis products originate from | Distinguishes glucose, xylose, arabinose, etc. | Requires more demanding pretreatment and instruments |
Oligosaccharide profile | Cleavage sites and degradation depth | Suitable for mechanism analysis | Data interpretation is more complex |
Viscosity change | Whether endo-enzymes act on long-chain polysaccharides | Sensitive to endo-action | Does not represent complete hydrolysis |
OD reduction | Degree of microbial lysis | Rapid evaluation of cell lysis | Easily affected by aggregation and sedimentation |
Microscopic imaging | Whether cell wall structure is disrupted | Shows morphological changes | Limited quantitative capability |
Biofilm staining | EPS or biofilm biomass change | Suitable for screening matrix degradation effects | Cannot directly distinguish killing from matrix removal |
5 Enzyme and Detection Products Related to Cell Wall Polysaccharide Degradation Experiments
Table 5 Enzyme Products Related to Cell Wall Polysaccharide Degradation Experiments
Cat. No. | Product Name | Grade/Specification | Product Category | Application Positioning |
Cellulase | Native,EnzymoPure™,≥ 4500 CNU-R/g | Cellulose-degrading enzyme | Used for plant cell wall cellulose hydrolysis, tissue digestion, and lignocellulose saccharification | |
Cellulase from Aspergillus sp. | ActiBioPure™, Bioactive, High Performance, EnzymoPure™, ≥1000 U/g liquid | Cellulose-degrading enzyme | Used for plant cell wall degradation, cellulase hydrolysis, and optimization of protoplast preparation conditions | |
Cellulase from Trichoderma sp. | powder,≥5,000 units/g solid | Cellulose-degrading enzyme | Used for Trichoderma-derived cellulase systems, cellulose hydrolysis, and saccharification experiments | |
Cellulase from Trichoderma reesei | EnzymoPure™, ≥100,000 U/g powder | High-activity cellulose-degrading enzyme | Used for lignocellulose saccharification, plant cell wall degradation, and high-activity enzyme systems | |
Cellulase from Trichoderma reesei | aqueous solution,≥700 units/g | Cellulose-degrading enzyme | Used as a liquid enzyme preparation for cellulose hydrolysis and plant tissue digestion | |
Cellulase from Trichoderma reesei | Bioactive,ActiBioPure™,High Performance,EnzymoPure™,≥700 EGU/g | Cellulose-degrading enzyme | Used for endo-cellulose hydrolysis, cell wall loosening, and biomass enzymatic hydrolysis | |
Cellulase from Trichoderma reesei ATCC 26921 | lyophilized powder,≥1 unit/mg solid | Cellulose-degrading enzyme | Used for cellulase activity evaluation and cell wall cellulose degradation | |
Cellulase from Trichoderma reesei ATCC 26921 | EnzymoPure™, ≥25 units/mg dry weight | Cellulose-degrading enzyme | Used for plant cell wall cellulose degradation and enzyme preparation comparison | |
Cellulase from Trichoderma reesei ATCC 26921 | EnzymoPure™, ≥45 units/mg dry weight | Cellulose-degrading enzyme | Used for higher-activity cellulose degradation systems and saccharification experiments | |
Cellulase from Aspergillus niger(Carrier for starch) | Bioactive,ActiBioPure™,High Performance,EnzymoPure™,≥10,000U/g enzyme powder | Cellulose-degrading enzyme | Used for Aspergillus niger-derived cellulose degradation and plant cell wall enzymatic hydrolysis | |
Cellulase, enzyme blend | Bioactive,ActiBioPure™,High Performance,EnzymoPure™,>1000 BHU/g | Composite cellulase system | Used for composite enzymatic hydrolysis of plant cell walls and applied saccharification experiments | |
Cellulase(Carrier for starch) | EnzymoPure™, from Trichoderma viride,≥20,000U/g,powder | Cellulose-degrading enzyme | Used for Trichoderma viride-derived cellulose hydrolysis and biomass degradation | |
β-Glucosidase | Bioactive, ActiBioPure™, Native, High Performance, EnzymoPure™, ≥10U/mg powder; 10-60 U/mg protein | Cellulose saccharification auxiliary enzyme | Used for converting cellobiose to glucose and reducing cellulase product inhibition | |
β-Glucosidase | Bioactive, ActiBioPure™, Native, High Performance, EnzymoPure™, ≥4 U/mg powder | Cellulose saccharification auxiliary enzyme | Used for terminal hydrolysis in cellulose degradation and improving saccharification efficiency | |
Beta-glucanase | EnzymoPure™, ≥100 FBG/g | β-Glucan-degrading enzyme | Used for β-1,3/1,4-glucan hydrolysis and fungal/plant glucan structural research | |
β-(1→3)-D-Glucanase | Bioactive,ActiBioPure™,Native,High Performance,EnzymoPure™,from Helix pomatia; ≥0.2 U/mg enzyme powder | Fungal cell wall glucan-degrading enzyme | Used for degradation of yeast and fungal cell wall β-1,3-glucan backbones | |
β-1,3-1,4-Glucanase |
| β-Glucan-degrading enzyme | Used for mixed-linkage β-glucan hydrolysis and plant cell wall or microbial glucan research | |
β-Glucanase from Trichoderma sp. | technical grade, ≥50 U/mg powder | β-Glucan-degrading enzyme | Used for Trichoderma-derived β-glucan degradation and applied enzymatic hydrolysis systems | |
β-Glucanase from Aspergillus niger | powder, dark brown, ~1 U/mg | β-Glucan-degrading enzyme | Used for Aspergillus niger-derived β-glucan hydrolysis and cell wall glucan analysis | |
Dextranase | Bioactive,ActiBioPure™,High Performance,EnzymoPure™,from Chaetomium gracile; ≥400U/mg enzyme powder | Glucan-degrading enzyme | Used for glucan substrate hydrolysis, fungal cell wall degradation, and extracellular polysaccharide degradation | |
Dextranase | EnzymoPure™,Derived from Penicillium genus, lyophilized powder, 10-25 units/mg solid | Glucan-degrading enzyme | Used for Penicillium-derived glucan hydrolysis and polysaccharide structural analysis | |
Dextranase from Chaetomium erraticum | EnzymoPure™, ≥100 KDU-A/g | Glucan-degrading enzyme | Used for glucan degradation, biofilm polysaccharide degradation, and fungal cell wall-related experiments | |
Hemicellulase | Bioactive,ActiBioPure™,High Performance,EnzymoPure™,from Aspergillus niger; ≥400 HCU/mg enzyme powder | Composite hemicellulose-degrading enzyme | Used for hemicellulose hydrolysis, plant cell wall loosening, and lignocellulose saccharification | |
Hemicellulase from gastritis | EnzymoPure™, ≥200 unit/mg solid | Composite hemicellulose-degrading enzyme | Used for hemicellulose degradation and composite polysaccharide hydrolysis of plant cell walls | |
Hemicellulase from Aspergillus niger | Bioactive,ActiBioPure™,High Performance,EnzymoPure™,≥50 U/mg enzyme powder | Composite hemicellulose-degrading enzyme | Used for Aspergillus niger-derived hemicellulose hydrolysis and saccharification assistance | |
Xylanase | EnzymoPure™, >100000 U/g | Xylan main-chain degrading enzyme | Used for xylan hydrolysis, hemicellulose degradation, and xylose release analysis | |
Xylanase | Recombinant, powder,≥2500 units/g, recombinant, expressed in <I>Aspergillus oryzae</I> | Recombinant xylanase | Used for recombinant xylanase activity evaluation and hemicellulose degradation experiments | |
Xylanase from Pichia pastoris | technical grade, ≥100 U/mg powder | Xylan main-chain degrading enzyme | Used for Pichia pastoris-derived xylanase and industrial hemicellulose hydrolysis | |
Xylanase from Trichoderma viride | lyophilized powder, 100-300 units/mg protein | Xylan main-chain degrading enzyme | Used for Trichoderma viride-derived xylan hydrolysis and plant cell wall hemicellulose degradation | |
Xylanase recombinant | EnzymoPure™, ≥2500 units/g expressed in Aspergillus oryzae | Recombinant xylanase | Used for recombinant xylanase activity validation and xylan degradation mechanism research | |
Exo-1,4-β-xylosidase |
| Hemicellulose terminal hydrolase | Used for conversion of xylo-oligosaccharides to xylose and analysis of xylan degradation depth | |
Gourmet oligosaccharide | EnzymoPure™, Enzyme activity 50000u/g | Mannan-degrading enzyme | Used for hydrolysis of mannan, glucomannan, and some fungal cell wall mannans | |
Pectinase from Aspergillus | ≥0.3 U/mg | Pectin-degrading enzyme | Used for pectin hydrolysis, plant middle lamella degradation, and tissue softening | |
Pectinase from Rhizopus sp. | powder, 400-800 units/g solid | Pectin-degrading enzyme | Used for Rhizopus-derived pectin degradation and plant cell separation | |
Pectinase from Aspergillus aculeatus | EnzymoPure™, aqueous solution,≥3,800 units/mL | Pectin-degrading enzyme | Used in liquid pectinase systems, plant tissue digestion, and middle lamella degradation | |
Pectinase from Aspergillus niger | BioReagent, suitable for plant cell culture, EnzymoPure™, 40% glycerol solution,≥5 units/mg protein (Lowry) | Pectinase for plant cell culture | Used for plant protoplast preparation, cell separation, and tissue digestion | |
Pectinase from Aspergillus niger | EnzymoPure™, ≥20 units/mg dry weight | Pectin-degrading enzyme | Used for pectin hydrolysis and plant tissue softening experiments | |
Pectinase from Aspergillus niger | EnzymoPure™, Native,≥30 000 U/g | High-activity pectin-degrading enzyme | Used for efficient pectin degradation, protoplast preparation, and plant cell wall loosening | |
Pectolyase Y-23, A. japonicus |
| Pectin-degrading enzyme | Used for pectin hydrolysis and degradation of plant cell wall pectin components | |
Pectolyase from Aspergillus japonicus | lyophilized powder,≥0.3 units/mg solid | Pectin-degrading enzyme | Used for middle lamella pectin degradation, tissue dispersion, and pectin structural analysis | |
Pectinase | EnzymoPure™, ≥3300 PGNU/g | Pectin main-chain hydrolase | Used for polygalacturonic acid hydrolysis, pectin main-chain degradation, and pectin structural research | |
Chitinase | Bioactive,ActiBioPure™,High Performance,Food Grade,EnzymoPure™,from Aspergillus niger; ≥100 U/g enzyme powder | Fungal cell wall chitin-degrading enzyme | Used for chitin hydrolysis, fungal cell wall lysis, and chitin degradation research | |
Chitinase | Bioactive,ActiBioPure™,Native,High Performance,EnzymoPure™,from Trichoderma harzianum; ≥100 U/ml; ≥400 U/mg protein | Fungal cell wall chitin-degrading enzyme | Used for high-activity chitin degradation, fungal cell wall lysis, and antifungal mechanism research | |
Chitinase, Streptomyces griseus |
| Chitin-degrading enzyme | Used for Streptomyces-derived chitin hydrolysis and fungal cell wall model degradation | |
Chitinase, Serratia marcescens |
| Chitin-degrading enzyme | Used for bacterial-derived chitinase activity and chitin degradation mechanism research | |
Chitinase from Streptomyces griseus | lyophilized powder (essentially salt free),≥200 units/g solid | Chitin-degrading enzyme | Used for chitin hydrolysis and fungal cell wall degradation under low-salt conditions | |
β-N-Acetylglucosaminidase from Canavalia ensiformis (Jack bean) | EnzymoPure™,ActiBioPure™,Bioactive,High Performance,Native,ammonium sulfate suspension, ≥10 U/mg protein; Protein content: 1-5 mg/ml | Chitin terminal hydrolysis auxiliary enzyme | Used for terminal product release in chitin degradation and hydrolysis of N-acetylglucosaminide bonds | |
N-Acetyl-β-D-Glucosaminidase Control (NAG Control) | from beef kidney | NAG reference standard | Used for quality control of NAG activity assay systems and validation of terminal hydrolysis in chitin degradation | |
T4 Lysozyme | Bioactive,Recombinant,ActiBioPure™,High Performance,EnzymoPure™,≥95%(SDS-PAGE),1 mg/ml | Peptidoglycan hydrolase | Used for bacterial peptidoglycan lysis, cell wall structural research, and recombinant lysozyme controls | |
Lysozyme Chloride | From protein | Lysozyme preparation | Used for bacterial cell wall lysis and peptidoglycan degradation experiments | |
Lysozyme from Human Neutrophil | Bioactive,ActiBioPure™,Native,High Performance,EnzymoPure™,≥95%(SDS-PAGE),>30,000 sugar U/mg protein; Pre-lyophilization Protein Concentration: See COA | Human-derived lysozyme | Used for human antimicrobial enzyme research, peptidoglycan hydrolysis, and bacterial cell wall lysis | |
Lysozyme,from egg white | Bioactive,ActiBioPure™,Native,High Performance,EnzymoPure™,≥20000U/mg enzyme powder | Classical lysozyme | Used for Gram-positive bacterial lysis, peptidoglycan hydrolysis, and nucleic acid/protein extraction pretreatment | |
Lysozyme from chicken egg white | EnzymoPure™,Native,≥5,000 units/mg dry weight | Classical lysozyme | Used for routine bacterial cell wall lysis and peptidoglycan degradation experiments | |
Lysozyme from chicken egg white(Purified,Salt Free) | EnzymoPure™,Native,≥8,000 units/mg dry weight | Purified lysozyme | Used for bacterial lysis and cell wall degradation systems sensitive to salt background | |
Lysozyme Solution (10 mg/mL) | BioReagent,Suitable for molecular biology,10 mg/mL | Lysozyme solution | Used for molecular biology sample pretreatment, bacterial lysis, and nucleic acid extraction | |
Lysozyme Solution (50 mg/mL) | BioReagent,Suitable for molecular biology,50 mg/mL | High-concentration lysozyme solution | Used for high-concentration bacterial lysis systems and sample pretreatment | |
Lysozyme, Egg White | Ultra pure, EnzymoPure™ | High-purity lysozyme | Used for high-purity peptidoglycan hydrolysis, methodological controls, and bacterial lysis | |
Laccase | Bioactive,ActiBioPure™,High Performance,EnzymoPure™,≥1 U/mg Liquid; from Aspergillus sp. | Lignin barrier-modifying enzyme | Used for lignin-related structural modification and improving plant cell wall polysaccharide accessibility | |
Laccase | EnzymoPure™,≥1 U/mg; from Aspergillus sp. | Lignin barrier-modifying enzyme | Used for lignin oxidative modification and lignocellulose pretreatment mechanism research | |
Laccase | Native,EnzymoPure™,≥1000 LAMU/g; from Aspergillus sp. | Lignin barrier-modifying enzyme | Used for high-activity laccase treatment, lignin barrier weakening, and biomass enzymatic hydrolysis assistance | |
Laccase from Trametes versicolor | Bioactive,ActiBioPure™,Native,High Performance,EnzymoPure™,from Trametes versicolor; ≥0.5 U/mg enzyme powder | Lignin barrier-modifying enzyme | Used for Trametes versicolor-derived laccase oxidation modification and lignocellulose degradation assistance | |
Peroxidase, Lignin |
| Lignin oxidase | Used for lignin barrier treatment, lignocellulose pretreatment, and improvement of polysaccharide accessibility |
Table 6 Products for Cell Wall Polysaccharide-Degrading Enzyme Activity and Product Detection
Cat. No. | Product Name | Grade/Specification | Product Category | Application Positioning |
Cellulase (CL) Activity Assay Kit (DNS, Micro Method) | BioReagent | Cellulase activity detection | Used for measuring cellulase activity in micro systems and screening enzyme preparation conditions | |
Cellulase (CL) Activity Assay Kit (DNS, Colorimetric Method) | BioReagent | Cellulase activity detection | Used for colorimetric measurement of cellulase activity and evaluation of saccharification capacity | |
Endo-β-1,4-Glucanase Activity Assay Kit (Micro Method) | BioReagent | Endocellulase activity detection | Used for measuring endo-β-1,4-glucanase activity and evaluating internal cleavage of cellulose chains | |
Endo-β-1,4-Glucanase Activity Assay Kit (Colorimetric Method) | BioReagent | Endocellulase activity detection | Used for analyzing endo-β-1,4-glucanase activity in colorimetric systems | |
Exo-β-1,4-Glucanase Activity Assay Kit (Micro Method) | BioReagent | Exocellulase activity detection | Used for evaluating exo-β-1,4-glucanase activity and cellobiose release | |
Exo-β-1,4-Glucanase Activity Assay Kit (Colorimetric Method) | BioReagent | Exocellulase activity detection | Used for colorimetric detection of exocellulase activity and analysis of cellulose degradation depth | |
Soil Endo-β-1,4-Glucanase Activity Assay Kit (Micro Method) | BioReagent | Soil cellulose-degrading enzyme detection | Used for measuring cellulose degradation potential and carbon cycling-related enzyme activity in soil samples | |
Soil Endo-β-1,4-Glucanase Activity Assay Kit (Colorimetric Method) | BioReagent | Soil cellulose-degrading enzyme detection | Used for colorimetric measurement of soil endocellulase activity | |
Soil Exo-β-1,4-Glucanase Activity Assay Kit (Micro Method) | BioReagent | Soil cellulose-degrading enzyme detection | Used for evaluating soil exocellulase activity and cellulose degradation processes | |
Soil Exo-β-1,4-Glucanase Activity Assay Kit (Colorimetric Method) | BioReagent | Soil cellulose-degrading enzyme detection | Used for colorimetric detection of exocellulase activity in soil samples | |
β-Glucosidase (β-GC) Activity Assay Kit (Micro Method) | BioReagent | β-Glucosidase activity detection | Used for measuring cellobiose terminal hydrolysis capacity and cellulase saccharification auxiliary enzyme activity | |
β-Glucosidase (β-GC) Activity Assay Kit (Colorimetric Method) | BioReagent | β-Glucosidase activity detection | Used for colorimetric detection of β-glucosidase activity and evaluation of saccharification systems | |
Soil β-Glucosidase (S-β-GC) Activity Assay Kit (Micro Method) | BioReagent | Soil β-glucosidase detection | Used for evaluating soil cellulose degradation terminal hydrolase activity and carbon cycling | |
Soil β-Glucosidase (S-β-GC) Activity Assay Kit (Colorimetric Method) | BioReagent | Soil β-glucosidase detection | Used for colorimetric measurement of soil β-glucosidase activity | |
β-1,3-Glucanase (β-1,3-GA) Activity Assay Kit (Micro Method) | BioReagent | β-1,3-glucanase activity detection | Used for evaluating fungal cell wall β-1,3-glucan degradation capacity | |
β-1,3-Glucanase (β-1,3-GA) Activity Assay Kit (Colorimetric Method) | BioReagent | β-1,3-glucanase activity detection | Used for colorimetric detection of β-1,3-glucanase activity and fungal cell wall enzymatic hydrolysis analysis | |
Xylanase Activity Assay Kit (DNS, Micro Method) | BioReagent | Xylanase activity detection | Used for micro-method measurement of xylanase activity and hemicellulose hydrolysis capacity | |
Xylanase Activity Assay Kit (DNS, Colorimetric Method) | BioReagent | Xylanase activity detection | Used for colorimetric evaluation of xylan hydrolysis and lignocellulose saccharification assistance | |
β-Xylosidase Activity Assay Kit (Micro Method) | BioReagent | β-Xylosidase activity detection | Used for analyzing xylo-oligosaccharide terminal hydrolysis and xylose release capacity | |
β-Xylosidase Activity Assay Kit (Colorimetric Method) | BioReagent | β-Xylosidase activity detection | Used for colorimetric measurement of β-xylosidase activity and evaluation of hemicellulose degradation depth | |
Soil β-Xylosidase Activity Assay Kit (Micro Method) | BioReagent | Soil hemicellulose-degrading enzyme detection | Used for analyzing β-xylosidase activity related to soil xylan degradation | |
Soil β-Xylosidase Activity Assay Kit (Colorimetric Method) | BioReagent | Soil hemicellulose-degrading enzyme detection | Used for colorimetric measurement of soil β-xylosidase activity | |
Pectinase Activity Assay Kit (DNS, Micro Method) | BioReagent | Pectinase activity detection | Used for measuring pectin degradation capacity and plant tissue digestion enzyme activity in micro systems | |
Pectinase Activity Assay Kit (DNS, Colorimetric Method) | BioReagent | Pectinase activity detection | Used for colorimetric measurement of pectinase activity and evaluation of pectin hydrolysis efficiency | |
Polygalacturonase (PG) Activity Assay Kit (Micro Method) | BioReagent | Pectin main-chain hydrolase detection | Used for PG activity measurement, pectin main-chain hydrolysis, and cell wall pectin degradation analysis | |
Polygalacturonase (PG) Activity Assay Kit (Colorimetric Method) | BioReagent | Pectin main-chain hydrolase detection | Used for colorimetric detection of PG activity and evaluation of polygalacturonic acid polymer degradation | |
Pectin Lyase (PL) Activity Assay Kit (UV Micro Method) | BioReagent | Pectin lyase activity detection | Used for PL activity measurement and evaluation of unsaturated pectin oligosaccharide generation | |
Pectin Lyase (PL) Activity Assay Kit (UV Colorimetric Method) | BioReagent | Pectin lyase activity detection | Used for UV colorimetric detection of pectin cleavage reactions | |
Chitinase Activity Assay Kit (Micro Method) | BioReagent | Chitinase activity detection | Used for micro-scale measurement of chitin degradation capacity and fungal cell wall lytic enzyme activity | |
Chitinase Activity Assay Kit (Colorimetric Method) | BioReagent | Chitinase activity detection | Used for colorimetric detection of chitinase activity and evaluation of antifungal enzyme activity | |
Soil Chitinase Activity Assay Kit (Micro Method) | BioReagent | Soil chitin-degrading enzyme detection | Used for evaluating soil chitin degradation, fungal residue decomposition, and nitrogen cycling-related enzyme activity | |
Soil Chitinase Activity Assay Kit (Colorimetric Method) | BioReagent | Soil chitin-degrading enzyme detection | Used for colorimetric measurement of soil chitinase activity | |
N-Acetyl-β-D-glucosaminidase (NAG) Activity Assay Kit (Micro Method) | BioReagent | Chitin terminal hydrolase detection | Used for NAG activity measurement, chitin terminal hydrolysis, and analysis of fungal cell wall degradation products | |
N-Acetyl-β-D-glucosaminidase (NAG) Activity Assay Kit (Colorimetric Method) | BioReagent | Chitin terminal hydrolase detection | Used for colorimetric detection of NAG activity and evaluation of chitin degradation depth | |
Soil N-Acetyl-β-D-glucosaminidase (S-NAG) Activity Assay Kit (Micro Method) | BioReagent | Soil chitin-degrading enzyme detection | Used for soil NAG activity, chitin degradation, and microbial residue decomposition research | |
Soil N-Acetyl-β-D-glucosaminidase (S-NAG) Activity Assay Kit (Colorimetric Method) | BioReagent | Soil chitin-degrading enzyme detection | Used for colorimetric measurement of soil NAG activity | |
Lysozyme (LYS/LZM) Activity Assay Kit (Micro Method) | BioReagent | Lysozyme activity detection | Used for measuring peptidoglycan hydrolysis capacity, bacterial lysis systems, and lysozyme activity | |
Lysozyme (LYS/LZM) Activity Assay Kit (Colorimetric Method) | BioReagent | Lysozyme activity detection | Used for colorimetric detection of lysozyme activity and evaluation of bacterial cell wall lysis capacity | |
Laccase Activity Assay Kit (Micro Method) | BioReagent | Laccase activity detection | Used for measuring laccase activity related to lignin barrier modification | |
Laccase Activity Assay Kit (Colorimetric Method) | BioReagent | Laccase activity detection | Used for colorimetric detection of laccase activity and evaluation of lignocellulose pretreatment | |
Soil Laccase Activity Assay Kit (Micro Method) | BioReagent | Soil lignin oxidase detection | Used for evaluating soil lignin modification, plant residue degradation, and microbial oxidase activity | |
Soil Laccase Activity Assay Kit (Colorimetric Method) | BioReagent | Soil lignin oxidase detection | Used for colorimetric measurement of soil laccase activity | |
Lignin Peroxidase (Lip) Activity Assay Kit (Veratryl Alcohol, Micro Method) | BioReagent | Lignin peroxidase detection | Used for lignin peroxidase activity measurement and lignin barrier pretreatment research | |
Lignin Peroxidase (Lip) Activity Assay Kit (Veratryl Alcohol, Colorimetric Method) | BioReagent | Lignin peroxidase detection | Used for colorimetric evaluation of lignin peroxidase activity | |
Soil Lignin peroxidase (S-Lip) Activity Assay Kit (Resveratrol, Micro Method) | BioReagent | Soil lignin peroxidase detection | Used for evaluating soil plant residue degradation, lignin oxidation, and microbial decomposition activity | |
Soil Lignin Peroxidase (S-Lip) Activity Assay Kit (Veratryl Alcohol, Colorimetric Method) | BioReagent | Soil LiP activity detection | Used for colorimetric detection of soil LiP activity and lignin-related degradation evaluation |
6 Common Questions
6.1 Why are cellulase and pectinase usually used together in plant protoplast preparation?
Cellulose forms the structural framework of the plant cell wall, while pectin mainly maintains the middle lamella and intercellular adhesion. Cellulase alone may not sufficiently separate cells, while pectinase alone is insufficient to disrupt the cell wall framework. Their combination improves cell wall digestion efficiency and protoplast release.
6.2 Should chitinase or β-glucanase be prioritized for fungal cell wall lysis?
The choice should depend on fungal species and cell wall composition. If chitin content is high, chitinase may be prioritized. For yeasts or certain fungal cell walls rich in β-glucan, β-glucanase is often required. In actual lysis, composite enzyme systems are usually used, and conditions should be validated by microscopic observation and lysis rate.
6.3 Why is lysozyme less effective for lysing Gram-negative bacteria?
The outer membrane of Gram-negative bacteria blocks lysozyme from reaching the peptidoglycan layer, so lysozyme alone often cannot achieve complete lysis. EDTA, mild surfactants, heat treatment, or mechanical disruption can increase outer membrane permeability, but treatment intensity should be controlled according to downstream nucleic acid, protein, or activity assays.
6.4 Does reduced biofilm after polysaccharidase treatment indicate cell death?
Not necessarily. Polysaccharidases may only disrupt the extracellular polysaccharide matrix and loosen the biofilm structure, while cells remain viable. Viable cell counts, metabolic activity, membrane integrity, and microscopic structure should be assessed together to distinguish matrix degradation from killing.
6.5 Why is a heat-inactivated enzyme control needed in polysaccharide-degrading enzyme experiments?
A heat-inactivated enzyme control helps exclude the effects of non-enzymatic components, buffers, salts, or impurities in enzyme preparations on substrates and cell status. If the heat-inactivated enzyme control still produces a significant signal, the result may involve non-enzymatic degradation, chemical interference, or detection background.
Research on plant and microbial cell wall polysaccharide-degrading enzymes should establish correspondence among substrate structure, enzyme mode of action, and experimental readouts. Structural differences among cellulose, hemicellulose, pectin, chitin, β-glucan, and peptidoglycan determine enzyme selection. Reducing sugars, oligosaccharide profiles, cell lysis rates, and microscopic structures reflect different levels of degradation outcomes.
