Principles, Methods, and Applied Practice of Enzyme Activity Assays
Principles, Methods, and Applied Practice of Enzyme Activity Assays
Enzyme activity reflects the rate capability by which an enzyme catalyzes the conversion of substrate to product, and is a key parameter for characterizing metabolic state, evaluating pathological changes, describing the intensity of biological processes, and optimizing industrial biocatalytic systems. For different sample types and analytical objectives, enzyme activity is commonly quantified by monitoring substrate consumption, product formation, or changes in optical/electrochemical properties of the reaction system, with reaction-condition control, identification of the linear range, and correction of matrix interference serving as the core safeguards for data reliability. Establishing fit-for-purpose assay methodologies and standardized quality-control workflows helps improve sensitivity, specificity, and result comparability, thereby supporting multi-scenario applications in life science research, clinical testing, industrial process control, and food and environmental monitoring.
Keywords: enzyme activity; kinetics; spectrophotometry; fluorescence; electrochemistry; chromatography; biosensors; quality control
I. Background and Significance
Enzymes are highly efficient and specific catalytic molecules in biological systems. Changes in enzyme activity often precede changes in endpoint concentrations, and can therefore reflect physiological metabolism, signaling regulation, and stress responses with higher sensitivity. In life science research, enzyme activity is used to resolve pathway bottlenecks and regulatory mechanisms; in clinical testing, abnormal activity of specific enzymes can serve as an important clue for disease screening and therapeutic evaluation; in industrial production, enzyme activity is a core metric for fermentation and enzyme-preparation quality control, process optimization, and scale-up verification. Consequently, the choice of enzyme activity assay technology and the quality of implementation directly affect the reliability of scientific conclusions and the validity of process decisions.
II. Core Principles of Enzyme Activity Measurement
The essence of enzyme activity is the ability of an enzyme, under defined conditions, to catalyze the conversion of a specific substrate to product. The core quantitative logic is to monitor, under controllable conditions during the enzymatic reaction: the rate of decrease in substrate concentration, the rate of increase in product concentration, or the rate of change in physicochemical signals associated with reaction progress (absorbance, fluorescence intensity, luminescence intensity, current/potential, etc.), and then convert these rates into enzyme activity.
Common units include:
- U (International Unit): the amount of enzyme that catalyzes the conversion of 1 μmol of substrate (or formation of 1 μmol of product) in 1 min under specified conditions;
- kat (katal): the amount of enzyme that catalyzes the conversion of 1 mol of substrate in 1 s.
To obtain comparable and traceable data, measurement should satisfy three key conditions:
- Reaction conditions are constant (temperature, pH, ionic strength, cofactors, etc.);
- The reaction is within the initial-rate linear region (rate is approximately proportional to enzyme amount);
- Bias sources such as substrate depletion, product inhibition, matrix interference, and non-specific reactions are avoided or corrected.
III. Mainstream Enzyme Activity Assay Technologies and Their Characteristics
3.1 Spectroscopic Methods: The Mainstream System for Routine Laboratory Testing
(1) UV–Visible spectrophotometry
The principle is to monitor the time-dependent change in absorbance of the substrate/product at a characteristic wavelength, and to convert reaction rate and enzyme activity using the Beer–Lambert law. A typical example is the dehydrogenase system in which NADH exhibits a characteristic absorption at 340 nm: NADH generation or consumption during the reaction causes absorbance changes that can be used to calculate the initial rate.
- Advantages: widely available instruments, simple operation, good repeatability, suitable for process monitoring;
- Limitations: more suitable for systems where substrate or product has a distinct absorption peak; color/turbidity in complex samples can elevate background.
(2) Fluorescence assays
The principle is to use fluorescent substrates/probes that produce changes in fluorescence signals (increase, decrease, or wavelength shift) after enzymatic catalysis, and to characterize enzyme activity via the rate of fluorescence change. This is commonly used for low-abundance enzymes, micro-volume systems, or high-throughput screening.
- Advantages: high sensitivity; limits of detection are often superior to colorimetric systems;
- Limitations: inner-filter effects, photobleaching, sample autofluorescence, and fluorescence quenching require evaluation and correction.
(3) Chemiluminescence assays
The principle is that enzyme catalysis triggers chemiluminescent substrate systems to generate light emission, with luminescence intensity correlated with enzyme activity. This is commonly used in scenarios requiring extremely high sensitivity or in trace biomarker systems.
- Advantages: high sensitivity, low background, no external excitation light required;
- Limitations: substrate stability and reaction time window strongly affect results; strict timing and consistent mixing are required.
3.2 Electrochemical Methods: An Important Direction for Micro-Volume, Rapid, and Portable Testing
Electrochemical methods quantify enzyme activity by monitoring changes in current, potential, or conductivity caused by the production/consumption of electroactive species generated in enzymatic reactions (e.g., H₂O₂, electron-transfer mediators).
(1) Typical detection modes
- Amperometry: measure current changes at a fixed potential; commonly used for quantifying redox products;
- Potentiometry: monitor potential changes; suitable for systems with pronounced ionic/charge changes;
- Impedance: detect changes in interfacial electrochemical properties; can be combined with immobilized systems.
(2) Method characteristics
- Advantages: fast response, high sensitivity, easy miniaturization and field deployment;
- Limitations: electrode materials and surface states must be consistent; ionic strength and pH can strongly affect signals; electrode fouling and drift must be controlled via calibration and QC.
3.3 Chromatographic Methods: A High-Specificity Route for Precise Quantification
Chromatography separates substrates and products and quantifies their concentration changes to calculate enzyme activity. It is especially suitable for situations where structurally similar substrates/products coexist, multi-substrate/multi-product systems, or complex-matrix samples.
(1) Liquid chromatography (HPLC/UPLC)
Can be used to quantify sugars, amino acids, nucleotides, and various small-molecule products. Coupling with UV/fluorescence/mass spectrometric detectors can improve sensitivity and specificity.
(2) Gas chromatography (GC)
Suitable for volatile substrates/products; non-volatile samples usually require derivatization prior to analysis.
- Advantages: strong separation capability, high specificity, reliable quantification;
- Limitations: relatively complex workflow, longer turnaround time, higher requirements for instrumentation and method development; more suitable for confirmatory analysis and method validation.
3.4 Biosensor Methods: A Key Form Factor for Real-Time and Engineered Applications
Biosensors couple enzymatic recognition elements with signal transduction units to enable rapid, real-time, or continuous monitoring.
(1) Structural components
- Recognition element: immobilized enzyme or enzymatic reaction system;
- Transduction element: electrochemical, optical, piezoelectric, etc.;
- Amplification and processing: signal amplification, filtering, and algorithmic correction.
(2) Method characteristics
- Advantages: rapid detection, deployable online/on-site, easy integration with microfluidics and portable devices;
- Limitations: immobilized enzyme stability, sensor lifetime, and inter-batch consistency are key bottlenecks, requiring systematic stability evaluation and calibration strategies.
IV. Key Influencing Factors and Quality Control
4.1 Control of Reaction-Condition Parameters
- Temperature: enzyme activity is temperature-dependent; above the optimum temperature, conformational damage may cause inactivation. Use thermostatic devices and record temperature deviations.
- pH: ionization states at the active site determine catalytic efficiency. Use buffering systems to maintain pH stability, and avoid buffer components that participate in side reactions or interfere with readouts.
- Substrate concentration: ensure the reaction remains within the initial-rate linear region and is preferably close to substrate saturation; in practice, substrate concentration is often set to ~3–10×Km and the linear region confirmed by preliminary experiments.
- Ionic strength and cofactors: metal ions, salt concentration, and coenzymes (e.g., NAD(P)H) can markedly affect activity; fix concentrations and include omission controls to verify dependence.
4.2 Sample and Reagent Factors
- Sample preprocessing: complex samples may contain inhibitors/activators and exhibit turbidity/color interference. Strategies such as centrifugation, filtration, dialysis, desalting, or dilution can be used, and matrix effects evaluated via recovery or standard-addition approaches.
- Enzyme stability: some enzymes lose activity readily ex vivo; operate at low temperature and minimize freeze–thaw cycles. If needed, add stabilizers (e.g., glycerol, inert proteins) and clarify their effects on assay signals.
- Reagent purity and batch consistency: impurities in substrates, coenzymes, and buffer components can introduce non-specific reactions or background drift. Establish batch verification and incoming inspection mechanisms.
4.3 Data Processing and Decision Rules
- Linear region: calculate initial rate using the linear-fitted region of the time–signal curve; avoid late-stage reaction data.
- Blanks and controls: include at least a reagent blank, a sample blank (no substrate or no reaction initiation), and a positive control; for complex matrices, consider standard addition or spike recovery.
- Repeatability: set technical replicates and within-batch QC materials; define outlier rules and retest conditions to ensure traceability.
V. Selection Criteria for Reagents and Consumables
5.1 Selection of Enzyme Activity Assay Kits
(1) Methodological compatibility
- Colorimetric/UV micro-assays: suitable for routine quantification and process monitoring;
- Fluorescence/luminescence systems: suitable for micro-volume, low-abundance targets, and high-throughput screening;
- Mechanism-specific systems (e.g., tetrazolium salt color development): suitable for scenarios requiring wider dynamic range or stronger signal amplification.
(2) Compatibility with sample type
Different matrices (cell lysates, tissue homogenates, biofluids, food extracts, environmental samples, etc.) differ substantially. Prefer systems that explicitly specify compatible matrices and provide matrix-correction strategies; when necessary, verify suitability via spike-recovery experiments.
(3) Quality grade and batch management
Prefer high-purity grades and stable formulations suitable for bioactivity analysis; pay attention to batch consistency of critical components and in-shelf-life stability, and perform bridging validation when changing lots.
Product list
Catalog No. | Product Name | Grade and Purity | Assay Type | Scope | Typical Application Direction |
Pyruvate Kinase (PK) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | Glycolysis-related enzyme activity evaluation; suitable for research comparisons across treatments | Glycolysis / energy metabolism | |
Acetokinase (ACK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV standard assay | ACK activity evaluation; suitable for comparing activity across samples/conditions | Microbial metabolism / metabolic engineering | |
Acetokinase (ACK) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | ACK activity evaluation; suitable for limited sample amount or multi-sample comparisons | Microbial metabolism / metabolic engineering | |
Acetylcholinesterase (AchE) activity detection kit (DTNB, microcalorimetry) | BioReagent | DTNB, micro-assay | Cholinesterase-related activity evaluation; inhibition-effect studies or pre/post comparisons | Neuroenzymology / inhibitor screening | |
Caspase 3/7 Activity Assay Kit | BioReagent | Activity assay kit (refer to manual) | Caspase-3/7 activity trend evaluation in apoptosis studies; group comparisons | Apoptosis / pharmacological evaluation | |
Caspase 3 Activity Assay Kit | BioReagent; Suitable for Analysis; Colorimetry | Colorimetric | Comparative analysis of Caspase-3 activity; relative quantification and trend assessment | Apoptosis / mechanistic research | |
Caspase 2 Activity Assay Kit | BioReagent | Activity assay kit (refer to manual) | Caspase-2 activity evaluation; comparisons under stress/apoptosis conditions | Stress response / apoptosis | |
Caspase 6 Activity Assay Kit | BioReagent | Activity assay kit (refer to manual) | Caspase-6 activity evaluation; mechanism studies or condition comparisons | Apoptosis / mechanistic research | |
Caspase 9 Activity Assay Kit | BioReagent | Activity assay kit (refer to manual) | Caspase-9 activity trend evaluation; comparisons for mitochondrial pathway | Mitochondrial apoptosis pathway | |
Creatin Kinase (CK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV standard assay | CK activity evaluation; suitable for energy metabolism studies or cross-sample comparisons | Energy metabolism / muscle-related research | |
Chloroplast 3-Phosphoglycerate Kinase (chl PGK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV colorimetric | Plant/chloroplast enzyme activity evaluation; sample/condition comparisons | Photosynthetic metabolism / plant physiology | |
Chloroplast 3-Phosphoglycerate Kinase (chl PGK) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | Plant/chloroplast enzyme activity evaluation; suitable for small sample volume or multi-sample comparisons | Photosynthetic metabolism / plant physiology | |
Catalase (CAT) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV colorimetric | CAT activity evaluation; comparisons across samples in oxidative-stress studies | Oxidative stress / antioxidation | |
Catalase (CAT) Activity Assay Kit (AHM, Colorimetric Method) | BioReagent | Ammonium molybdate, colorimetric | CAT activity evaluation; suitable for visible-light colorimetry comparisons | Oxidative stress / antioxidation | |
Catalase (CAT) Activity Assay Kit (AHM, Micro Method) | BioReagent | Ammonium molybdate, micro-assay | CAT activity evaluation; suitable for limited sample amount or multi-condition comparisons | Oxidative stress / antioxidation | |
Ca²⁺/Mg²⁺-ATPase Activity Assay Kit (AHM, Micro Method) | BioReagent | Ammonium molybdate, micro-assay | Ca²⁺/Mg²⁺-dependent ATPase activity evaluation; condition-based comparisons | Membrane protein function / ion pumps | |
Cellulase (CL) Activity Assay Kit (DNS, Micro Method) | BioReagent | DNS, micro-assay | Cellulase activity evaluation; enzyme preparation comparison or condition optimization | Biomass degradation / industrial enzymology | |
Cellulase (CL) Activity Assay Kit (DNS, Colorimetric Method) | BioReagent | DNS, colorimetric | Cellulase activity evaluation; routine colorimetric comparisons | Biomass degradation / industrial enzymology | |
L-Lactate Dehydrogenase Assay Kit (WST-8) | BioReagent; Suitable for Analysis; Colorimetry | WST-8 method | L-LDH activity evaluation; trend and condition comparisons | Energy metabolism / lactate metabolism | |
D-Lactate Dehydrogenase (D-LDH) Activity Assay Kit (DNPH, Micro Method) | BioReagent | DNPH, micro-assay | D-LDH activity evaluation; microbial metabolism or fermentation-related sample comparisons | Microbial metabolism / fermentation research | |
Fructokinase (FRK) Activity Assay Kit (Micro Method) | BioReagent | Micro-assay | FRK activity evaluation; multi-sample comparisons and condition optimization | Sugar metabolism / fructose metabolism | |
Fructokinase (FRK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV colorimetric | FRK activity evaluation; comparisons under UV readout | Sugar metabolism / fructose metabolism | |
α-Amylase (α-AL) Activity Assay Kit (DNS, Micro Method) | BioReagent | DNS, micro-assay | α-Amylase activity evaluation; hydrolytic capacity comparison or condition screening | Carbohydrate hydrolysis / enzyme preparation evaluation | |
Glutathione S-transferase (GST) detection kit (CDNB, microcalorimetry) | BioReagent | CDNB, micro-assay | GST activity evaluation; condition comparisons in detoxification studies | Detox metabolism / pharmacology-toxicology | |
Glucokinase (GK) Activity Assay Kit (Micro Method) | BioReagent | Micro-assay | GK activity evaluation; multi-sample comparisons or treatment-difference analysis | Sugar metabolism / energy metabolism | |
Glucokinase (GK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV colorimetric | GK activity evaluation; comparisons under UV readout | Sugar metabolism / energy metabolism | |
Glutathione Peroxidase (GSH-Px) Activity Assay Kit (DTNB, Colorimetric Method) | BioReagent | DTNB, colorimetric | GSH-Px activity evaluation; sample comparisons under oxidative stress | Oxidative stress / antioxidation | |
Glutathione Peroxidase (GSH-Px) Activity Assay Kit (DTNB, Micro Method) | BioReagent | DTNB, micro-assay | GSH-Px activity evaluation; suitable for limited sample amount or multi-sample comparisons | Oxidative stress / antioxidation | |
Glutamic Dehydrogenase (GDH) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | GDH activity evaluation; comparisons in amino-acid metabolism studies | Amino acid metabolism / nitrogen metabolism | |
Glutamate Synthase (GOGAT) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | GOGAT activity evaluation; comparisons in nitrogen assimilation research | Plant nitrogen assimilation / nitrogen metabolism | |
Glutathione S-Transferase (GST) Activity Assay Kit (Micro Assay) | BioReagent | Micro-assay | GST activity evaluation; multi-sample screening and condition comparisons | Detox metabolism / pharmacology-toxicology | |
Glutathione Reductases (GR) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | GR activity evaluation; condition comparisons in antioxidative systems | Oxidative stress / antioxidation | |
Glucose-6-Phosphate Dehydrogenase (G6PDH) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | G6PDH activity evaluation; comparisons in PPP-related studies | PPP / redox support | |
Hexokinase (HK) Activity Assay Kit (WST-8, Micro Method) | BioReagent | WST-8, micro-assay | HK activity evaluation; multi-sample comparisons and condition screening | Sugar metabolism / energy metabolism | |
Hexokinase (HK) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | HK activity evaluation; suitable for limited sample amount or multi-condition comparisons | Sugar metabolism / energy metabolism | |
Hexokinase (HK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV standard assay | HK activity evaluation; routine spectrophotometric comparisons | Sugar metabolism / energy metabolism | |
Lactate Dehydrogenase (LDH) Cytotoxicity Assay Kit (WST-8, Micro Method) | BioReagent | WST-8, micro-assay | Trend evaluation of cell damage/toxicity (LDH-related); group comparisons | Cytotoxicity / pharmacology | |
Lactate Dehydrogenase (LDH) Cytotoxicity Assay Kit (DNPH, Micro Method) | BioReagent | DNPH, micro-assay | Trend comparison of cell damage across treatments | Cytotoxicity / pharmacology | |
NAD Kinase (NADK) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | NADK activity evaluation; comparisons in cofactor-metabolism studies | Cofactor metabolism / redox | |
NAD Kinase (NADK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV standard assay | NADK activity evaluation; routine enzymology comparisons | Cofactor metabolism / redox | |
Na⁺/K⁺-ATPase Activity Assay Kit (AHM, Micro Method) | BioReagent | Ammonium molybdate, micro-assay | Na⁺/K⁺-ATPase activity evaluation; membrane pump function comparisons | Membrane protein function / ion pumps | |
Phosphofructokinase (PFK) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | PFK activity evaluation; comparisons in glycolysis research | Glycolysis / energy metabolism | |
Phosphoenol Pyruvate Carboxykinase (PEPCK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV standard assay | PEPCK activity evaluation; comparisons in metabolic regulation research | Gluconeogenesis / metabolic regulation | |
Pyruvate Kinase (PK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV standard assay | PK activity evaluation; sample/condition comparisons | Glycolysis / energy metabolism | |
Phosphoenol Pyruvate Carboxykinase (PEPCK) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | PEPCK activity evaluation; suitable for limited sample amount or multi-sample comparisons | Gluconeogenesis / metabolic regulation | |
Plant Polyphenol Oxidase (PPO) Activity Assay Kit (Catechol, Micro Method) | BioReagent | Catechol, micro-assay | PPO activity evaluation; comparisons in browning/stress-related research | Plant physiology / quality & stress tolerance | |
Pyruvate Phosphate Dikinase (PPDK) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | PPDK activity evaluation; trend comparisons in plant metabolism | Photosynthetic metabolism / metabolic regulation | |
Pyruvate Phosphate Dikinase (PPDK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV standard assay | PPDK activity evaluation; routine spectrophotometric comparisons | Photosynthetic metabolism / metabolic regulation | |
3-Phosphoglycerate Kinase (PGK) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | PGK activity evaluation; comparisons in metabolic pathway research | Sugar metabolism / energy metabolism | |
3-Phosphoglycerate Kinase (PGK) Activity Assay Kit (UV Colorimetric Method) | BioReagent | UV colorimetric | PGK activity evaluation; comparisons under UV readout | Sugar metabolism / energy metabolism | |
Peroxidase (POD) Activity Assay Kit (Guaiacol, Micro Method) | BioReagent | Guaiacol, micro-assay | POD activity evaluation; trend comparisons in oxidative stress/plant studies | Oxidative stress / plant stress tolerance | |
Plant Root Activity Assay Kit (TTC, Colorimetric Method) | BioReagent | TTC, colorimetric | Root vigor trend evaluation; pre/post or cross-sample comparisons | Plant physiology / root phenotyping | |
Soil Catalase (S-CAT) Activity Assay Kit (UV Micro Method) | BioReagent | UV micro-assay | Soil/environmental enzyme activity evaluation; soil-to-soil or treatment comparisons | Environmental / soil enzymology | |
Total Superoxide Dismutase (T-SOD) Activity Assay Kit (WST-8, Micro Method) | BioReagent | WST-8, micro-assay | Total SOD activity evaluation; trend comparisons in oxidative stress studies | Oxidative stress / antioxidation |
5.2 Substrate and Probe Selection
(1) Peptide substrates and reporter groups (e.g., AMC/AFC/pNA)
- Specificity: substrate sequences should match the recognition sites of the target protease to avoid cross-reactivity that elevates “apparent activity”;
- Purity and background: high-purity substrates reduce background from impurity peptides; select fluorescent or colorimetric reporter groups according to the instrument platform and evaluate inner-filter effects and baseline absorbance.
Product list
Catalog No. | Product Name | Grade and Purity | Signal Type | Scope | Typical Application Direction | Use Notes |
Ala-Ala-Phe-AMC, TFA salt | BioReagent; ≥98% | Fluorescence (AMC) | Protease/peptidase substrate screening and activity evaluation; condition comparisons; inhibition observation | Protease activity / substrate screening | TFA salt; suitable for fluorescence readers | |
Ac-LEHD-AMC, TFA salt | BioReagent; ≥98% | Fluorescence (AMC) | Caspase-related activity evaluation; trend comparisons in apoptosis/inflammation studies | Apoptosis (caspase-related) / inhibitor studies | TFA salt; suitable for fluorescence readers | |
Ac-WEHD-AMC, TFA salt | BioReagent; ≥98% | Fluorescence (AMC) | Caspase-related activity evaluation; sample comparisons or inhibitor prescreening | Inflammation (caspase-related) / inhibitor screening | TFA salt; suitable for fluorescence readers | |
Ac-DEVD-AFC | BioReagent; ≥98% | Fluorescence (AFC) | Caspase-related activity evaluation; treatment-condition comparisons | Apoptosis (Caspase-3/7-related) | Suitable for fluorescence readers | |
Caspase 2 substrate (chromogenic) | BioReagent; ≥98%(HPLC) | Colorimetric (pNA) | Caspase-related activity evaluation; trend analysis under visible-light readout | Apoptosis / stress (Caspase-2-related) | Chromogenic substrate; suitable for spectrophotometers/plate readers | |
Gly-Phe-AMC, TFA salt | BioReagent; ≥98% | Fluorescence (AMC) | Protease/peptidase substrate screening and activity evaluation; comparisons across systems/conditions | Protease activity / substrate screening | TFA salt; suitable for fluorescence readers | |
Gly-Phe-AFC,TFA salt | ≥98% | Fluorescence (AFC) | Protease/peptidase substrate screening and activity evaluation; enzymology and inhibition observation | Protease activity / substrate screening | TFA salt; suitable for fluorescence readers | |
Z-DEVD-AFC | BioReagent; ≥98% | Fluorescence (AFC) | Caspase-related activity evaluation; trend comparisons in apoptosis studies | Apoptosis (Caspase-3/7-related) / inhibitor screening | Suitable for fluorescence readers | |
Z-DEVD-AMC | BioReagent; ≥98% | Fluorescence (AMC) | Caspase-related activity evaluation; sample comparisons and condition screening | Apoptosis (Caspase-3/7-related) | Suitable for fluorescence readers |
(2) Non-peptide substrates/probes
Suitable for glycosidases, oxidases, and related enzyme systems. Key points to evaluate include:
- probe stability;
- interference from reaction by-products (including non-specific side reactions);
- the linearity between product signal output and reaction rate (within the initial-rate window).
Product list
Catalog No. | Product Name | Grade and Purity | Scope | Typical Application Direction |
D-Luciferin-6-O-β-D-galactopyranoside | ≥98% | Substrate conversion/enzyme activity evaluation related to β-galactosidase; applicable to reporter systems or trend comparisons in assay optimization | Reporter genes / enzyme activity / substrate screening |
5.3 Auxiliary Enzymes and Buffer Systems
(1) Auxiliary enzymes / recombinant proteins
Auxiliary enzymes used for coupled reactions, signal amplification, or system calibration should be evaluated for: specific activity, contaminating enzyme activities, potential effects of tag types on activity, and storage and repeated freeze–thaw stability.
Product list
Catalog No. | Product Name | Grade and Purity | Scope | Typical Application Direction | Key Use Points |
Recombinant Taq DNA Polymerase Protein | EnzymoPure™; His-Tag; ≥95%; See COA | Enzymology applications in DNA amplification-related reactions; routine amplification and condition optimization | Molecular biology amplification / method development and optimization | Reaction system and cycling conditions can be optimized by template complexity and target length; refer to COA/manual | |
Horseradish Peroxidase (HRP) | Bioactive; ActiBioPure™; Native; High Performance; EnzymoPure™; ≥300U/mg enzyme powder, Rz≥3; from Horseradish | Peroxidase-catalyzed chromogenic/luminescent systems; signal amplification and labeling assays | Immunoassays / protein labeling and chromogenic systems | Applicable to common HRP substrate systems; tune substrate and reaction time by required signal | |
Horseradish Peroxidase (HRP) | Bioactive; Recombinant; ActiBioPure™; High Performance; EnzymoPure™; ≥250U/mg enzyme powder, Rz ≥3; expressed in Nicotiana benthamiana | Peroxidase-catalyzed chromogenic/luminescent systems; detection/labeling applications | Immunoassays / protein labeling and chromogenic systems | Optimize dilution and reaction conditions to match the target system; consult manual and assay conditions | |
Horseradish Peroxidase (HRP) | Bioactive; Recombinant; ActiBioPure™; High Performance; EnzymoPure™; ≥150U/mg enzyme powder, Rz ≥2; expressed in Nicotiana benthamiana | Peroxidase-catalyzed chromogenic/luminescent systems; routine detection and method development | Immunoassays / protein labeling and chromogenic systems | Suitable for common HRP substrate systems; adjust enzyme amount/substrate concentration to achieve an appropriate SNR | |
Recombinant Sumo Protease Protein | Carrier Free; Bioactive; ActiBioPure™; Azide Free; High Performance; His-Tag; ≥90%(SDS-PAGE) | Enzymology applications for fusion-protein tag removal/cleavage; applicable to purification workflows | Protein expression & purification / tag removal / process development | Optimize cleavage ratio, temperature, and time by substrate protein and tag construct; azide-free for azide-sensitive systems |
(2) Buffers and supporting solutions
- pH compatibility: match the optimal pH of the target enzyme;
- System compatibility: electrochemical assays should avoid components that affect electrode signals; high-sensitivity fluorescence systems should consider fluorescent impurities;
- Purity and sterility: select buffer systems with low impurities and low endogenous enzyme contamination; use sterile filtration and cold storage when necessary.
Product list
Catalog No. | Product Name | Grade and Purity | Scope | Typical Application Direction | Key Use Points |
TNT Buffer (10×) | sterile-filtered; BioReagent; Suitable for molecular biology; 10× | Preparation and maintenance of common buffer systems in molecular biology experiments; applicable to routine nucleic acid/protein workflows (subject to protocol) | General molecular biology buffers / workflow support | 10× concentrate, typically diluted to working concentration; sterile filtration is suitable for contamination-sensitive workflows; adjust per manual and assay system |
VI. Applied Practice and Summary
6.1 Life Science Research
- Used to analyze metabolic pathways and signal transduction. For example, kinase/phosphatase activity reflects pathway activation status, and nuclease activity is used to evaluate nucleic acid processing and gene-editing system performance; in drug screening, high-throughput fluorescence/luminescence systems can rapidly assess enzyme inhibition or activation effects.
6.2 Clinical Testing
- Activities of many serum enzymes correlate with tissue injury and can be used for auxiliary diagnosis, disease-course monitoring, and prognosis evaluation. Clinical scenarios emphasize methodological standardization, establishment of reference intervals, inter-batch consistency, and completeness of QC rules.
6.3 Industrial Production and Process Control
- In fermentation, enzyme preparation manufacturing, and food processing, enzyme activity is used to monitor key process nodes, evaluate batch quality, and optimize scale-up parameters; online or nearline electrochemical/sensor systems can improve process response speed and reduce delays from sampling and off-site testing.
6.4 Food and Environmental Monitoring
- Enzyme activity in foods can reflect processing adequacy and quality-change trends; in environmental samples, specific enzyme activities can serve as sensitive indicators of ecological process intensity and pollution stress. However, matrix-interference correction and recovery verification must be strengthened to ensure cross-region and cross-time comparability.
- Enzyme activity assays have formed a multi-technology spectrum, with spectroscopic methods as the routine backbone, electrochemistry and biosensors supporting rapid and field-deployable testing, and chromatography supporting high-specificity confirmatory quantification. Regardless of the chosen route, the key to data reliability lies in: control of reaction conditions and the linear region, evaluation and correction of matrix interference, and an executable QC system (blanks, controls, recovery, and within-/between-batch QC). Looking forward, enzyme activity assays will further develop toward high throughput, miniaturization, automation, and intelligence, and—with coordinated optimization of standardized methodologies and supporting reagents/consumables—will improve cross-platform and cross-scenario consistency, expanding application depth and breadth in point-of-care clinical testing, online industrial monitoring, and rapid environmental assessment.
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