Technical articles
Acetyl-Group Metabolic Enzyme Network and In Vitro Enzymology Analysis
Acetyl-Group Metabolic Enzyme Network and In Vitro Enzymology Analysis
Acetyl-group metabolism lies at the intersection of central carbon metabolism, lipid synthesis, post-translational protein modification, and epigenetic regulation. Interconversion among acetyl-CoA, acetate, citrate, and multiple acyl intermediates not only determines the direction of carbon-flux partitioning, but also directly influences protein acetylation states, metabolic-enzyme activity, and cellular functional output. Accordingly, research centered on key enzymatic nodes involved in acetyl-group generation, transport, transfer, and removal is an important component of pathway analysis and in vitro enzymology.
Keywords: acetyl-group metabolism; acetyl-CoA; acetyltransferases; deacetylases; pathway analysis; in vitro enzymology; central carbon metabolism; epigenetic regulation
1. Framework of Acetyl-Group Metabolism
1.1 Metabolic positioning and analytical hierarchy
(1) The dual attributes of the acetyl group
On the one hand, the acetyl group enters the tricarboxylic acid cycle, fatty acid synthesis, cholesterol synthesis, and ketone-body metabolism. On the other hand, it participates in chromatin regulation, control of protein stability, and remodeling of enzyme activity through lysine acetylation, N-terminal acetylation, and related processes. Thus, acetyl-group metabolism is not merely a process of material conversion, but a key layer coupling metabolic input with functional output.
(2) Integrated analysis of the donor layer and the modification layer
If only acetyl-CoA abundance is measured without analyzing acetyltransferase and deacetylase activity, differences in acetylation phenotypes are difficult to interpret. Conversely, if only acetylation levels are measured without tracing donor origin and compartmental distribution, it is difficult to establish a causal relationship between metabolic supply and modification changes. Therefore, studies of acetyl-group metabolism should adopt an analytical framework linking source, distribution, transfer, removal, and functional consequences.
1.2 Compartment specificity and carbon-flux coupling
(1) Differences in acetyl-group supply across subcellular compartments
Mitochondrial acetyl-CoA is mainly derived from pyruvate oxidation, fatty acid beta-oxidation, and degradation of certain amino acids, whereas cytosolic and nuclear acetyl-CoA depends more heavily on citrate cleavage and acetate reactivation. Therefore, different acetylation events within the same cell show clear compartment dependence.
(2) Effects of intercompartmental transport on acetyl-group accessibility
The citrate shuttle, acetate reutilization, and ketone-body metabolism can all alter acetyl-group availability in different compartments. Therefore, research on acetyl-group metabolic enzymes should not remain limited to measurement of a single enzyme activity, but must also be interpreted in conjunction with intercompartmental transport and metabolic coupling.
2. Nodes of Acetyl-Group Donor Generation
2.1 Glucose-derived entry points into the acetyl pool
(1) Pyruvate dehydrogenase complex
After glucose is converted to pyruvate through glycolysis, pyruvate must be converted to acetyl-CoA by the pyruvate dehydrogenase complex before it can enter the tricarboxylic acid cycle and multiple acetyl-dependent pathways. Accordingly, the PDH complex is a key entry node through which glucose-derived carbon flux is introduced into the acetyl pool.
(2) Activity regulation and flux limitation
PDH is regulated by phosphorylation, dephosphorylation, substrate supply, and the NADH/NAD+ state. Changes in its activity can markedly affect the capacity for mitochondrial acetyl-CoA generation. Therefore, in pathway analysis, PDH is not only a metabolic node, but also an important threshold node for entry of glucose-derived carbon flux into the acetyl-group metabolic network.
2.2 Formation of cytosolic and nuclear acetyl-group donors
(1) Carbon-output conversion mediated by ATP-citrate lyase
ACLY catalyzes the cleavage of citrate to produce acetyl-CoA and oxaloacetate, and is an important donor source for cytosolic lipid synthesis and nuclear acetylation reactions. Its function is not limited to replenishing cytosolic acetyl-CoA, but extends to converting mitochondria-derived carbon flux into acetyl-group input available for epigenetic regulation.
(2) Acetate reactivation mediated by the acetyl-CoA synthetase family
ACSS2 mainly catalyzes conversion of acetate into acetyl-CoA in the cytosol and nucleus, whereas ACSS1 is more strongly associated with mitochondrial localization. This pathway is particularly important under conditions of nutrient limitation, hypoxia, acetate enrichment, and metabolic reprogramming, and serves as a key node for non-glucose-derived acetyl-group supply.
2.3 Alternative sources of acetyl groups
(1) Fatty acid beta-oxidation pathway
After long-chain fatty acids enter mitochondria, they continuously generate acetyl-CoA through beta-oxidation. Therefore, under high-fat conditions, starvation, and certain tumor-metabolic contexts, lipid-derived acetyl groups may constitute an important source of supply.
(2) Ketone-body utilization pathway
Acetoacetate and beta-hydroxybutyrate can be converted back to acetyl-CoA through the relevant enzyme systems, thereby supplementing both energy metabolism and acetyl-group supply. Accordingly, ketone-body utilization should be incorporated into the source-classification framework in acetyl-group pathway analysis.
Table 1. Key enzymes related to acetyl-group donor generation and their functional positioning
Enzyme / Enzyme Complex | Main Substrate | Main Product | Functional Positioning | Main Research Significance |
Pyruvate dehydrogenase complex (PDH) | Pyruvate | Acetyl-CoA | Entry point for glucose-derived acetyl groups | Coupling of glycolysis to the TCA cycle and acetylation pathways |
ATP-citrate lyase (ACLY) | Citrate | Acetyl-CoA | Cytosolic / nuclear acetyl-group supply | Coupling of lipid synthesis and epigenetic acetylation |
Acetyl-CoA synthetase 1/2 (ACSS1/2) | Acetate | Acetyl-CoA | Acetate reactivation | Supply of non-glucose-derived acetyl groups |
Carnitine palmitoyltransferase system (CPT) | Long-chain fatty acyl groups | Entry into the beta-oxidation pathway | Carbon-entry point for fatty acids | Formation of lipid-derived acetyl groups |
Ketone-body-metabolism-related enzymes | Ketone bodies | Acetyl-CoA | Alternative source of acetyl groups | Studies of starvation and metabolic reprogramming |
Phosphotransacetylase (PTA) | Acetyl-CoA, inorganic phosphate | Acetyl phosphate, CoA | Interconversion node between acetyl-CoA and acetyl phosphate | Acetate metabolism, acetyl-phosphate bypass, and microbial acetyl-flux analysis |
3. Acetyl-Group Transfer Nodes
3.1 Protein acetyltransferase systems
(1) Lysine acetyltransferases
The KAT family uses acetyl-CoA as a donor to transfer acetyl groups to lysine residues on histones and non-histone proteins. This process can alter chromatin accessibility, transcription-complex assembly, and the functional state of metabolic enzymes, and therefore serves as a central bridge through which acetyl groups move from the metabolic pool into the functional layer.
(2) Substrate selectivity and site specificity
Different KAT family members exhibit distinct preferences for substrate proteins, peptide sequences, structural environments, and subcellular localization. Therefore, even when acetyl-CoA supply is sufficient, output from different acetyltransferase systems may still differ substantially.
3.2 Noncanonical acetylation outputs
(1) N-terminal acetylation
In addition to lysine acetylation, N-terminal acetylation is also an important protein-modification mode, with sustained effects on protein stability, localization, and molecular interactions. Therefore, acetyl-group transfer is not limited to histones and classical non-histone substrates.
(2) Small-molecule acetylation branches
Certain small-molecule metabolites can also undergo acetylation, thereby altering their activity, solubility, and metabolic fate. Thus, in pathway analysis, acetyl-group consumption should not be restricted solely to the protein-modification level.
4. Deacetylation Nodes
4.1 HDAC family
(1) Zn2+-dependent deacetylation systems
The HDAC family removes acetyl groups from lysine residues on proteins through hydrolytic reactions and is a major determinant of acetylation homeostasis in nuclear and cytosolic proteins. Changes in their expression and activity can directly affect the duration and magnitude of acetylation signaling.
(2) The reverse interpretive dimension of acetylation phenotypes
In studies of acetyl-group metabolism, a decrease in acetylation level does not necessarily arise from insufficient donor supply; it may also result from increased HDAC activity. Therefore, deacetylation nodes must be analyzed in parallel with donor-generation nodes.
4.2 Sirtuin family
(1) NAD+-dependent deacetylation links energy status to acetylation control
The Sirtuin family requires NAD+ to drive deacetylation reactions, and its activity is therefore tightly linked to redox state, mitochondrial function, and cellular energy balance. This feature makes Sirtuins an important node connecting metabolic status with acetylation output.
(2) Compartmental distribution and functional stratification
Distinct Sirtuin family members localized in the nucleus, cytosol, and mitochondria participate respectively in chromatin regulation, signaling-protein modification, and deacetylation of mitochondrial metabolic enzymes. Accordingly, research design should select the relevant deacetylation node on the basis of compartmental context.
5. Strategies for Pathway Analysis
5.1 Determination of acetyl-group origin
(1) Distinguishing the relative contribution of multiple sources
An increase in total acetyl-CoA does not directly identify its origin. Substrate deprivation, stable-isotope tracing, and key-enzyme inhibition strategies are required to distinguish the relative contributions of glucose, fatty acids, acetate, or ketone bodies to the acetyl pool.
(2) Nonequivalence between source and output layer
Mitochondria-derived acetyl groups are more strongly associated with energy metabolism and local protein acetylation, whereas cytosolic/nuclear acetyl groups more readily affect lipid synthesis and histone acetylation. Therefore, source determination must be extended further to analysis of downstream destination.
5.2 Analysis of acetyl-group fate
(1) Synthetic-metabolism-prioritized consumption pathways
Fatty acid, cholesterol, and isoprenoid synthesis all consume acetyl groups. Therefore, an increase in acetyl-CoA does not necessarily correspond first to enhanced acetylation; it may instead be preferentially consumed by anabolic pathways.
(2) Protein-modification output pathways
Histones, transcription factors, and multiple metabolic enzymes can all accept acetyl-group modification. Therefore, pathway studies must simultaneously examine donor levels, acetyltransferase activity, and target-protein acetylation states in order to establish a complete flux-to-modification relationship.
Table 2. Major analytical dimensions in acetyl-group metabolic pathway analysis
Analytical Dimension | Main Nodes | Main Readouts | Questions Addressed |
Source determination | PDH, ACLY, ACSS, CPT, ketone-body-metabolism enzymes, PTA | Isotope tracing, acetyl-CoA abundance, acetyl-phosphate changes | Where do the acetyl groups come from |
Compartmental supply | Mitochondria, cytosol, nucleus | Compartment-specific metabolites, compartment-specific enzyme activity | Where are acetyl groups distributed |
Modification writing | KAT, NAT, etc. | Protein acetylation level, substrate specificity | How do acetyl groups enter the functional layer |
Modification erasure | HDAC, Sirtuin | Deacetylation rate, NAD+ dependence | How is acetylation reversed |
Functional output | Metabolic enzymes, histones, transcription factors | Pathway flux, epigenetic state, phenotype | What consequences do acetyl-group changes produce |
6. Design of In Vitro Enzymology Studies
6.1 Studies of donor-forming enzymes
(1) Distinguishing upstream substrates from direct donors
For targets such as PDH, ACLY, ACSS2, and PTA, the principal focus is generation and interconversion of acetyl-group donors or related high-energy intermediates, rather than acetyl-group transfer itself. Therefore, in vitro studies should clearly distinguish whether the analysis concerns donor-formation efficiency or downstream acetylation output.
(2) Determinative role of cofactor systems
CoA, ATP, NAD+, Mg2+, and inorganic phosphate all affect the reaction efficiency of donor-forming enzymes. If cofactor composition is ignored, system limitations can easily be misinterpreted as enzyme-specific differences.
6.2 Studies of acetyltransferases
(1) Synchronous standardization of donor and acceptor substrates
Studies of acetyltransferases require simultaneous control of donor concentration, acceptor-peptide structure, reaction time, and ionic environment in order to distinguish differences in substrate binding from differences in catalytic efficiency.
(2) Kinetic parameters take priority over endpoint readouts
Measurement of endpoint acetylation alone cannot distinguish between whether modification occurred and how efficient the modification process was. Therefore, in in vitro enzymology, analysis should incorporate Km, kcat, competitive inhibition, and substrate-preference parameters.
6.3 Studies of deacetylases
(1) Enzyme-type differences and system configuration
HDAC studies must pay attention to Zn2+-dependent conditions, whereas Sirtuin studies must focus on controlling NAD+ concentration and redox background. These two classes of deacetylases should not be interpreted under a single unified set of conditions.
(2) Substrate level and the limits of extrapolation
Rates and selectivity conclusions derived from short peptide substrates, full-length protein substrates, or chromatin-like substrates are not equivalent. Therefore, substrate level should be matched to the research question.
Table 3. Common design modules in in vitro enzymology studies related to acetyl-group metabolism
Research Target | Core Substrates | Key Cofactors / Donors | Main Readouts | Questions Addressed |
Donor-forming enzymes such as PDH / ACLY / ACSS2 / PTA | Pyruvate, citrate, acetate, acetyl-CoA, inorganic phosphate | CoA, ATP, NAD+, etc. | Acetyl-CoA / acetyl-phosphate generation, substrate consumption | Analysis of acetyl-group origin and intermediate interconversion |
Acetyltransferases such as KAT / NAT | Acetyl-CoA + protein / peptide substrates | Acetyl-CoA | Acetylation level, kinetic parameters | Target specificity and catalytic efficiency |
Deacetylases such as HDAC / Sirtuin | Acetylated peptides / proteins | Zn2+ or NAD+ | Deacetylation rate, product release | Acetylation reversibility and homeostatic regulation |
Multi-enzyme reconstitution systems | Multiple serial substrates | Multi-enzyme and cofactor combinations | Carbon-flux partitioning and intermediate changes | Pathway coupling and rate-limiting-node analysis |
7. Representative Research Scenarios
7.1 Tumor metabolic reprogramming
(1) Rearrangement of acetyl-group supply and epigenetic remodeling
Tumor cells often enhance ACLY, ACSS2, or fatty acid oxidation pathways to increase cytosolic and nuclear acetyl-CoA supply, thereby supporting lipid synthesis and histone acetylation.
(2) Coordinated regulation of donor formation and deacetylation
Enhanced acetyl-group input and altered HDAC/Sirtuin activity often coexist. The former determines modification-writing capacity, whereas the latter determines the strength of modification erasure. Accordingly, both should be analyzed together.
7.2 Immunometabolism research
(1) Inflammatory transcriptional programs and acetyl-group supply
During immune-cell activation, changes in acetyl-CoA levels can directly affect the histone-acetylation state of inflammation-related genes, thereby altering the amplitude of the transcriptional response.
(2) Deacetylation networks in effector differentiation
Sirtuin-mediated deacetylation is closely linked to oxidative metabolism, oxidative stress, and immune-cell differentiation states, and therefore holds important significance in immunometabolism research.
7.3 Mitochondrial function research
(1) Joint control by local donor supply and local deacetylation
The acetylation state of mitochondrial metabolic enzymes can affect oxidative phosphorylation, fatty acid oxidation, and stress defense. Accordingly, both donor origin and local deacetylation capacity must be analyzed together.
(2) Functional decline caused by disrupted acetylation homeostasis
Restricted donor generation, decreased NAD+, or insufficient Sirtuin activity may all lead to abnormal mitochondrial acetylation profiles and consequent functional impairment.
8. Research Products Relevant to Studies of Acetyl-Group Metabolism
8.1 Basic reaction and regulatory reagents
Table 4. Basic reaction and regulatory reagents in acetyl-group metabolic pathway analysis
Name | CAS No. | Experimental Stage | Key Use | Use Notes |
Glacial acetic acid | Studies of acetate sources | Used as an acetate substrate source for ACSS-related reactivation and acetate-supplementation model construction | Suitable for studies of acetate-dependent acetyl-group generation | |
Sodium acetate | Studies of acetate sources | Used as a milder acetate-supplying form for acetate reactivation and feeding experiments | Suitable for acetate supplementation in cellular and in vitro systems | |
Pyruvic acid | Studies of glucose-derived acetyl groups | Used for reconstruction of the PDH pathway and analysis of glucose-derived carbon entry into acetyl-CoA | Suitable for in vitro enzymology and substrate-competition studies | |
Sodium pyruvate | Studies of glucose-derived acetyl groups | Used as a stable substrate form in PDH-related in vitro systems and cellular supplementation studies | Suitable for analysis of glucose-derived acetyl-group formation | |
Citric acid | Studies of cytosolic acetyl-group generation | Used as an ACLY substrate for analysis of citrate cleavage and cytosolic/nuclear acetyl-group supply | Suitable for construction of ACLY reaction systems | |
Trisodium citrate dihydrate | Studies of cytosolic acetyl-group generation | Used as a more strongly buffered citrate source in cellular and in vitro supplementation systems | Suitable for simulation of cytosolic acetyl-group supply | |
ATP disodium salt | Studies of donor-forming enzymes | Provides the energy substrate for ATP-dependent reactions such as ACSS | Commonly used together with Mg2+ | |
NAD+ | Studies of donor formation and deacetylation | Used in PDH and Sirtuin systems to connect redox state with deacetylation reactions | Suitable for metabolism-acetylation coupling studies | |
NADH disodium salt | Studies of donor formation | Used to analyze redox feedback and reaction balance in reactions such as PDH | Suitable for studies of regulation by reduced states | |
Thiamine pyrophosphate chloride | Studies of the PDH system | Used as an important coenzyme in PDH-related reactions for full reconstruction of the glucose-derived acetyl-entry system | Suitable for in vitro PDH activity assays | |
Magnesium chloride | Enzymology-system optimization | Provides ionic support for ATP-dependent reactions and multiple enzymatic systems | Commonly used in optimization of ACSS and related systems | |
Sodium dihydrogen phosphate | Studies of PTA and buffer systems | Provides an inorganic phosphate source and constructs phosphate buffer systems | Suitable for PTA- and acetyl-phosphate-related studies | |
Disodium hydrogen phosphate | Studies of PTA and buffer systems | Adjusts phosphate-buffer conditions and participates in inorganic phosphate supply | Suitable for screening in vitro PTA reaction conditions | |
Tris | Buffer-system construction | Provides a neutral to mildly alkaline enzymatic reaction environment | Suitable for most in vitro enzymatic reaction systems | |
HEPES | Buffer-system construction | Used in in vitro enzymology under mild buffering conditions | Suitable for systems requiring relatively high protein stability | |
Nicotinamide | Deacetylation-regulation studies | Used in Sirtuin-related intervention and deacetylation-mechanism analysis | Suitable for studies of NAD+-dependent deacetylation | |
Sodium butyrate | Acetylation-regulation studies | Commonly used as an experimental intervention to increase intracellular acetylation levels | Suitable for HDAC-related functional studies | |
Trichostatin A | Studies of deacetylation inhibition | Used as a classical HDAC inhibitor to elevate acetylation levels and analyze the contribution of deacetylation | Suitable for HDAC functional validation | |
Vorinostat | Studies of deacetylation inhibition | Used for HDAC inhibition and acetylation-enhancement experiments | Suitable for studies of epigenetic-acetylation intervention | |
Resveratrol | Deacetylation-regulation studies | Commonly used in Sirtuin-related regulatory studies | Suitable for analysis of coupling between metabolic state and deacetylation | |
L-Carnitine | Studies of lipid-derived acetyl groups | Used in research related to fatty-acid entry into mitochondria and auxiliary analysis of lipid-derived acetyl-group supply | Suitable for construction of fatty-acid-oxidation models | |
L-Acetylcarnitine hydrochloride | Studies of acetyl-group transport | Used to analyze acetyl-group transport and acetyl-group storage forms | Suitable for studies of mitochondrial-cytosolic acetyl exchange | |
Palmitic acid | Studies of lipid-derived acetyl groups | Used as a long-chain fatty-acid substrate in studies of acetyl-group generation through fatty-acid oxidation | Suitable for establishment of lipid-derived carbon-supply models | |
Sodium beta-hydroxybutyrate | Studies of ketone-body-derived acetyl groups | Used in studies of ketone-body metabolism and alternative acetyl-group sources | Suitable for starvation or metabolic-reprogramming models | |
Sodium dichloroacetate | Studies of PDH regulation | Commonly used to promote PDH flux and analyze regulation of the glucose-derived acetyl entry point | Suitable for experiments enhancing glucose-derived carbon supply | |
Sodium 4-phenylbutyrate | Acetylation-regulation studies | Can be used for intervention in acetylation state and analysis of cellular metabolic responses | Suitable for studies of metabolism-epigenetic coupling |
8.2 Functional proteins and molecular tools
Table 5. Functional proteins and molecular tools in enzymology studies of acetyl-group metabolism
Catalog No. | Name | Grade and Purity | Experimental Stage | Key Use | Use Notes |
Pyruvate Dehydrogenase (PDH) Activity Assay Kit (DCPIP, Micro Method) | BioReagent | Study of glucose-derived acetyl entry | Used to detect changes in PDH activity and evaluate the capacity for conversion of pyruvate into acetyl-CoA | Suitable for in vitro or tissue-sample analysis under conditions of altered glucose-derived carbon supply, PDH inhibition, or PDH activation | |
ATP Citrate Lyase (ACL) Activity Assay Kit (UV Micro Method) | BioReagent | Study of cytosolic acetyl-group supply | Used to detect ACLY activity and analyze the capacity of citrate cleavage to supply cytosolic/nuclear acetyl groups | Suitable for study designs with limited sample amounts or requiring high-throughput comparison | |
ATP Citrate Lyase (ACL) Activity Assay Kit (UV Colorimetric Method) | BioReagent | Study of cytosolic acetyl-group supply | Used for quantitative evaluation of ACLY catalytic efficiency and its impact on acetyl-donor formation | Suitable for routine enzyme-activity measurement and comparison among treatment groups | |
BMS 303141 | ≥98% | ACLY functional-intervention studies | Used to reduce cytosolic/nuclear acetyl-CoA supply by inhibiting ACLY and to analyze the dependence of lipid synthesis and acetylation writing on ACLY | Suitable for combined use with acetylation readouts, lipid-synthesis indices, and histone-acetylation assays | |
SB 204990 | ≥98% (HPLC) | ACLY functional-intervention studies | Used to validate the role of ACLY in acetyl-group source partitioning and as a pathway-intervention tool | Suitable for combined use with acetate supplementation, ACSS2 intervention, or isotope-tracing strategies | |
ACSS2 Human Pre-designed siRNA Set A | — | Study of acetate reactivation | Used to knock down ACSS2 and validate the contribution of acetate replenishment to conversion into acetyl-CoA and the resulting acetylation phenotype | Suitable for cell-level causal validation and studies of metabolic reprogramming | |
ACSS2-IN-1 | — | Acetate-reactivation intervention studies | Used to inhibit ACSS2 activity and analyze the functional contribution of acetate-derived acetyl-group input | Suitable for combined use with acetate-supplementation models and nuclear-acetylation readouts | |
Recombinant ACSS2 Antibody | Knockdown-validated | ACSS2 expression validation | Used to detect changes in ACSS2 expression and validate siRNA- or pharmacology-based interventions | Suitable for Western blot, immunoblotting, or node-expression analysis | |
Phosphate acetyltransferase | — | Study of the acetyl-phosphate bypass | Used to reconstruct the acetyl-CoA-acetyl-phosphate interconversion system and analyze acetate-metabolism branch pathways and acetyl flux | More suitable for microbial systems or in vitro reconstitution than for classical mammalian acetylation models | |
Recombinant KAT2A/GCN5 Antibody | Recombinant, ExactAb™, validated, see COA | Study of acetyl-transfer nodes | Used to detect KAT2A/GCN5 expression and analyze changes in classical lysine-acetyltransferase systems | Suitable for histone-acetylation-writing studies and transcription-regulation-related analysis | |
Recombinant KAT2B/PCAF Antibody | Recombinant, ExactAb™, validated, knockdown-validated, see COA | Study of acetyl-transfer nodes | Used to analyze changes in PCAF-mediated acetylation writing and its relationship to metabolic-donor changes | Suitable for acetyltransferase-expression validation and post-knockdown effect analysis | |
Recombinant KAT8/MYST1/MOF Antibody | ExactAb™, Validated, recombinant, 2.0 mg/mL | Study of acetyl-transfer nodes | Used to detect the KAT8/MOF acetyltransferase system and extend the scope of nuclear-acetylation research | Suitable for epigenetic regulation and chromatin-related acetylation studies | |
Human K-acetyltransferase 5 (KAT5) ELISA Kit | BioReagent | Detection of acetyltransferase level | Used to detect changes in KAT5 level and evaluate the regulatory state of the acetyl-writing layer | Suitable for quantitative analysis of pathway nodes in human samples | |
script | ≥97% | Studies of deacetylation inhibition | Used to inhibit HDAC activity, increase acetylation level, and validate the contribution of deacetylation | Suitable for establishment of acetylation-enhanced control groups | |
Pracinostat (SB939) | Moligand™, ≥98% | Deacetylation-intervention studies | Used for broad-spectrum HDAC inhibition to analyze the impact of deacetylation networks on acetylation homeostasis | Suitable for epigenetic-regulation and tumor-metabolism studies | |
RGFP966 | ≥98% | HDAC isoform-function studies | Used for selective inhibition of HDAC3 and analysis of the effects of specific deacetylation nodes on metabolism and transcription | Suitable for studies of the specific role of HDAC3 in acetylation homeostasis | |
Romidepsin (FK228, Depsipeptide) | Moligand™, ≥98% | HDAC1/2 functional-intervention studies | Used to analyze the regulatory effects of HDAC1/2 on nuclear acetylation levels and transcriptional states | Suitable for combined use with histone-acetylation readouts | |
Human Histone Deacetylase 1 (HDAC1) ELISA Kit | BioReagent | HDAC-node level detection | Used to detect HDAC1 levels and assist in assessing changes in deacetylation pathways | Suitable for node quantification in human samples | |
Human Histone Deacetylase 3 (HDAC3) ELISA Kit | BioReagent | HDAC-node level detection | Used to detect changes in HDAC3 level and, in combination with HDAC3 inhibitors, evaluate its functional contribution | Suitable for metabolism-epigenetic coupling studies | |
Human Histone Deacetylase 6 (HDAC6) ELISA Kit | BioReagent | HDAC-node level detection | Used to analyze changes in HDAC6 and expand research on cytosolic protein deacetylation | Suitable for studies of the cytoskeleton, stress responses, and cytosolic protein modification | |
Anti-HDAC1 antibody | ExactAb™, Validated, Recombinant, High performance, 0.125 mg/mL | HDAC expression validation | Used to detect HDAC1 protein levels and validate intervention effects | Suitable for Western blot or immunodetection | |
Recombinant HDAC3 Antibody | Recombinant, ExactAb™, validated, knockdown-validated, see COA | HDAC expression validation | Used to detect HDAC3 expression and support node confirmation after knockdown or inhibition experiments | Suitable for functional-validation studies | |
Recombinant HDAC6 Antibody | Recombinant, ExactAb™, knockdown-validated, validated, high performance, see COA | HDAC expression validation | Used to analyze changes in HDAC6 expression and its impact on acetylation homeostasis | Suitable for studies of cytosolic protein deacetylation | |
Recombinant Human HDAC1 Protein | Carrier-free, His-tagged, ≥85% (SDS-PAGE), see COA | In vitro deacetylase enzymology studies | Used to establish in vitro HDAC1 reaction systems and carry out inhibitor screening and enzymatic-parameter analysis | Suitable for deacetylation-substrate reactions and inhibitor evaluation | |
Recombinant Human HDAC3 Protein | Carrier-free, GST-tagged, His-tagged, ≥75% (SDS-PAGE), see COA | In vitro deacetylase enzymology studies | Used to reconstruct in vitro HDAC3 systems and analyze isoform-specific inhibitory effects | Suitable for validation in combination with tools such as RGFP966 | |
Cambinol | ≥98% | Sirtuin-intervention studies | Used to inhibit SIRT1/2 and analyze the contribution of NAD+-dependent deacetylation to acetylation homeostasis | Suitable for studies of coupling between energy state and deacetylation | |
Recombinant Human Sirtuin 1/SIRT1 Protein | Carrier-free, His-tagged, ≥65% (SDS-PAGE), see COA | In vitro Sirtuin enzymology studies | Used to establish in vitro SIRT1 deacetylation reaction systems and analyze NAD+-dependent catalytic characteristics | Interpretation should consider the effects of NAD+ concentration and substrate type | |
Recombinant SIRT1 Antibody | Recombinant, ExactAb™, validated, see COA | SIRT1 expression validation | Used to detect SIRT1 protein levels and support analysis of the relationship between metabolic state and deacetylation | Suitable for node-expression analysis and post-intervention validation | |
SRT1720 HCl | ≥98% | SIRT1 functional-activation studies | Used to enhance SIRT1-related deacetylation pathways and analyze regulatory effects of energy-state changes | Suitable for combined experimental design with NAD+-related condition changes | |
Salermide | ≥98% (HPLC) | Sirtuin-inhibition studies | Used for pharmacological inhibition of SIRT1/2 and evaluation of their effects on acetylation and metabolic phenotypes | Suitable for use as a contrast with SIRT1 activators | |
Human Sirtuin 1 (SIRT1) ELISA Kit | BioReagent | SIRT1 level detection | Used to detect changes in SIRT1 level and assist in interpreting NAD+-dependent deacetylation capacity | Suitable for node quantification in human samples | |
Recombinant SIRT3 Antibody | Knockdown-validated | SIRT3 expression validation | Used to analyze mitochondrial SIRT3 expression and its role in local deacetylation | Suitable for studies of mitochondrial function and acetylation homeostasis | |
Human Sirtuin3 (SIRT3) ELISA Kit | BioReagent | SIRT3 level detection | Used to detect SIRT3 levels and evaluate the state of mitochondrial deacetylation nodes | Suitable for studies of mitochondrial-protein acetylation | |
Human Acetylated Histone H3 (AH3) ELISA Kit | BioReagent | Acetylation-phenotype readout | Used to detect histone H3 acetylation level as a terminal readout of acetyl-group writing and erasure effects | Suitable for validation of epigenetic changes after KAT, HDAC, and Sirtuin intervention |
The key to research on acetyl-group metabolic enzymes lies in incorporating donor generation, compartmental distribution, modification writing, and modification removal into a unified analytical framework. Only when enzymatic behavior is interpreted within a continuous pathway context can the functional positioning of acetyl-group metabolism in pathway analysis and in vitro enzymology be accurately defined.
