β-hydroxybutyryl-HIST1H3A (K9) Antibody
Description
Introduction to β-hydroxybutyryl-HIST1H3A (K9) Antibody
The β-hydroxybutyryl-HIST1H3A (K9) antibody is a specialized immunological tool designed to detect lysine β-hydroxybutyrylation (Kbhb) at position 9 on histone H3.1 (HIST1H3A). This post-translational modification (PTM) links cellular metabolism to epigenetic regulation, as β-hydroxybutyrate (BHB)-derived Kbhb marks are enriched during metabolic states like fasting or ketosis . The antibody (Catalog #CAC11531) is a rabbit polyclonal reagent validated for research applications including chromatin immunoprecipitation (ChIP), Western blot (WB), and immunocytochemistry (ICC) .
Key discoveries about H3K9bhb:
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Metabolic Sensitivity: H3K9bhb levels increase dose-dependently with extracellular BHB concentration, demonstrating direct coupling between ketone body availability and epigenetic marking .
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Genomic Localization: In fasting mice, H3K9bhb accumulates at promoters of genes involved in PPAR signaling, redox balance, and amino acid catabolism .
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Cross-Reactivity Concerns: Studies reveal this antibody non-specifically recognizes acetylated or butyrylated histones in cells treated with histone deacetylase inhibitors (e.g., TSA) or butyrate .
Applications in Scientific Research
Antibody Characteristics:
| Parameter | Detail |
|---|---|
| Host Species | Rabbit |
| Immunogen | Synthetic peptide (β-hydroxybutyryl-Lys9 on human H3.1) |
| Cross-Reactivity | Human, Mouse |
| Storage | 2–8°C (short-term); -20°C (long-term) |
Experimental Validation:
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Specificity: Mass spectrometry confirmed enrichment of H3K9bhb peptides in BHB-treated HEK293 cells, though 13.99% of immunoprecipitated peptides carried this modification .
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Dose Response: 10 mM BHB increased H3K9bhb signal by 4.7-fold compared to controls in Western blots .
Challenges and Considerations in Antibody Specificity
Critical limitations identified in peer-reviewed studies:
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Non-Specific Recognition: The antibody detects acetylated H3K9 in TSA-treated cells and butyrylated histones in butyrate-exposed samples .
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Context-Dependent Signals: Immunoblot signals vary significantly across cell types due to competing PTMs (e.g., acetylation) .
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Validation Requirements: Researchers must include deacetylase inhibitor controls and confirm findings with mass spectrometry .
Future Directions and Research Implications
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Therapeutic Potential: H3K9bhb correlates with neuroprotective gene expression in fasting models, suggesting roles in aging or metabolic disease .
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Technical Improvements: Development of monoclonal antibodies or epitope-specific nanobodies could resolve specificity issues .
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Mechanistic Studies: Unresolved questions include writers/erasers of Kbhb and its crosstalk with other histone marks like acetylation .
Product Specs
Constituents: 50% Glycerol, 0.01M PBS, pH 7.4
The Anti-beta-hydroxybutyryl-HIST1H3A (K9) antibody (CSB-PA010418OA09bhbHU) from CUSABIO is a high-quality polyclonal antibody validated for use in ELISA, Western blotting, Immunocytochemistry, and Chromatin Immunoprecipitation (ChIP) applications. The peptide sequence used for the immunogen was derived from the region surrounding the β-hydroxybutyryl-Lys (9) modification on Human Histone H3.1. This antibody has undergone antigen affinity purification and is capable of recognizing HIST1H3A modified at the Lys9 residue.
β-hydroxybutyryl-HIST1H3A (K9) is a modified form of the histone H3 protein. Histone H3 is a fundamental component of the nucleosome, the basic structural unit of chromatin. This modified form plays a significant role in regulating gene expression in response to alterations in cellular metabolism, particularly during periods of fasting or ketosis.
Target Background
- Research suggests that epigenetic regulation in cancer may be mediated by the induction of E3 ubiquitin ligase NEDD4-dependent histone H3 ubiquitination. PMID: 28300060
- The identification of increased expression of H3K27me3 during a patient's clinical course can be a useful indicator for determining whether tumors are heterochronous. PMID: 29482987
- Recent studies have shown that JMJD5, a Jumonji C (JmjC) domain-containing protein, functions as a Cathepsin L-type protease that mediates histone H3 N-tail proteolytic cleavage under stress conditions, triggering a DNA damage response. PMID: 28982940
- Data suggests that the Ki-67 antigen proliferative index has significant limitations and that phosphohistone H3 (PHH3) may serve as a more reliable alternative proliferative marker. PMID: 29040195
- Findings indicate that cytokine-induced histone 3 lysine 27 trimethylation stabilizes gene silencing in macrophages. PMID: 27653678
- This data reveals that, in the early developing human brain, HIST1H3B constitutes the largest proportion of H3.1 transcripts among H3.1 isoforms. PMID: 27251074
- This series of 47 diffuse midline gliomas showed that the histone H3-K27M mutation was mutually exclusive with IDH1-R132H mutation and EGFR amplification, rarely co-occurred with BRAF-V600E mutation, and was commonly associated with p53 overexpression, ATRX loss, and monosomy 10. PMID: 26517431
- Research shows that histone chaperone HIRA co-localizes with viral genomes, binds to incoming viral, and deposits histone H3.3 onto these. PMID: 28981850
- These experiments demonstrated that PHF13 binds specifically to DNA and to two types of histone H3 methyl tags (lysine 4-tri-methyl or lysine 4-di-methyl) where it functions as a transcriptional co-regulator. PMID: 27223324
- Hemi-methylated CpGs DNA recognition activates UHRF1 ubiquitylation towards multiple lysines on the H3 tail adjacent to the UHRF1 histone-binding site. PMID: 27595565
- This study provides, for the first time, a detailed description of the MR imaging features of pediatric diffuse midline gliomas with histone H3 K27M mutation. PMID: 28183840
- Approximately 30% of pediatric high-grade gliomas (pedHGG), including GBM and DIPG, harbor a lysine 27 mutation (K27M) in histone 3.3 (H3.3), which is correlated with poor prognosis and was shown to influence EZH2 function. PMID: 27135271
- The H3F3A K27M mutation in adult cerebellar HGG is not an infrequent occurrence. PMID: 28547652
- Research indicates that lysyl oxidase-like 2 (LOXL2) is a histone modifier enzyme that removes trimethylated lysine 4 (K4) in histone H3 (H3K4me3) through an amino-oxidase reaction. PMID: 27735137
- Histone H3 lysine 9 (H3K9) acetylation was most prevalent when the Dbf4 transcription level was highest, whereas the H3K9me3 level was greatest during and just after replication. PMID: 27341472
- The SPOP-containing complex regulates SETD2 stability and H3K36me3-coupled alternative splicing. PMID: 27614073
- Data suggest that binding of the helical tail of histone 3 (H3) with PHD ('plant homeodomain') fingers of BAZ2A or BAZ2B (bromodomain adjacent to zinc finger domain 2A or 2B) requires molecular recognition of secondary structure motifs within the H3 tail and could represent an additional layer of regulation in epigenetic processes. PMID: 28341809
- These results demonstrate a novel mechanism by which Kdm4d regulates DNA replication by reducing the H3K9me3 level to facilitate the formation of the preinitiation complex. PMID: 27679476
- Histone H3 modifications caused by traffic-derived airborne particulate matter exposures in leukocytes. PMID: 27918982
- A key role of persistent histone H3 serine 10 or serine 28 phosphorylation in chemical carcinogenesis through regulating gene transcription of DNA damage response genes. PMID: 27996159
- hTERT promoter mutations are frequent in medulloblastoma and are associated with older patients, prone to recurrence and located in the right cerebellar hemisphere. On the other hand, histone 3 mutations do not seem to be present in medulloblastoma. PMID: 27694758
- AS1eRNA-driven DNA looping and activating histone modifications promote the expression of DHRS4-AS1 to economically control the DHRS4 gene cluster. PMID: 26864944
- Data suggest that nuclear antigen Sp100C is a multifaceted histone H3 methylation and phosphorylation sensor. PMID: 27129259
- The authors propose that histone H3 threonine 118 phosphorylation via Aurora-A alters the chromatin structure during specific phases of mitosis to promote timely condensin I and cohesin disassociation, which is essential for effective chromosome segregation. PMID: 26878753
- Hemi-methylated DNA opens a closed conformation of UHRF1 to facilitate its H3 histone recognition. PMID: 27045799
- Functional importance of H3K9me3 in hypoxia, apoptosis and repression of APAK. PMID: 25961932
- Taken together, the authors verified that histone H3 is a real substrate for GzmA in vivo in the Raji cells treated by staurosporin. PMID: 26032366
- We conclude that circulating H3 levels correlate with mortality in sepsis patients and inversely correlate with antithrombin levels and platelet counts. PMID: 26232351
- Data show that double mutations on the residues in the interface (L325A/D328A) decreases the histone H3 H3K4me2/3 demethylation activity of lysine (K)-specific demethylase 5B (KDM5B). PMID: 24952722
- Data indicate that minichromosome maintenance protein 2 (MCM2) binding is not required for incorporation of histone H3.1-H4 into chromatin but is important for stability of H3.1-H4. PMID: 26167883
- Data suggest that histone H3 lysine methylation (H3K4me3) serves a crucial mechanistic role in leukemia stem cell (LSC) maintenance. PMID: 26190263
- PIP5K1A modulates ribosomal RNA gene silencing through its interaction with histone H3 lysine 9 trimethylation and heterochromatin protein HP1-alpha. PMID: 26157143
- Data indicate that lower-resolution mass spectrometry instruments can be utilized for histone post-translational modifications (PTMs) analysis. PMID: 25325711
- Data indicate that inhibition of lysine-specific demethylase 1 activity prevented IL-1beta-induced histone H3 lysine 9 (H3K9) demethylation at the microsomal prostaglandin E synthase 1 (mPGES-1) promoter. PMID: 24886859
- The authors report that de novo CENP-A assembly and kinetochore formation on human centromeric alphoid DNA arrays is regulated by a histone H3K9 acetyl/methyl balance. PMID: 22473132
Q&A
What is β-hydroxybutyryl-HIST1H3A (K9) Antibody and what applications has it been validated for?
β-hydroxybutyryl-HIST1H3A (K9) Antibody is a polyclonal antibody that specifically recognizes the β-hydroxybutyryl modification at lysine 9 of histone H3.1 (HIST1H3A). According to product information, this antibody has been validated for multiple applications including:
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Enzyme immunoassay (EIA)
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Immunoassay
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Chromatin immunoprecipitation (ChIP)
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Enzyme-linked immunosorbent assay (ELISA)
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Immunocytochemistry (ICC)
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Immunoprecipitation (IP)
These applications make it a versatile tool for investigating histone β-hydroxybutyrylation in various experimental contexts.
How does histone lysine β-hydroxybutyrylation (Kbhb) differ from other histone modifications?
Histone lysine β-hydroxybutyrylation (Kbhb) represents a novel class of histone post-translational modification that differs from more well-characterized modifications in several key aspects:
| Feature | Kbhb | Acetylation | Methylation |
|---|---|---|---|
| Metabolic origin | Derived from β-hydroxybutyrate, which increases during starvation, intense exercise, and diabetic ketoacidosis | Derived from acetyl-CoA | Derived from S-adenosylmethionine |
| Physiological context | Elevated during metabolic stress (starvation, ketosis) | General cellular process | General cellular process |
| Function | Gene regulation in response to metabolic state | Gene activation | Gene activation or repression (depending on site) |
| Writer enzymes | p300 | HATs (including p300) | HMTs |
| Eraser enzymes | HDAC1, HDAC2, SIRT1, SIRT2 | HDACs, SIRTs | KDMs |
Unlike acetylation, which is predominantly associated with gene activation, Kbhb appears to be a mechanism by which ketone bodies specifically regulate cellular physiology through changes in gene expression .
What experimental methods can be used to detect and quantify histone β-hydroxybutyrylation?
Multiple methodologies can be employed to study histone β-hydroxybutyrylation:
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Antibody-based methods:
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Mass spectrometry-based methods:
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Enrichment strategies:
When designing experiments, it's important to include appropriate controls to distinguish β-hydroxybutyrylation from other acylation modifications.
What is the relationship between cellular β-hydroxybutyrate levels and histone β-hydroxybutyrylation?
Research demonstrates a direct relationship between cellular β-hydroxybutyrate levels and histone β-hydroxybutyrylation:
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β-hydroxybutyrate can be converted into β-hydroxybutyryl-CoA in cells, which serves as the cofactor for lysine β-hydroxybutyrylation
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Treatment of cells with sodium β-hydroxybutyrate induces histone Kbhb levels in a dose-dependent manner
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Histone Kbhb levels increase under physiological conditions that elevate β-hydroxybutyrate, including:
This relationship establishes histone β-hydroxybutyrylation as a mechanism through which metabolic state can directly influence gene expression patterns through epigenetic regulation.
What are the regulatory enzymes ("writers" and "erasers") for histone lysine β-hydroxybutyrylation?
Based on current research, the following enzymes regulate histone lysine β-hydroxybutyrylation:
Writers:
Erasers:
Several histone deacetylases (HDACs) demonstrate de-β-hydroxybutyrylation activity:
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HDAC1, HDAC2, and HDAC3 (Class I HDACs)
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SIRT1 and SIRT2 (Class III HDACs)
In vitro screening of 18 recombinant HDACs (HDAC1-11 and SIRT1-7) showed that these five enzymes exhibited notable de-Kbhb activity toward core histones. This was confirmed using Kbhb-containing histone peptides as substrates followed by HPLC assay.
Cellular validation showed:
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Simultaneous knockdown of HDAC1 and HDAC2 increased levels of Kbhb in both HEK293 and HeLa cells
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Treatment with MS275 (a selective HDAC1/2/3 inhibitor) increased multiple Kbhb site signals in a dose-dependent manner
This regulatory system allows dynamic control of histone β-hydroxybutyrylation levels in response to changing cellular conditions.
How does ENL protein function as a "reader" of histone β-hydroxybutyrylation to modulate gene expression?
ENL (Eleven-nineteen leukemia protein) functions as a "reader" of histone β-hydroxybutyrylation marks. Research using histone peptide probes with and without β-hydroxybutyrylation modification has identified ENL as a protein that specifically recognizes and binds to β-hydroxybutyrylated histones.
Experimental approaches to study this interaction include:
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Using functionalized probes (H3K9bhb and unmodified H3K9) incubated with nuclear extracts
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UV crosslinking at 365 nm to capture binding proteins
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Washing and trypsin digestion followed by HPLC-MS/MS analysis to identify binding partners
The identification of ENL as a reader of histone β-hydroxybutyrylation provides a mechanistic link between this metabolic-responsive histone modification and subsequent changes in gene expression. ENL is known to be involved in transcriptional elongation, suggesting that β-hydroxybutyrylation may influence this process.
What is the functional significance of H3K9bhb compared to other histone modifications at the same residue (H3K9ac, H3K9me3)?
H3K9 is a critical residue that can undergo multiple modifications with distinct functional outcomes:
| Modification | Functional Association | Response to β-hydroxybutyrate | Relationship to Gene Expression |
|---|---|---|---|
| H3K9bhb | Active gene expression, metabolic pathways | Induced by β-hydroxybutyrate in a dose-dependent manner | Associated with active genes during metabolic stress |
| H3K9ac | Active gene expression | Shows marginal changes with β-hydroxybutyrate treatment | Generally associated with euchromatin |
| H3K9me3 | Heterochromatin, gene silencing | Not directly regulated by β-hydroxybutyrate | Usually marks silent genes and heterochromatin |
Intriguingly, research has shown that β-hydroxybutyrate treatment increases H3K9bhb levels while having minimal effect on H3K9ac levels, suggesting specific regulatory mechanisms for these distinct modifications at the same residue .
In the context of class switch recombination (CSR) in B cells, both H3 acetyl K9 and H3 trimethyl K9 have been found to correlate with recombining pairs of donor and recipient switch regions. This is surprising since H3 trimethyl K9 is typically associated with silent genes and heterochromatin .
These findings suggest complex interplay between different modifications at the same residue, potentially allowing for nuanced regulation of gene expression in response to various cellular signals.
How can isotopic labeling approaches be applied to study the dynamics of β-hydroxybutyrylation?
Isotopic labeling provides powerful tools for studying β-hydroxybutyrylation dynamics:
Methodology:
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Treat cells with isotopically labeled β-hydroxybutyrate (e.g., sodium [13C2]-β-hydroxybutyrate)
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Extract histones and perform trypsin digestion
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Analyze by HPLC/MS/MS to detect peptides modified by the isotopic β-hydroxybutyryl group
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Identify specific Kbhb sites through mass shift detection (+2 Da for 13C2-labeled samples)
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Compare fragmentation patterns with unlabeled controls
This approach has successfully demonstrated that:
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Sodium β-hydroxybutyrate can be converted into β-hydroxybutyryl-CoA in cells
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β-hydroxybutyryl-CoA serves as the cofactor for enzymatic lysine β-hydroxybutyrylation
Additional applications of isotopic labeling include:
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Pulse-chase experiments to determine turnover rates of Kbhb marks
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Comparative analysis of site-specific Kbhb dynamics under different physiological conditions
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Validation of writer and eraser enzyme activities in cellular contexts
What methodological approaches are recommended for validating the specificity of β-hydroxybutyryl-HIST1H3A (K9) antibodies?
Validating antibody specificity is critical for reliable research. For β-hydroxybutyryl-HIST1H3A (K9) antibodies, consider these approaches:
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Peptide competition assays:
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Pre-incubate antibody with excess synthetic β-hydroxybutyrylated and unmodified peptides
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Specificity is demonstrated if only the β-hydroxybutyrylated peptide blocks signal
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Multiple antibody validation:
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Genetic/biochemical manipulation:
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Modulate β-hydroxybutyrate levels (e.g., sodium β-hydroxybutyrate treatment)
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Manipulate writer (p300) or eraser (HDAC1/2) enzyme levels
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Confirm antibody signal changes accordingly
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Control modifications:
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Test cross-reactivity with similar acylations (acetylation, butyrylation)
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Include acetylated and unmodified histone controls in assays
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Mass spectrometry correlation:
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Confirm antibody-detected sites match MS-identified β-hydroxybutyrylation sites
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These validation steps ensure that experimental results accurately reflect the presence and dynamics of histone β-hydroxybutyrylation.
How can ChIP-seq be optimized for β-hydroxybutyryl-HIST1H3A (K9) antibodies?
Optimizing ChIP-seq for β-hydroxybutyryl-HIST1H3A (K9) antibodies requires special considerations:
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Cross-linking optimization:
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Standard formaldehyde cross-linking (1% for 10 minutes) works for most histone modifications
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Consider dual cross-linking approaches (DSG followed by formaldehyde) for improved capture
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Sonication parameters:
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Target fragment size of 200-500 bp
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Verify fragmentation efficiency by agarose gel electrophoresis
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Antibody validation for ChIP:
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Controls:
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Include input DNA control
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Use IgG negative control
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Consider ChIP for H3K9ac as a comparative modification
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Include β-hydroxybutyrate treatment conditions to demonstrate specificity
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Data analysis considerations:
This optimized approach will enable researchers to accurately map the genome-wide distribution of H3K9bhb and correlate it with gene expression patterns under various metabolic conditions.
