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AB134171

Anti-SIRT2 antibody [EPR1667]

4

(1 Review)

|

(4 Publications)

Rabbit Recombinant Monoclonal SIRT2 antibody. Suitable for WB and reacts with Human samples. Cited in 4 publications.

View Alternative Names

SIR2L, SIR2L2, SIRT2, NAD-dependent protein deacetylase sirtuin-2, NAD-dependent protein deacylase sirtuin-2, NAD-dependent protein defatty-acylase sirtuin-2, Regulatory protein SIR2 homolog 2, SIR2-like protein 2

3 Images
Western blot - Anti-SIRT2 antibody [EPR1667] (AB134171)
  • WB

Unknown

Western blot - Anti-SIRT2 antibody [EPR1667] (AB134171)

All lanes:

Western blot - Anti-SIRT2 antibody [EPR1667] (ab134171) at 1/500 dilution

Lane 1:

SKBR3 cell lysate at 10 µg

Lane 2:

SH-SY5Y cell lysate at 10 µg

Secondary

All lanes:

HRP labelled goat anti-rabbit at 1/2000 dilution

Predicted band size: 43 kDa

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Western blot - Anti-SIRT2 antibody [EPR1667] (AB134171)
  • WB

Lab

Western blot - Anti-SIRT2 antibody [EPR1667] (AB134171)

Western blot : Anti-SIRT2 antibody [EPR1667] ab134171 staining at 1/500 dilution, shown in green; Mouse anti-CANX ab238078 loading control staining at 1/20000 dilution, shown in magenta. A band was observed at 45 kDa in Wild-type MCF7 cell lysates with no signal observed at this size in SIRT2 knockout MCF7 cell line. To generate this image, samples were run on an SDS-PAGE gel then transferred onto a nitrocellulose membrane. Membranes were blocked in 3pc Milk in TBS-0.1 % Tween® 20 (TBS-T) before incubation with primary antibodies overnight at 4 °C. Blots were washed four times in TBS-T, incubated with secondary antibodies for 1 h at room temperature, washed again four times then imaged. Secondary antibodies used were Goat anti-Rabbit 800CW and Goat anti-Mouse 680RD at 1/20,000 dilution.

All lanes:

Western blot - Anti-SIRT2 antibody [EPR1667] (ab134171) at 1/500 dilution

Lane 1:

Wild-type MCF7 at 20 µg

Lane 2:

Western blot - Human SIRT2 knockout MCF7 cell line (ab289308) at 20 µg

Lane 3:

THP-1 at 20 µg

Lane 4:

HeLa at 20 µg

Lane 5:

U-2 OS at 20 µg

Secondary

All lanes:

Goat anti-Rabbit 800CW & Goat anti-Mouse 680RD at 1/20000 dilution

Predicted band size: 43 kDa

Observed band size: 45 kDa,77 kDa

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Western blot - Anti-SIRT2 antibody [EPR1667] (AB134171)
  • WB

Lab

Western blot - Anti-SIRT2 antibody [EPR1667] (AB134171)

Lane 1 : Wild-type HAP1 whole cell lysate (20 μg)
Lane 2 : SIRT2 knockout HAP1 whole cell lysate (20 μg)
Lane 3 : HeLa whole cell lysate (20 μg)
Lane 4 : SH-SY5Y whole cell lysate (20 μg)

Lanes 1 - 4 : Merged signal (red and green). Green - ab134171 observed at 48 kDa. Red - loading control, ab18058, observed at 130 kDa.

ab134171 was shown to specifically react with SIRT2 in wild-type HAP1 cells. No band was observed when SIRT2 knockout samples were examined. Wild-type and SIRT2 knockout samples were subjected to SDS-PAGE. ab134171 and ab18058 (Mouse anti-Vinculin loading control) were incubated overnight at 4°C at 1/500 dilution and 1/10,000 dilution respectively. Blots were developed with Goat anti-Rabbit IgG H&L (IRDye® 800CW) preabsorbed ab216773 and Goat anti-Mouse IgG H&L (IRDye® 680RD) preabsorbed ab216776 secondary antibodies at 1/10,000 dilution for 1 hour at room temperature before imaging.

All lanes:

Western blot - Anti-SIRT2 antibody [EPR1667] (ab134171)

Predicted band size: 43 kDa

Observed band size: 48 kDa

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  • Carrier free

    Anti-SIRT2 antibody [EPR1667] - BSA and Azide free

Key facts

Host species

Rabbit

Clonality

Monoclonal

Clone number

EPR1667

Isotype

IgG

Carrier free

No

Reacts with

Human

Applications

WB

applications

Immunogen

The exact immunogen used to generate this antibody is proprietary information.

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Reactivity data

{ "title": "Reactivity Data", "filters": { "stats": ["", "Species", "Dilution Info", "Notes"], "tabs": { "all-applications": {"fullname" : "All Applications", "shortname": "All Applications"}, "ICCIF" : {"fullname" : "Immunocytochemistry/ Immunofluorescence", "shortname":"ICC/IF"}, "IP" : {"fullname" : "Immunoprecipitation", "shortname":"IP"}, "FlowCyt" : {"fullname" : "Flow Cytometry", "shortname":"Flow Cyt"}, "WB" : {"fullname" : "Western blot", "shortname":"WB"}, "IHCP" : {"fullname" : "Immunohistochemistry (Formalin/PFA-fixed paraffin-embedded sections)", "shortname":"IHC-P"} }, "product-promise": { "all": "all", "testedAndGuaranteed": "tested", "guaranteed": "expected", "predicted": "predicted", "notRecommended": "not-recommended" } }, "values": { "Human": { "ICCIF-species-checked": "notRecommended", "ICCIF-species-dilution-info": "", "ICCIF-species-notes": "<p></p>", "IP-species-checked": "notRecommended", "IP-species-dilution-info": "", "IP-species-notes": "<p></p>", "FlowCyt-species-checked": "notRecommended", "FlowCyt-species-dilution-info": "", "FlowCyt-species-notes": "<p></p>", "WB-species-checked": "testedAndGuaranteed", "WB-species-dilution-info": "1/500 - 1/1000", "WB-species-notes": "<p></p>", "IHCP-species-checked": "notRecommended", "IHCP-species-dilution-info": "", "IHCP-species-notes": "<p></p>" } } }
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Product details

Species reactivity
Mouse: We have preliminary internal testing data to indicate this antibody may not react with this species.
Please contact us for more information.

Patented technology
Our RabMAb® technology is a patented hybridoma-based technology for making rabbit monoclonal antibodies. For details on our patents, please refer to RabMAb® patents.

What are the advantages of a recombinant monoclonal antibody?
This product is a recombinant monoclonal antibody, which offers several advantages including:

  • - High batch-to-batch consistency and reproducibility
  • - Improved sensitivity and specificity
  • - Long-term security of supply
  • - Animal-free batch production

For more information, read more on recombinant antibodies.

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Properties and storage information

Form
Liquid
Purification technique
Affinity purification Protein A
Storage buffer
pH: 7.2 - 7.4 Preservative: 0.01% Sodium azide Constituents: PBS, 50% Tissue culture supernatant, 40% Glycerol (glycerin, glycerine), 0.05% BSA
Shipped at conditions
Blue Ice
Appropriate short-term storage conditions
+4°C
Appropriate long-term storage conditions
-20°C
Storage information
Stable for 12 months at -20°C
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Supplementary information

This supplementary information is collated from multiple sources and compiled automatically.

SIRT2 also known as Sirtuin 2 is a member of the sirtuin family of proteins which are NAD+-dependent deacetylases known for regulating various cellular processes. SIRT2 has a molecular mass of approximately 43 kDa. Its expression is prominent in the cytoplasm but can also be found in the nucleus of cells particularly in the brain and liver tissues. The protein deacetylates various substrates influencing cellular processes including aging metabolism and neurodegeneration.
Biological function summary

SIRT2 contributes to the regulation of cellular homeostasis and stress responses. This protein acts as a deacetylase modulating the acetylation status of key proteins and participates in various signaling pathways. It functions as part of a larger protein complex and interacts with substrates that include tubulin and histones. These interactions help SIRT2 control processes such as cell cycle differentiation and proliferation indicating its importance in maintaining normal cellular function.

Pathways

SIRT2 plays an essential role in the insulin signaling pathway and the FoxO transcription factor pathway. In these pathways SIRT2 interacts with other sirtuins like SIRT1 which helps regulate metabolic homeostasis and oxidative stress responses. SIRT2's activity in deacetylating proteins such as p53 impacts cellular responses to DNA damage and genomic stability further integrating it into critical regulatory networks within the cell.

SIRT2 relates to neurodegenerative diseases like Parkinson's disease and metabolic disorders such as obesity. Its involvement in deacetylating alpha-synuclein links SIRT2 to Parkinson's disease pathogenesis. In metabolic disorders abnormalities in SIRT2 activity can affect glucose and lipid metabolism connecting it with proteins like acetyl-CoA carboxylase. Understanding SIRT2's function offers potential therapeutic targets for these conditions and highlights its importance in disease regulation.
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Product protocols

For this product, it's our understanding that no specific protocols are required. You can visit:
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Target data

NAD-dependent protein deacetylase, which deacetylates internal lysines on histone and alpha-tubulin as well as many other proteins such as key transcription factors (PubMed : 12620231, PubMed : 16648462, PubMed : 18249187, PubMed : 18332217, PubMed : 18995842, PubMed : 20543840, PubMed : 20587414, PubMed : 21081649, PubMed : 21726808, PubMed : 21949390, PubMed : 22014574, PubMed : 22771473, PubMed : 23468428, PubMed : 23908241, PubMed : 24177535, PubMed : 24681946, PubMed : 24769394, PubMed : 24940000). Participates in the modulation of multiple and diverse biological processes such as cell cycle control, genomic integrity, microtubule dynamics, cell differentiation, metabolic networks, and autophagy (PubMed : 12620231, PubMed : 16648462, PubMed : 18249187, PubMed : 18332217, PubMed : 18995842, PubMed : 20543840, PubMed : 20587414, PubMed : 21081649, PubMed : 21726808, PubMed : 21949390, PubMed : 22014574, PubMed : 22771473, PubMed : 23468428, PubMed : 23908241, PubMed : 24177535, PubMed : 24681946, PubMed : 24769394, PubMed : 24940000). Plays a major role in the control of cell cycle progression and genomic stability (PubMed : 12697818, PubMed : 16909107, PubMed : 17488717, PubMed : 17726514, PubMed : 19282667, PubMed : 23468428). Functions in the antephase checkpoint preventing precocious mitotic entry in response to microtubule stress agents, and hence allowing proper inheritance of chromosomes (PubMed : 12697818, PubMed : 16909107, PubMed : 17488717, PubMed : 17726514, PubMed : 19282667, PubMed : 23468428). Positively regulates the anaphase promoting complex/cyclosome (APC/C) ubiquitin ligase complex activity by deacetylating CDC20 and FZR1, then allowing progression through mitosis (PubMed : 22014574). Associates both with chromatin at transcriptional start sites (TSSs) and enhancers of active genes (PubMed : 23468428). Plays a role in cell cycle and chromatin compaction through epigenetic modulation of the regulation of histone H4 'Lys-20' methylation (H4K20me1) during early mitosis (PubMed : 23468428). Specifically deacetylates histone H4 at 'Lys-16' (H4K16ac) between the G2/M transition and metaphase enabling H4K20me1 deposition by KMT5A leading to ulterior levels of H4K20me2 and H4K20me3 deposition throughout cell cycle, and mitotic S-phase progression (PubMed : 23468428). Deacetylates KMT5A modulating KMT5A chromatin localization during the mitotic stress response (PubMed : 23468428). Also deacetylates histone H3 at 'Lys-57' (H3K56ac) during the mitotic G2/M transition (PubMed : 20587414). Upon bacterium Listeria monocytogenes infection, deacetylates 'Lys-18' of histone H3 in a receptor tyrosine kinase MET- and PI3K/Akt-dependent manner, thereby inhibiting transcriptional activity and promoting late stages of listeria infection (PubMed : 23908241). During oocyte meiosis progression, may deacetylate histone H4 at 'Lys-16' (H4K16ac) and alpha-tubulin, regulating spindle assembly and chromosome alignment by influencing microtubule dynamics and kinetochore function (PubMed : 24940000). Deacetylates histone H4 at 'Lys-16' (H4K16ac) at the VEGFA promoter and thereby contributes to regulate expression of VEGFA, a key regulator of angiogenesis (PubMed : 24940000). Deacetylates alpha-tubulin at 'Lys-40' and hence controls neuronal motility, oligodendroglial cell arbor projection processes and proliferation of non-neuronal cells (PubMed : 18332217, PubMed : 18995842). Phosphorylation at Ser-368 by a G1/S-specific cyclin E-CDK2 complex inactivates SIRT2-mediated alpha-tubulin deacetylation, negatively regulating cell adhesion, cell migration and neurite outgrowth during neuronal differentiation (PubMed : 17488717). Deacetylates PARD3 and participates in the regulation of Schwann cell peripheral myelination formation during early postnatal development and during postinjury remyelination (PubMed : 21949390). Involved in several cellular metabolic pathways (PubMed : 20543840, PubMed : 21726808, PubMed : 24769394). Plays a role in the regulation of blood glucose homeostasis by deacetylating and stabilizing phosphoenolpyruvate carboxykinase PCK1 activity in response to low nutrient availability (PubMed : 21726808). Acts as a key regulator in the pentose phosphate pathway (PPP) by deacetylating and activating the glucose-6-phosphate G6PD enzyme, and therefore, stimulates the production of cytosolic NADPH to counteract oxidative damage (PubMed : 24769394). Maintains energy homeostasis in response to nutrient deprivation as well as energy expenditure by inhibiting adipogenesis and promoting lipolysis (PubMed : 20543840). Attenuates adipocyte differentiation by deacetylating and promoting FOXO1 interaction to PPARG and subsequent repression of PPARG-dependent transcriptional activity (PubMed : 20543840). Plays a role in the regulation of lysosome-mediated degradation of protein aggregates by autophagy in neuronal cells (PubMed : 20543840). Deacetylates FOXO1 in response to oxidative stress or serum deprivation, thereby negatively regulating FOXO1-mediated autophagy (PubMed : 20543840). Deacetylates a broad range of transcription factors and co-regulators regulating target gene expression. Deacetylates transcriptional factor FOXO3 stimulating the ubiquitin ligase SCF(SKP2)-mediated FOXO3 ubiquitination and degradation (By similarity). Deacetylates HIF1A and therefore promotes HIF1A degradation and inhibition of HIF1A transcriptional activity in tumor cells in response to hypoxia (PubMed : 24681946). Deacetylates RELA in the cytoplasm inhibiting NF-kappaB-dependent transcription activation upon TNF stimulation (PubMed : 21081649). Inhibits transcriptional activation by deacetylating p53/TP53 and EP300 (PubMed : 18249187, PubMed : 18995842). Also deacetylates EIF5A (PubMed : 22771473). In addition to protein deacetylase activity, also acts as a protein-lysine deacylase by recognizing other acyl groups : catalyzes removal of N(6)-benzoyl (benzoyl) and N(6)-methacryl (methacryl) acyl groups from lysine residues, leading to histone debenzoylation and demethacrylation, respectively (PubMed : 30154464, PubMed : 34961760). Functions as a negative regulator on oxidative stress-tolerance in response to anoxia-reoxygenation conditions (PubMed : 24769394). Plays a role as tumor suppressor (PubMed : 22014574). In addition to protein deacetylase activity, also has activity toward long-chain fatty acyl groups and mediates protein-lysine demyristoylation and depalmitoylation of target proteins, such as ARF6 and KRAS, thereby regulating their association with membranes (PubMed : 25704306, PubMed : 29239724, PubMed : 32103017).. Isoform 1. Deacetylates EP300, alpha-tubulin and histone H3 and H4.. Isoform 2. Deacetylates EP300, alpha-tubulin and histone H3 and H4.. Isoform 5. Lacks deacetylation activity, at least toward known SIRT2 targets.
See full target information SIRT2
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Publications (4)

Recent publications for all applications. Explore the full list and refine your search

Shock (Augusta, Ga.) 63:255-266 PubMed39527461

2024

INHIBITING SIRT2 ATTENUATES SEPSIS-INDUCED ACUTE KIDNEY INJURY VIA FOXO1 ACETYLATION-MEDIATED AUTOPHAGY ACTIVATION.

Applications

Unspecified application

Species

Unspecified reactive species

Binmei Yu,Lijun Weng,Jiaxin Li,Tingjie Wang,Weihuang Qiu,Yuying Li,Menglu Shi,Bo Lin,Xianzhong Lin,Zhongqing Chen,Zhenhua Zeng,Youguang Gao

International journal of molecular sciences 22: PubMed34068624

2021

Targeting SIRT2 Sensitizes Melanoma Cells to Cisplatin via an EGFR-Dependent Mechanism.

Applications

Unspecified application

Species

Unspecified reactive species

Iwona Karwaciak,Anna Sałkowska,Kaja Karaś,Jarosław Dastych,Marcin Ratajewski

Cancers 11: PubMed31091806

2019

SIRT2 Contributes to the Resistance of Melanoma Cells to the Multikinase Inhibitor Dasatinib.

Applications

Unspecified application

Species

Unspecified reactive species

Iwona Karwaciak,Anna Sałkowska,Kaja Karaś,Marta Sobalska-Kwapis,Aurelia Walczak-Drzewiecka,Łukasz Pułaski,Dominik Strapagiel,Jarosław Dastych,Marcin Ratajewski

eLife 6: PubMed29239724

2017

SIRT2 and lysine fatty acylation regulate the transforming activity of K-Ras4a.

Applications

Unspecified application

Species

Unspecified reactive species

Hui Jing,Xiaoyu Zhang,Stephanie A Wisner,Xiao Chen,Nicole A Spiegelman,Maurine E Linder,Hening Lin
View all publications
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