AB110915

Anti-PARP1 antibody [A6.4.12]

Name: Anti-PARP1 antibody [A6.4.12] (ab110915) | Abcam
Brand: Abcam Limited
SKU: AB110915
Price: 400 USD
Availability: InStock
Rating: 5 (1 reviews)

Lab Essentials
What is this?

(1 Review)

(14 Publications)

Mouse Monoclonal PARP1 antibody. Suitable for IHC-P and reacts with Human samples. Cited in 14 publications. Immunogen corresponding to Native Full Length Protein corresponding to Human PARP1.

View Alternative Names

ADPRT, PPOL, PARP1, Poly [ADP-ribose] polymerase 1, PARP-1, ADP-ribosyltransferase diphtheria toxin-like 1, DNA ADP-ribosyltransferase PARP1, NAD(+) ADP-ribosyltransferase 1, Poly[ADP-ribose] synthase 1, Protein poly-ADP-ribosyltransferase PARP1, ARTD1, ADPRT 1

3 Images

Immunohistochemistry (Formalin/PFA-fixed paraffin-embedded sections) - Anti-PARP1 antibody [A6.4.12] (AB110915)

IHC-P

Unknown

Immunohistochemistry (Formalin/PFA-fixed paraffin-embedded sections) - Anti-PARP1 antibody [A6.4.12] (AB110915)

ab110915, at 10 μg/ml, staining PARP1 in formalin fixed, paraffin embedded Human placenta by Immunohistochemistry. Biotinylated anti mouse IgG secondary antibody, alkaline phosphatase streptavidin and chromogen was used to develop staining.

IHC-P

Unknown

Immunohistochemistry (Formalin/PFA-fixed paraffin-embedded sections) - Anti-PARP1 antibody [A6.4.12] (AB110915)

ab110915, at 10 μg/ml, staining PARP1 in formalin fixed, paraffin embedded Human skin by Immunohistochemistry. Biotinylated anti mouse IgG secondary antibody, alkaline phosphatase streptavidin and chromogen was used to develop staining.

IHC-P

Unknown

Immunohistochemistry (Formalin/PFA-fixed paraffin-embedded sections) - Anti-PARP1 antibody [A6.4.12] (AB110915)

ab110915, at 10 μg/ml, staining PARP1 in formalin fixed, paraffin embedded Human spleen by Immunohistochemistry. Biotinylated anti mouse IgG secondary antibody, alkaline phosphatase streptavidin and chromogen was used to develop staining.

Key facts

Host species

Mouse

Clonality

Monoclonal

Clone number

A6.4.12

Isotype

IgG1

Carrier free

Reacts with

Human

Applications

IHC-P

applications

Immunogen

Native Full Length Protein corresponding to Human PARP1.

P09874

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Reactivity data

{ "title": "Reactivity Data", "filters": { "stats": ["", "Species", "Dilution Info", "Notes"], "tabs": { "all-applications": {"fullname" : "All Applications", "shortname": "All Applications"}, "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": { "IHCP-species-checked": "testedAndGuaranteed", "IHCP-species-dilution-info": "10 µg/mL", "IHCP-species-notes": "<p></p>" }, "Mouse": { "IHCP-species-checked": "predicted", "IHCP-species-dilution-info": "", "IHCP-species-notes": "" }, "Rat": { "IHCP-species-checked": "predicted", "IHCP-species-dilution-info": "", "IHCP-species-notes": "" }, "Drosophila melanogaster": { "IHCP-species-checked": "predicted", "IHCP-species-dilution-info": "", "IHCP-species-notes": "" }, "Hamster": { "IHCP-species-checked": "predicted", "IHCP-species-dilution-info": "", "IHCP-species-notes": "" }, "Xenopus laevis": { "IHCP-species-checked": "predicted", "IHCP-species-dilution-info": "", "IHCP-species-notes": "" } } }

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Properties and storage information

Form

Liquid

Purification technique

Affinity purification Protein G

Storage buffer

Preservative: 0.09% Sodium azide

Shipped at conditions

Blue Ice

Appropriate short-term storage duration

1-2 weeks

Appropriate short-term storage conditions

+4°C

Appropriate long-term storage conditions

-20°C

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Supplementary information

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

PARP1 also known as poly(ADP-ribose) polymerase 1 is an enzyme that plays an important role in DNA repair processes. It detects DNA single-strand breaks and uses NAD+ as a substrate to add ADP-ribose polymers to itself and other proteins. This post-translational modification signals DNA repair machinery to the site of damage. PARP1 has a molecular weight of approximately 116 kDa. It is widely expressed in the nucleus of eukaryotic cells. PARP1 is often studied by western blotting techniques to analyze its expression and activation levels.

Biological function summary

Poly(ADP-ribose) polymerase 1 functions to maintain genomic stability by acting within the base excision repair complex. This complex is important for the detection and repair of DNA damage preventing the accumulation of mutations. By acting at sites of DNA stress PARP1 facilitates the binding of DNA repair proteins stabilizing the DNA structure during the repair process. This role is significant for cells that undergo frequent DNA replication or are exposed to high levels of genotoxic stress.

Pathways

The PARP1 protein is integral to the DNA damage response and repair pathway. It interacts with other proteins such as XRCC1 to coordinate repair activities at damaged DNA sites. Another important pathway involving PARP1 is the apoptosis pathway where excessive activation of PARP1 can lead to cell death due to depletion of cellular NAD+ and ATP. This indicates its dual role in both promoting cell survival through DNA repair and contributing to cell death when damage is irreparable.

Poly(ADP-ribose) polymerase 1 is strongly linked to cancer and neurodegenerative diseases. Its activity is heightened in many cancer types where cancer cells exploit PARP1 for survival by repairing DNA damage that would otherwise be lethal. Inhibitors of PARP1 are being developed as cancer therapies to target these survival mechanisms. Moreover overactivation of PARP1 in neurodegenerative disorders like Alzheimer's disease can lead to excessive energy consumption promoting neuronal cell damage. In these contexts PARP1 connects with proteins like BRCA1 in cancer or AIF in neurodegeneration illustrating its role in disease mechanisms.

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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

Poly-ADP-ribosyltransferase that mediates poly-ADP-ribosylation of proteins and plays a key role in DNA repair (PubMed : 17177976, PubMed : 18055453, PubMed : 18172500, PubMed : 19344625, PubMed : 19661379, PubMed : 20388712, PubMed : 21680843, PubMed : 22582261, PubMed : 23230272, PubMed : 25043379, PubMed : 26344098, PubMed : 26626479, PubMed : 26626480, PubMed : 30104678, PubMed : 31796734, PubMed : 32028527, PubMed : 32241924, PubMed : 32358582, PubMed : 33186521, PubMed : 34465625, PubMed : 34737271). Mediates glutamate, aspartate, serine, histidine or tyrosine ADP-ribosylation of proteins : the ADP-D-ribosyl group of NAD(+) is transferred to the acceptor carboxyl group of target residues and further ADP-ribosyl groups are transferred to the 2'-position of the terminal adenosine moiety, building up a polymer with an average chain length of 20-30 units (PubMed : 19764761, PubMed : 25043379, PubMed : 28190768, PubMed : 29954836, PubMed : 35393539, PubMed : 7852410, PubMed : 9315851). Serine ADP-ribosylation of proteins constitutes the primary form of ADP-ribosylation of proteins in response to DNA damage (PubMed : 33186521, PubMed : 34874266). Specificity for the different amino acids is conferred by interacting factors, such as HPF1 and NMNAT1 (PubMed : 28190768, PubMed : 29954836, PubMed : 32028527, PubMed : 33186521, PubMed : 33589610, PubMed : 34625544, PubMed : 34874266). Following interaction with HPF1, catalyzes serine ADP-ribosylation of target proteins; HPF1 confers serine specificity by completing the PARP1 active site (PubMed : 28190768, PubMed : 29954836, PubMed : 32028527, PubMed : 33186521, PubMed : 33589610, PubMed : 34625544, PubMed : 34874266). Also catalyzes tyrosine ADP-ribosylation of target proteins following interaction with HPF1 (PubMed : 29954836, PubMed : 30257210). Following interaction with NMNAT1, catalyzes glutamate and aspartate ADP-ribosylation of target proteins; NMNAT1 confers glutamate and aspartate specificity (By similarity). PARP1 initiates the repair of DNA breaks : recognizes and binds DNA breaks within chromatin and recruits HPF1, licensing serine ADP-ribosylation of target proteins, such as histones (H2BS6ADPr and H3S10ADPr), thereby promoting decompaction of chromatin and the recruitment of repair factors leading to the reparation of DNA strand breaks (PubMed : 17177976, PubMed : 18172500, PubMed : 19344625, PubMed : 19661379, PubMed : 23230272, PubMed : 27067600, PubMed : 34465625, PubMed : 34874266). HPF1 initiates serine ADP-ribosylation but restricts the polymerase activity of PARP1 in order to limit the length of poly-ADP-ribose chains (PubMed : 33683197, PubMed : 34732825, PubMed : 34795260). In addition to base excision repair (BER) pathway, also involved in double-strand breaks (DSBs) repair : together with TIMELESS, accumulates at DNA damage sites and promotes homologous recombination repair by mediating poly-ADP-ribosylation (PubMed : 26344098, PubMed : 30356214). Mediates the poly-ADP-ribosylation of a number of proteins, including itself, APLF, CHFR, RPA1 and NFAT5 (PubMed : 17396150, PubMed : 19764761, PubMed : 24906880, PubMed : 34049076). In addition to proteins, also able to ADP-ribosylate DNA : catalyzes ADP-ribosylation of DNA strand break termini containing terminal phosphates and a 2'-OH group in single- and double-stranded DNA, respectively (PubMed : 27471034). Required for PARP9 and DTX3L recruitment to DNA damage sites (PubMed : 23230272). PARP1-dependent PARP9-DTX3L-mediated ubiquitination promotes the rapid and specific recruitment of 53BP1/TP53BP1, UIMC1/RAP80, and BRCA1 to DNA damage sites (PubMed : 23230272). PARP1-mediated DNA repair in neurons plays a role in sleep : senses DNA damage in neurons and promotes sleep, facilitating efficient DNA repair (By similarity). In addition to DNA repair, also involved in other processes, such as transcription regulation, programmed cell death, membrane repair, adipogenesis and innate immunity (PubMed : 15607977, PubMed : 17177976, PubMed : 19344625, PubMed : 27256882, PubMed : 32315358, PubMed : 32844745, PubMed : 35124853, PubMed : 35393539, PubMed : 35460603). Acts as a repressor of transcription : binds to nucleosomes and modulates chromatin structure in a manner similar to histone H1, thereby altering RNA polymerase II (PubMed : 15607977, PubMed : 22464733). Acts both as a positive and negative regulator of transcription elongation, depending on the context (PubMed : 27256882, PubMed : 35393539). Acts as a positive regulator of transcription elongation by mediating poly-ADP-ribosylation of NELFE, preventing RNA-binding activity of NELFE and relieving transcription pausing (PubMed : 27256882). Acts as a negative regulator of transcription elongation in response to DNA damage by catalyzing poly-ADP-ribosylation of CCNT1, disrupting the phase separation activity of CCNT1 and subsequent activation of CDK9 (PubMed : 35393539). Involved in replication fork progression following interaction with CARM1 : mediates poly-ADP-ribosylation at replication forks, slowing fork progression (PubMed : 33412112). Poly-ADP-ribose chains generated by PARP1 also play a role in poly-ADP-ribose-dependent cell death, a process named parthanatos (By similarity). Also acts as a negative regulator of the cGAS-STING pathway (PubMed : 32315358, PubMed : 32844745, PubMed : 35460603). Acts by mediating poly-ADP-ribosylation of CGAS : PARP1 translocates into the cytosol following phosphorylation by PRKDC and catalyzes poly-ADP-ribosylation and inactivation of CGAS (PubMed : 35460603). Acts as a negative regulator of adipogenesis : catalyzes poly-ADP-ribosylation of histone H2B on 'Glu-35' (H2BE35ADPr) following interaction with NMNAT1, inhibiting phosphorylation of H2B at 'Ser-36' (H2BS36ph), thereby blocking expression of pro-adipogenetic genes (By similarity). Involved in the synthesis of ATP in the nucleus, together with NMNAT1, PARG and NUDT5 (PubMed : 27257257). Nuclear ATP generation is required for extensive chromatin remodeling events that are energy-consuming (PubMed : 27257257).. Poly [ADP-ribose] polymerase 1, processed C-terminus. Promotes AIFM1-mediated apoptosis (PubMed : 33168626). This form, which translocates into the cytoplasm following cleavage by caspase-3 (CASP3) and caspase-7 (CASP7) in response to apoptosis, is auto-poly-ADP-ribosylated and serves as a poly-ADP-ribose carrier to induce AIFM1-mediated apoptosis (PubMed : 33168626).. Poly [ADP-ribose] polymerase 1, processed N-terminus. This cleavage form irreversibly binds to DNA breaks and interferes with DNA repair, promoting DNA damage-induced apoptosis.

See full target information PARP1

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Publications (14)

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

Antioxidants (Basel, Switzerland) 12: PubMed36671041

2023

Evidence of Increased Oxidative Stress in the Placental Tissue of Women Who Suffered an Episode of Psychosis during Pregnancy.

Applications

Unspecified application

Species

Unspecified reactive species

Miguel A Ortega,Oscar Fraile-Martinez,Cielo García-Montero,Sonia Rodriguez-Martín,Rosa M Funes Moñux,Coral Bravo,Juan A De Leon-Luis,Jose V Saz,Miguel A Saez,Luis G Guijarro,Guillermo Lahera,Jorge Monserrat,Fernando Mora,Javier Quintero,Julia Bujan,Natalio García-Honduvilla,Melchor Alvarez-Mon,Miguel Angel Alvarez-Mon

Antioxidants (Basel, Switzerland) 11: PubMed35453444

2022

Oxidative Stress Markers Are Associated with a Poor Prognosis in Patients with Pancreatic Cancer.

Applications

Unspecified application

Species

Unspecified reactive species

Miguel A Ortega,Oscar Fraile-Martinez,Leonel Pekarek,Cielo García-Montero,Miguel Angel Alvarez-Mon,Alejandro J Castellanos,Natalio García-Honduvilla,Julia Buján,Melchor Alvarez-Mon,Miguel A Sáez,Luis G Guijarro,Angel Asúnsolo

Cardiovascular diagnosis and therapy 11:1025-1035 PubMed34815953

2021

Lipopolysaccharide induces pyroptosis through regulation of autophagy in cardiomyocytes.

Applications

Unspecified application

Species

Unspecified reactive species

You-Fu He,Jing Huang,Yu Qian,De-Bin Liu,Qi-Fang Liu

Journal of cellular and molecular medicine 25:7878-7889 PubMed34148301

2021

Tissue remodelling and increased DNA damage in patients with incompetent valves in chronic venous insufficiency.

Applications

Unspecified application

Species

Unspecified reactive species

Miguel A Ortega,Oscar Fraile-Martínez,Cielo García-Montero,Leonel Pekarek,Miguel A Alvarez-Mon,Luis G Guijarro,Maria Del Carmen Boyano,Felipe Sainz,Melchor Álvarez-Mon,Julia Buján,Natalio García-Honduvilla,Ángel Asúnsolo

Oncology reports 45:665-679 PubMed33416155

2021

Enhancement of cisplatin sensitivity in human breast cancer MCF-7 cell line through BiP and 14-3-3ζ co-knockdown.

Applications

Unspecified application

Species

Unspecified reactive species

Tahereh Kashkoulinejad-Kouhi,Shahrokh Safarian,Blanca Arnaiz,Laura Saa

Frontiers in cell and developmental biology 8:414 PubMed32528962

2020

Overexpression of FAM46A, a Non-canonical Poly(A) Polymerase, Promotes Hemin-Induced Hemoglobinization in K562 Cells.

Applications

Unspecified application

Species

Unspecified reactive species

Hsi-Hsien Lin,Yu-Ling Lo,Wen-Chih Wang,Kuan-Yeh Huang,Kuan-Yu I,Gin-Wen Chang

International journal of cancer 145:474-483 PubMed30614530

2019

Cytoplasmic PARP-1 promotes pancreatic cancer tumorigenesis and resistance.

Applications

Unspecified application

Species

Unspecified reactive species

Fei Xu,Yong Sun,Shan-Zhong Yang,Tong Zhou,Nirag Jhala,Jay McDonald,Yabing Chen

Cancer discovery 8:988-1005 PubMed29880585

2018

Haploinsufficiency Impairs Catalytic Activity of PARP1 and Promotes Chromosome Instability and Growth of Intestinal Tumors.

Applications

Unspecified application

Species

Unspecified reactive species

Anuratha Sakthianandeswaren,Marie J Parsons,Dmitri Mouradov,Ruth N MacKinnon,Bruno Catimel,Sheng Liu,Michelle Palmieri,Christopher Love,Robert N Jorissen,Shan Li,Lachlan Whitehead,Tracy L Putoczki,Adele Preaudet,Cary Tsui,Cameron J Nowell,Robyn L Ward,Nicholas J Hawkins,Jayesh Desai,Peter Gibbs,Matthias Ernst,Ian Street,Michael Buchert,Oliver M Sieber

Neoplasia (New York, N.Y.) 20:140-151 PubMed29248718

2017

Proteomic Characterization of Prostate Cancer to Distinguish Nonmetastasizing and Metastasizing Primary Tumors and Lymph Node Metastases.

Applications

Unspecified application

Species

Unspecified reactive species

Ann-Kathrin Müller,Melanie Föll,Bianca Heckelmann,Selina Kiefer,Martin Werner,Oliver Schilling,Martin L Biniossek,Cordula Annette Jilg,Vanessa Drendel

Cell cycle (Georgetown, Tex.) 16:200-212 PubMed27937072

2016

Altered expression of G1/S phase cell cycle regulators in placental mesenchymal stromal cells derived from preeclamptic pregnancies with fetal-placental compromise.

Applications

Species

Unspecified reactive species

Anna Maria Nuzzo,Domenica Giuffrida,Bianca Masturzo,Paolo Mele,Ettore Piccoli,Carola Eva,Tullia Todros,Alessandro Rolfo

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