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AB42364

Anti-OPA1 antibody

3

(7 Reviews)

|

(179 Publications)

Rabbit Polyclonal OPA1 antibody. Suitable for IP, WB and reacts with Rat, Mouse, Human samples. Cited in 179 publications.

View Alternative Names

Optic atrophy protein 1 homolog

3 Images
Immunoprecipitation - Anti-OPA1 antibody (AB42364)
  • IP

Unknown

Immunoprecipitation - Anti-OPA1 antibody (AB42364)

OPA1 was immunoprecipitated using 0.5mg Rat Brain whole tissue lysate, 5μg of Rabbit polyclonal to OPA1 and 50μl of protein G magnetic beads (+). No antibody was added to the control (-).
The antibody was incubated under agitation with Protein G beads for 10min, rat brain whole tissue lysate diluted in RIPA buffer was added to each sample and incubated for a further 10min under agitation.
Proteins were eluted by addition of 40μl SDS loading buffer and incubated for 10min at 70oC; 10μl of each sample was separated on a SDS PAGE gel, transferred to a nitrocellulose membrane, blocked with 5% BSA and probed with ab42364.
Secondary : Mouse monoclonal [SB62a] Secondary Antibody to Rabbit IgG light chain (HRP) (ab99697).
Band : 92kDa : OPA1; non specific - 100kDa : We are unsure as to the identity of this extra band.

All lanes:

Immunoprecipitation - Anti-OPA1 antibody (ab42364)

Predicted band size: 111 kDa

false

Western blot - Anti-OPA1 antibody (AB42364)
  • WB

Unknown

Western blot - Anti-OPA1 antibody (AB42364)

Abcam recommends using milk as the blocking agent. Abcam welcomes customer feedback and would appreciate any comments regarding this product and the data presented above.

All lanes:

Western blot - Anti-OPA1 antibody (ab42364) at 1 µg/mL

Lane 1:

Human brain tissue lysate - total protein (<a href='/en-us/products/unavailable/human-brain-tissue-lysate-total-protein-ab29466'>ab29466</a>) at 10 µg

Lane 2:

Brain (Mouse) Tissue Lysate at 10 µg

Lane 3:

Brain (Rat) Tissue Lysate at 10 µg

Secondary

All lanes:

Western blot - Goat Anti-Rabbit IgG H&L (HRP) (<a href='/en-us/products/secondary-antibodies/goat-rabbit-igg-h-l-hrp-ab97051'>ab97051</a>) at 1/10000 dilution

Predicted band size: 111 kDa

Observed band size: 100 kDa,92 kDa

true

Exposure time: 2min

Western blot - Anti-OPA1 antibody (AB42364)
  • WB

Project

Western blot - Anti-OPA1 antibody (AB42364)

Although the predicted band size is ~111 kDa based on Swiss-prot data, bands of 92 kDa and 86 kDa has been previously observed. Investigative Ophthalmology & Visual Science, November 2005, Vol. 46, No. 11

All lanes:

Western blot - Anti-OPA1 antibody (ab42364) at 1 µg/mL

All lanes:

Brain (Rat) Tissue Lysate - normal tissue at 10 µg

Secondary

All lanes:

Goat polyclonal to Rabbit IgG - H&L - Pre-Adsorbed (HRP) at 1/3000 dilution

Predicted band size: 111 kDa

Observed band size: 86 kDa,92 kDa

false

Key facts

Host species

Rabbit

Clonality

Polyclonal

Isotype

IgG

Carrier free

No

Reacts with

Mouse, Rat, Human

Applications

WB, IP

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"}, "IP" : {"fullname" : "Immunoprecipitation", "shortname":"IP"}, "WB" : {"fullname" : "Western blot", "shortname":"WB"} }, "product-promise": { "all": "all", "testedAndGuaranteed": "tested", "guaranteed": "expected", "predicted": "predicted", "notRecommended": "not-recommended" } }, "values": { "Human": { "IP-species-checked": "guaranteed", "IP-species-dilution-info": "", "IP-species-notes": "", "WB-species-checked": "testedAndGuaranteed", "WB-species-dilution-info": "1 µg/mL", "WB-species-notes": "<p>Abcam recommends using milk as the blocking agent.</p>" }, "Mouse": { "IP-species-checked": "guaranteed", "IP-species-dilution-info": "", "IP-species-notes": "", "WB-species-checked": "testedAndGuaranteed", "WB-species-dilution-info": "1 µg/mL", "WB-species-notes": "<p>Abcam recommends using milk as the blocking agent.</p>" }, "Rat": { "IP-species-checked": "testedAndGuaranteed", "IP-species-dilution-info": "", "IP-species-notes": "<p></p>", "WB-species-checked": "testedAndGuaranteed", "WB-species-dilution-info": "1 µg/mL", "WB-species-notes": "<p>Abcam recommends using milk as the blocking agent.</p>" }, "Chicken": { "IP-species-checked": "predicted", "IP-species-dilution-info": "", "IP-species-notes": "", "WB-species-checked": "predicted", "WB-species-dilution-info": "", "WB-species-notes": "" }, "Orangutan": { "IP-species-checked": "predicted", "IP-species-dilution-info": "", "IP-species-notes": "", "WB-species-checked": "predicted", "WB-species-dilution-info": "", "WB-species-notes": "" } } }
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Properties and storage information

Form
Liquid
Purification technique
Affinity purification Immunogen
Storage buffer
pH: 7.4 Preservative: 0.02% Sodium azide Constituents: PBS, 1% BSA
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
Aliquoting information
Upon delivery aliquot
Storage information
Avoid freeze / thaw cycle
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Supplementary information

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

OPA1 also known as optic atrophy 1 is a dynamin-related GTPase protein important for mitochondrial fusion. OPA1 has a molecular weight of about 120 kDa and is present mostly in the inner mitochondrial membrane. It promotes the maintenance of mitochondrial DNA cristae structures and the modulation of mitochondrial dynamics. Expression of OPA1 occurs in tissues with high energy demands including the retina brain and muscles. Detection of the OPA1 protein can be done using techniques such as Western blot and it reveals different isoforms generated through alternative splicing.
Biological function summary

Mitochondrial dynamics involving OPA1 ensure energy production efficiency and cell health. OPA1 plays a role in mitochondrial fusion by forming a complex with mitofusins MFN1 and MFN2. This complex maintains the integrity of mitochondrial networks facilitates proper respiratory function and prevents apoptosis by regulating cristae junctions. It also participates in the stress response particularly in the preservation of the mitochondrial structure and function under challenging conditions.

Pathways

OPA1 integrates into the mitochondrial fusion and fission pathways important for cellular energy metabolism. It works alongside proteins like DRP1 in balancing these processes. The involvement in these pathways is essential for cellular adaptation to metabolic needs and stress. OPA1 also has a relationship with the PINK1/Parkin pathway where its regulation affects mitophagy a process of clearing damaged mitochondria. These interactions highlight the importance of OPA1 in maintaining cellular and mitochondrial homeostasis.

Mutations in OPA1 have been linked to autosomal dominant optic atrophy and a range of neurodegenerative conditions. The protein’s dysfunction leads to the degeneration of the retinal ganglion cells and their axons resulting in vision loss. OPA1 also shows connections to disorders like Charcot-Marie-Tooth disease where its interaction with other proteins like MFN2 plays a role. Deficiency or dysfunction of OPA1 disrupts mitochondrial dynamics leading to cellular energy deficits and contributing to disease pathophysiology.
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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

Dynamin-related GTPase that is essential for normal mitochondrial morphology by mediating fusion of the mitochondrial inner membranes, regulating cristae morphology and maintaining respiratory chain function (PubMed : 16778770). Exists in two forms : the transmembrane, long form (Dynamin-like GTPase OPA1, long form; L-OPA1), which is tethered to the inner mitochondrial membrane, and the short soluble form (Dynamin-like GTPase OPA1, short form; S-OPA1), which results from proteolytic cleavage and localizes in the intermembrane space (By similarity). Both forms (L-OPA1 and S-OPA1) cooperate to catalyze the fusion of the mitochondrial inner membrane (By similarity). The equilibrium between L-OPA1 and S-OPA1 is essential : excess levels of S-OPA1, produced by cleavage by OMA1 following loss of mitochondrial membrane potential, lead to an impaired equilibrium between L-OPA1 and S-OPA1, inhibiting mitochondrial fusion (By similarity). The balance between L-OPA1 and S-OPA1 also influences cristae shape and morphology (By similarity). Involved in remodeling cristae and the release of cytochrome c during apoptosis (By similarity). Proteolytic processing by PARL in response to intrinsic apoptotic signals may lead to disassembly of OPA1 oligomers and release of the caspase activator cytochrome C (CYCS) into the mitochondrial intermembrane space (By similarity). Acts as a regulator of T-helper Th17 cells, which are characterized by cells with fused mitochondria with tight cristae, by mediating mitochondrial membrane remodeling : OPA1 is required for interleukin-17 (IL-17) production (By similarity). Its role in mitochondrial morphology is required for mitochondrial genome maintenance (By similarity).. Dynamin-like GTPase OPA1, long form. Constitutes the transmembrane long form (L-OPA1) that plays a central role in mitochondrial inner membrane fusion and cristae morphology (By similarity). L-OPA1 and the soluble short form (S-OPA1) form higher-order helical assemblies that coordinate the fusion of mitochondrial inner membranes (By similarity). Inner membrane-anchored L-OPA1 molecules initiate membrane remodeling by recruiting soluble S-OPA1 to rapidly polymerize into a flexible cylindrical scaffold encaging the mitochondrial inner membrane (By similarity). Once at the membrane surface, the formation of S-OPA1 helices induce bilayer curvature (By similarity). OPA1 dimerization through the paddle region, which inserts into cardiolipin-containing membrane, promotes GTP hydrolysis and the helical assembly of a flexible OPA1 lattice on the membrane, which drives membrane curvature and mitochondrial fusion (By similarity). Plays a role in the maintenance and remodeling of mitochondrial cristae, some invaginations of the mitochondrial inner membrane that provide an increase in the surface area (By similarity). Probably acts by forming helical filaments at the inside of inner membrane tubes with the shape and dimensions of crista junctions (By similarity). The equilibrium between L-OPA1 and S-OPA1 influences cristae shape and morphology : increased L-OPA1 levels promote cristae stacking and elongated mitochondria, while increased S-OPA1 levels correlated with irregular cristae packing and round mitochondria shape (By similarity).. Dynamin-like GTPase OPA1, short form. Constitutes the soluble short form (S-OPA1) generated by cleavage by OMA1, which plays a central role in mitochondrial inner membrane fusion and cristae morphology (By similarity). The transmembrane long form (L-OPA1) and the S-OPA1 form higher-order helical assemblies that coordinate the fusion of mitochondrial inner membranes (By similarity). Inner membrane-anchored L-OPA1 molecules initiate membrane remodeling by recruiting soluble S-OPA1 to rapidly polymerize into a flexible cylindrical scaffold encaging the mitochondrial inner membrane (By similarity). Once at the membrane surface, the formation of S-OPA1 helices induce bilayer curvature (By similarity). OPA1 dimerization through the paddle region, which inserts into cardiolipin-containing membrane, promotes GTP hydrolysis and the helical assembly of a flexible OPA1 lattice on the membrane, which drives membrane curvature and mitochondrial fusion (By similarity). Excess levels of S-OPA1 produced by cleavage by OMA1 following stress conditions that induce loss of mitochondrial membrane potential, lead to an impaired equilibrium between L-OPA1 and S-OPA1, thereby inhibiting mitochondrial fusion (By similarity). Involved in mitochondrial safeguard in response to transient mitochondrial membrane depolarization by mediating flickering : cleavage by OMA1 leads to excess production of S-OPA1, preventing mitochondrial hyperfusion (By similarity). Plays a role in the maintenance and remodeling of mitochondrial cristae, some invaginations of the mitochondrial inner membrane that provide an increase in the surface area (By similarity). Probably acts by forming helical filaments at the inside of inner membrane tubes with the shape and dimensions of crista junctions (By similarity). The equilibrium between L-OPA1 and S-OPA1 influences cristae shape and morphology : increased L-OPA1 levels promote cristae stacking and elongated mitochondria, while increased S-OPA1 levels correlated with irregular cristae packing and round mitochondria shape (By similarity).. Isoform 2. Isoforms that contain the alternative exon 4b are required for mitochondrial genome maintenance, possibly by anchoring the mitochondrial nucleoids to the inner mitochondrial membrane.. Isoform 3. Isoforms that contain the alternative exon 4b are required for mitochondrial genome maintenance, possibly by anchoring the mitochondrial nucleoids to the inner mitochondrial membrane.
See full target information Opa1
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Publications (179)

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

Redox biology 86:103799 PubMed40774145

2025

Peroxiredoxin Ⅲ mitigates mitochondrial HO-mediated damage and supports quality control in cardiomyocytes under hypoxia-reoxygenation stress.

Applications

Unspecified application

Species

Unspecified reactive species

Ji Won Park,Seong Keun Sonn,Byung-Hoon Lee,Goo Taeg Oh,Tong-Shin Chang

Acta pharmaceutica Sinica. B 15:3125-3148 PubMed40654366

2025

The crucial function of IDO1 in pulmonary fibrosis: From the perspective of mitochondrial fusion in lung fibroblasts and targeted molecular inhibition.

Applications

Unspecified application

Species

Unspecified reactive species

Lei Wang,Shanchun Ge,Ye Zhang,Deqin Feng,Ting Zhu,Louqian Zhang,Chaofeng Zhang

Cell communication and signaling : CCS 23:256 PubMed40450326

2025

mTOR inhibition triggers mitochondrial fragmentation in cardiomyocytes through proteosome-dependent prohibitin degradation and OPA-1 cleavage.

Applications

Unspecified application

Species

Unspecified reactive species

Hugo E Verdejo,Valentina Parra,Andrea Del Campo,Cesar Vasquez-Trincado,Damian Gatica,Camila Lopez-Crisosto,Jovan Kuzmicic,Leslye Venegas-Zamora,Ursula Zuñiga-Cuevas,Mayarling F Troncoso,Rodrigo Troncoso,Beverly A Rothermel,Mario Chiong,E Dale Abel,Sergio Lavandero

Membranes 15: PubMed40422762

2025

Membrane ATPases and Mitochondrial Proteins in Fetal Cerebellum After Exposure to L-Glutamate During Gestation.

Applications

Unspecified application

Species

Unspecified reactive species

Adrián Tejero,David Agustín León-Navarro,Mairena Martín

Stem cell research & therapy 16:218 PubMed40312745

2025

Puerarin relives inflammation, bone destruction and facilitates osteogenic differentiation in periodontitis by enhancing mitochondrial autophagy via activating mitochondrial Mitofusin 2.

Applications

Unspecified application

Species

Unspecified reactive species

Yulan Xiang,Zelu Li,Xin He,Xiaoyang Chu,Chunyan Gao,Jiahao Guo,Yingyi Luan,Kai Yang,Dongliang Zhang

Journal of nanobiotechnology 23:208 PubMed40075447

2025

Macrophage-derived mitochondria-rich extracellular vesicles aggravate bone loss in periodontitis by disrupting the mitochondrial dynamics of BMSCs.

Applications

Unspecified application

Species

Unspecified reactive species

Jiayin Yan,Tian Yang,Siyuan Ma,Danfeng Li,Cheng Hu,Jiali Tan

Science advances 11:eadr1938 PubMed40020067

2025

A long-lived pool of PINK1 imparts a molecular memory of depolarization-induced activity.

Applications

Unspecified application

Species

Unspecified reactive species

Liam Pollock,Ioanna Ch Georgiou,Emma V Rusilowicz-Jones,Michael J Clague,Sylvie Urbé

Respiratory research 25:443 PubMed39725939

2024

Activated DRP1 promotes mitochondrial fission and induces glycolysis in ATII cells under hyperoxia.

Applications

Unspecified application

Species

Unspecified reactive species

Tong Sun,Haiyang Yu,Dingning Zhang,Danni Li,Jianhua Fu

Cellular and molecular life sciences : CMLS 82:13 PubMed39719538

2024

Trimethylamine-N-oxide accelerates osteoporosis by PERK activation of ATF5 unfolding.

Applications

Unspecified application

Species

Unspecified reactive species

Yu-Han Lin,Wei-Shiung Lian,Re-Wen Wu,Yu-Shan Chen,Shin-Long Wu,Jih-Yang Ko,Shao-Yu Wang,Holger Jahr,Feng-Sheng Wang

Aging and disease 16:3040-3054 PubMed39571159

2024

Exercise Types: Physical Activity Mitigates Cardiac Aging and Enhances Mitochondrial Function via PKG-STAT3-Opa1 Axis.

Applications

Unspecified application

Species

Unspecified reactive species

Reka Szekeres,Daniel Priksz,Mariann Bombicz,Beata Pelles-Tasko,Anna Szilagyi,Brigitta Bernat,Aniko Posa,Balazs Varga,Rudolf Gesztelyi,Sandor Somodi,Zoltan Szabo,Zoltan Szilvassy,Bela Juhasz
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