Description:

Size: 100 microliters

Catalog no.: GENTObs-6018R-A594

Price: 489 EUR

Product details

Gene ID

91

Modification site

None

Swiss Prot

P36896

Target Protein/Peptide

ACVR1B

Applications

IF(IHC-P)

Excitation emission

590nm/617nm

Concentration

1ug per 1ul

Subcellular locations

Extracellular

Conjugated with

ALEXA FLUOR® 594

Conjugated

Alexa conjugate 1

Applications with corresponding dilutions

IF(IHC-P)(1:50-200)

Clonality

Polyclonal Antibody

Clone

Polyclonal Antibodies

Other name

Anti-ACVR1B Polyclonal

Purification method

Purified by Protein A.

Group

Polyclonals and antibodies

Also known as

ACVR1B Polyclonal Antibody

Type

Conjugated Primary Antibody

Conjugation

Alexa Fluor,ALEXA FLUOR® 594

Host organism

Rabbit (Oryctolagus cuniculus)

Properties

For facs or microscopy Alexa 1 conjugate.

Specificity

This antibody reacts specifically with ACVR1B

Modification

No modification has been applied to this antibody

Antigen Source

KLH conjugated synthetic peptide derived from human ACVR1B

Cross reactive species

Human (Homo sapiens), Mouse (Mus musculus), Rat (Rattus norvegicus)

Storage

Water buffered solution containing 100ug/ml BSA, 50% glycerol and 0.09% sodium azide. Store at 4°C for 12 months.

Description

This antibody needs to be stored at + 4°C in a fridge short term in a concentrated dilution. Freeze thaw will destroy a percentage in every cycle and should be avoided.

Synonyms

ALK4; SKR2; ACTRIB; ACVRLK4; Activin receptor type-1B; Activin receptor type IB; ACTR-IB; Activin receptor-like kinase 4; ALK-4; Serine/threonine-protein kinase receptor R2; ACVR1B

About

Polyclonals can be used for Western blot, immunohistochemistry on frozen slices or parrafin fixed tissues. The advantage is that there are more epitopes available in a polyclonal antiserum to detect the proteins than in monoclonal sera.

Cross Reactive Species details

No significant cross reactivity has been observed for this antibody for the tested species. However, note that due to limited knowledge it is impossible to predict with 100% guarantee that the antibody does not corss react with any other species.

Advisory

Avoid freeze/thaw cycles as they may denaturate the polypeptide chains of the antibody, thus reducing its reactivity, specificity and sensitivity. For antibodies that are in liquid form or reconstituted lyophilized antibodies small amounts could become entrapped on the seal or the walls of the tube. Prior to use briefly centrifuge the vial to gather all the solution on the bottom.

Background information

Transmembrane serine/threonine kinase activin type-1 receptor forming an activin receptor complex with activin receptor type-2 (ACVR2A or ACVR2B). Transduces the activin signal from the cell surface to the cytoplasm and is thus regulating a many physiological and pathological processes including neuronal differentiation and neuronal survival, hair follicle development and cycling, FSH production by the pituitary gland, wound healing, extracellular matrix production, immunosuppression and carcinogenesis. Activin is also thought to have a paracrine or autocrine role in follicular development in the ovary. Within the receptor complex, type-2 receptors (ACVR2A and/or ACVR2B) act as a primary activin receptors whereas the type-1 receptors like ACVR1B act as downstream transducers of activin signals. Activin binds to type-2 receptor at the plasma membrane and activates its serine-threonine kinase. The activated receptor type-2 then phosphorylates and activates the type-1 receptor such as ACVR1B. Once activated, the type-1 receptor binds and phosphorylates the SMAD proteins SMAD2 and SMAD3, on serine residues of the C-terminal tail. Soon after their association with the activin receptor and subsequent phosphorylation, SMAD2 and SMAD3 are released into the cytoplasm where they interact with the common partner SMAD4. This SMAD complex translocates into the nucleus where it mediates activin-induced transcription. Inhibitory SMAD7, which is recruited to ACVR1B through FKBP1A, can prevent the association of SMAD2 and SMAD3 with the activin receptor complex, thereby blocking the activin signal. Activin signal transduction is also antagonized by the binding to the receptor of inhibin-B via the IGSF1 inhibin coreceptor. ACVR1B also phosphorylates TDP2.