T9154-01J
Clone Type
MonoclonalHost
MouseSource
PorcineIsotype
IgG1Clone Number
TU-01Grade
Affinity PurifiedApplications
FC IC IHC IP WBCrossreactivity
Hu Mo Po YeGene ID
7277Shipping Temp
Blue IceStorage Temp
-20°CMouse Anti-Tubulin, alpha, NT (Alpha Tubulin, Tubulin alpha Ubiquitous, H2-Alpha, K-alpha-1, TUBA3, Tubulin alpha 1 Chain, TUBA1, TUBA1A, Tubulin K alpha 1)
The microtubules are intracellular dynamic polymers made up of evolutionarily conserved polymorphic alpha/beta-tubulin heterodimers and a large number of microtubule-associated proteins (MAPs). The microtubules consist of 13 protofilaments and have an outer diameter 25 nm. Microtubules have their intrinsic polarity; highly dynamic plus ends and less dynamic minus ends. Microtubules are required for vital processes in eukaryotic cells including mitosis, meiosis, maintenance of cell shape and intracellular transport. Microtubules are also necessary for movement of cells by means of flagella and cilia. In mammalian tissue culture cells microtubules have their minus ends anchored in microtubule organizing centers (MTOCs). The GTP (guanosintriphosphate) molecule is an essential for tubulin heterodimer to associate with other heterodimers to form microtubule. In vivo, microtubule dynamics vary considerably. Microtubule polymerization is reversible and a populations of microtubules in cells are on their minus ends either growing or shortening – this phenomenon is called dynamic instability of microtubules. On a practical level, microtubules can easily be stabilized by the addition of non-hydrolysable analogues of GTP (eg. GMPPCP) or more commonly by anti-cancer drugs such as Taxol. Taxol stabilizes microtubules at room temperature for many hours. Using limited proteolysis by enzymes both tubulin subunits can be divided into N-terminal and C-terminal structural domains. The alpha-tubulin (relative molecular weight around 50 kDa) is globular protein that exists in cells as part of soluble alpha/beta-tubulin dimer or it is polymerized into microtubules. In different species it is coded by multiple tubulin genes that form tubulin classes (in human 6 genes). Expressed tubulin genes are named tubulin isotypes. Some of the tubulin isotypes are expressed ubiquitously, while some have more restricted tissue expression. Alpha-tubulin is also subject of numerous post-translational modifications. Tubulin isotypes and their posttranslational modifications are responsible for multiple tubulin charge variants - tubulin isoforms. Heterogeneity of alpha-tubulin is concentrated in C-terminal structural domain.
Applications
Suitable for use in Western Blot, Flow Cytometry, Immunoprecipitation, Immunohistochemistry and Immunocytochemistry. Other applications not tested.
Recommended Dilution
Flow Cytometry: 1-4ug/ml using intracellular staining Western Blot: 1-2ug/ml under reducing conditions Immunohistochemistry: paraffin sections Optimal dilutions to be determined by the researcher.
Storage and Stability
May be stored at 4°C for short-term only. Aliquot to avoid repeated freezing and thawing. Store at -20°C. Aliquots are stable for 12 months after receipt. For maximum recovery of product, centrifuge the original vial after thawing and prior to removing the cap.
Immunogen
Fraction of tubulin purified from porcine brain by two cycles of polymerization - depolymerization.
Form
Supplied as a liquid in PBS, pH 7.4, 0.09% sodium azide.
Purity
Purified by Protein A affinity chromatography.
Specificity
Recognizes a defined epitope (aa65-97) on N-terminal structural domain of porcine alpha-tubulin. Species Crossreactivity: mouse, human, turkey, Eisenia, Paramecium, Nicotiana, Yeast and Arabidopsis
Intended for research use only. Not for use in human, therapeutic, or diagnostic applications.
References
1. Viklicky V, Draber P, Hasek J, Bartek J.: Production and characterization of a monoclonal antitubulin antibody. Cell Biol Int Rep. 1982 Aug;6(8):725-31. 2. Grimm M, Breitling F, Little M.: Location of the epitope for the alpha-tubulin monoclonal antibody TU-O1. Biochim Biophys Acta. 1987 Jul 24;914(1):83-8. 3. Linhartova I, Draber P, Draberova E, Viklicky V.: Immunological discrimination of|beta-tubulin isoforms in developing mouse brain. Post-translational modification of non-class-III beta-tubulins. Biochem J. 1992 Dec 15;288 ( Pt 3):919-24. 4. Draber P, Draberova E, Zicconi D, Sellitto C, Viklicky V, Cappuccinelli P.: Heterogeneity of microtubules recognized by monoclonal antibodies to alpha-tubulin. Eur J Cell Biol. 1986 Jun;41(1):82-8. 5. Draber P, Draberova E, Linhartova I, Viklicky V.: Differences in the exposure of C- and N-terminal tubulin domains in cytoplasmic microtubules detected with domain-specific monoclonal antibodies. J Cell Sci. 1989 Mar;92 ( Pt 3):519-28. 6. Draber P, Draberova E, Viklicky V.: Immunostaining of human spermatozoa with tubulin domain-specific monoclonal antibodies. Recognition of a unique beta tubulin epitope in the sperm head. Histochemistry. 1991;95 (5):519-24. 7. Smertenko A, Blume Y, Viklicky V, Opatrny Z, Draber P.: Post-translational modifications and multiple tubulin isoforms in Nicotiana tabacum L. cells. Planta. 1997;201(3):349-58.USBio References
No references available