Mouse anti Cytokeratin 13 / Keratin K13
| Code | Size | Price |
|---|
| MUB0322P | 0.1 mg | £326.00 |
Quantity:
Prices exclude any Taxes / VAT
Overview
Host Type: Mouse
Antibody Isotype: IgG2a
Antibody Clonality: Monoclonal
Antibody Clone: 1C7
Regulatory Status: RUO
Target Species:
- Fish
- Human
Applications:
- Immunohistochemistry (IHC)
- Western Blot (WB)
Storage:
Store at 4°C or in small aliquots at -20°C.
Documents
Further Information
Applications Description:
1C7 is suitable for immunoblotting and immunohistochemistry on frozen tissues. Optimal antibody dilution should be determined by titration; recommended range is 1:25 ? 1:200 for immunohistochemistry with avidin-biotinylated Horseradish peroxidase complex (ABC) as detection reagent, and 1:100 ? 1:1000 for immunoblotting applications.
Background:
Cytokeratins are a subfamily of intermediate filament proteins and are characterized by a remarkable biochemical diversity, represented in Human epithelial tissues by at least 20 different polypeptides. They range in molecular weight between 40 kDa and 68 kDa and isoelectric pH between 4.9 ? 7.8. The individual Human Cytokeratins are numbered 1 to 20. The various epithelia in the Human body usually express Cytokeratins which are not only characteristic of the type of epithelium, but also related to the degree of matuRation or differentiation within an epithelium. Cytokeratin subtype expression patterns are used to an increasing extent in the distinction of different types of epithelial malignancies. The Cytokeratin antibodies are not only of assistance in the differential diagnosis of tumors using immunohistochemistry on tissue sections, but are also a useful tool in cytopathology and flow cytometric assays.
Caution:
This product is intended FOR RESEARCH USE ONLY, and FOR TESTS IN VITRO, not for use in diagnostic or therapeutic procedures involving humans or animals.
This product contains sodium azide. To prevent formation of toxic vapors, do not mix with strong acidic solutions. To prevent formation of potentially explosive metallic azides in metal plumbing, always wash into drain with copious quantities of water.
This datasheet is as accurate as reasonably achievable, but Nordic-MUbio accepts no liability for any inaccuracies or omissions in this information.
This product contains sodium azide. To prevent formation of toxic vapors, do not mix with strong acidic solutions. To prevent formation of potentially explosive metallic azides in metal plumbing, always wash into drain with copious quantities of water.
This datasheet is as accurate as reasonably achievable, but Nordic-MUbio accepts no liability for any inaccuracies or omissions in this information.
Field of Interest:
Cytoskeleton
Formulation:
Each vial contains 100 ul 1 mg/ml purified monoclonal antibody in PBS containing 0.09% sodium azide.
Product:
Each vial contains 100 ul 1 mg/ml purified monoclonal antibody in PBS containing 0.09% sodium azide.
Source:
1C7 is a Mouse monoclonal IgG2a antibody derived by fusion of SP2/0 Mouse myeloma cells with spleen cells from a BALB/c Mouse immunized with a Cytokeratin preparation extracted from Human esophagus.
Specificity:
1C7 reacts exclusively with Cytokeratin 13 which is present in non-cornified squamous epithelia, except cornea, and transitional epithelial regions, with the exception of basal cell layers of some stRatified epithelia.
UniProt:
P13646
References
1. van Muijen, G. N., Ruiter, D. J., Franke, W. W., Achtstatter, T., Haasnoot, W. H., Ponec, M., and Warnaar, S. O. (1986). Cell type heterogeneity of Cytokeratin expression in complex epithelia and carcinomas as demonstrated by monoclonal antibodies specific for Cytokeratins nos. 4 and 13, Exp Cell Res 162, 97-113.
2. Weikel, W., Wagner, R., and Moll, R. (1987). Characterization of subcolumnar reserve cells and other epithelia of Human uterine cervix. Demonstration of diverse Cytokeratin polypeptides in reserve cells, Virchows Arch B Cell Pathol Incl Mol Pathol 54, 98-110.
3. Smedts, F., Ramaekers, F., Robben, H., Pruszczynski, M., van Muijen, G., Lane, B., Leigh, I., and Vooijs, P. (1990). Changing patterns of Keratin expression during progression of cervical intraepithelial neoplasia, Am J Pathol 136, 657-68.
4. van Niekerk, C. C., Boerman, O. C., Ramaekers, F. C., and Poels, L. G. (1991). Marker profile of different phases in the transition of normal Human ovarian epithelium to ovarian carcinomas, Am J Pathol 138, 455-63.
5. Smedts, F., Ramaekers, F., Troyanovsky, S., Pruszczynski, M., Link, M., Lane, B., Leigh, I., Schijf, C., and Vooijs, P. (1992). Keratin expression in cervical cancer, Am J Pathol 141, 497-511.
6. Bauwens, L. J., De Groot, J. C., Ramaekers, F. C., Veldman, J. E., and Huizing, E. H. (1992). Expression of intermediate filament proteins in the adult Human vestibular labyrinth, Ann Otol Rhinol Laryngol 101, 479-86.
7. Van Niekerk, C. C., Ramaekers, F. C., Hanselaar, A. G., Aldeweireldt, J., and Poels, L. G. (1993). Changes in expression of differentiation markers between normal ovarian cells and derived tumors, Am J Pathol 142, 157-77.
8. van Dorst, E. B., van Muijen, G. N., Litvinov, S. V., and Fleuren, G. J. (1998). The limited difference between Keratin patterns of squamous cell carcinomas and adenocarcinomas is explicable by both cell lineage and state of differentiation of tumour cells, J Clin Pathol 51, 679-84.
2. Weikel, W., Wagner, R., and Moll, R. (1987). Characterization of subcolumnar reserve cells and other epithelia of Human uterine cervix. Demonstration of diverse Cytokeratin polypeptides in reserve cells, Virchows Arch B Cell Pathol Incl Mol Pathol 54, 98-110.
3. Smedts, F., Ramaekers, F., Robben, H., Pruszczynski, M., van Muijen, G., Lane, B., Leigh, I., and Vooijs, P. (1990). Changing patterns of Keratin expression during progression of cervical intraepithelial neoplasia, Am J Pathol 136, 657-68.
4. van Niekerk, C. C., Boerman, O. C., Ramaekers, F. C., and Poels, L. G. (1991). Marker profile of different phases in the transition of normal Human ovarian epithelium to ovarian carcinomas, Am J Pathol 138, 455-63.
5. Smedts, F., Ramaekers, F., Troyanovsky, S., Pruszczynski, M., Link, M., Lane, B., Leigh, I., Schijf, C., and Vooijs, P. (1992). Keratin expression in cervical cancer, Am J Pathol 141, 497-511.
6. Bauwens, L. J., De Groot, J. C., Ramaekers, F. C., Veldman, J. E., and Huizing, E. H. (1992). Expression of intermediate filament proteins in the adult Human vestibular labyrinth, Ann Otol Rhinol Laryngol 101, 479-86.
7. Van Niekerk, C. C., Ramaekers, F. C., Hanselaar, A. G., Aldeweireldt, J., and Poels, L. G. (1993). Changes in expression of differentiation markers between normal ovarian cells and derived tumors, Am J Pathol 142, 157-77.
8. van Dorst, E. B., van Muijen, G. N., Litvinov, S. V., and Fleuren, G. J. (1998). The limited difference between Keratin patterns of squamous cell carcinomas and adenocarcinomas is explicable by both cell lineage and state of differentiation of tumour cells, J Clin Pathol 51, 679-84.