Anti-Xylan 4 [CCRC-M150, 5C6.A3.C6.F6.G6] Antibody (supernatant)
![Anti-Xylan 4 [CCRC-M150, 5C6.A3.C6.F6.G6] Antibody (supernatant)](https://www.kerafast.com/MediaStorage/Product/Images/Large/1322_2001202001264313210.jpg "Anti-Xylan 4 [CCRC-M150, 5C6.A3.C6.F6.G6] Antibody (supernatant)")
This mouse IgG3k monoclonal antibody was generated against glycan and recognizes corn, sorghum, possibly others xylan-4.
Highlights:
- Reacts with corn, sorghum, possibly others xylan-4
- Suitable for ELISA, Immunolabeling and Immunofluorscence applications
Xylan is a group of hemicelluloses that reside in plant cells walls and also can be found in some algae (both green and red). Xylans are polysaccharides whose backbone consists of beta-1,4-linked xylosyl residues. This backbone can be substituted with side-chains of arabinosyl, glucuronosyl, and 4-O-mthylglucuronosyl residues, and can also be further modified by acetyl substitution on the hydroxyls of the xylosyl residues.
From the laboratory of Michael G. Hahn, PhD, University of Georgia.
This mouse IgG3k monoclonal antibody was generated against glycan and recognizes corn, sorghum, possibly others xylan-4.
Highlights:
- Reacts with corn, sorghum, possibly others xylan-4
- Suitable for ELISA, Immunolabeling and Immunofluorscence applications
Xylan is a group of hemicelluloses that reside in plant cells walls and also can be found in some algae (both green and red). Xylans are polysaccharides whose backbone consists of beta-1,4-linked xylosyl residues. This backbone can be substituted with side-chains of arabinosyl, glucuronosyl, and 4-O-mthylglucuronosyl residues, and can also be further modified by acetyl substitution on the hydroxyls of the xylosyl residues.
From the laboratory of Michael G. Hahn, PhD, University of Georgia.
| Product Type: | Antibody |
| Antigen: | Xylan-4 |
| Accession ID: | CCRC M150 |
| Isotype: | IgG3k |
| Clonality: | Monoclonal |
| Clone Name: | CCRC M150 : 5C6.A3.C6.F6.G6 |
| Reactivity: | Corn, sorghum, possibly others |
| Immunogen: | Glycan |
| Species Immunized: | Mouse |
| Buffer: | Cell culture supernatant |
| Tested Applications: | ELISA, Immunolabeling, IF |
| Storage: | <1 month at 4C, >1 month at -80C |
| Shipped: | Cold Packs |
Notes:
Also reacts (weekly) with Phormium cookianum (New Zealand Mountain Flax) high arabinose xylan.
Immunolocalization data indicate that CCRC-M8 binds to an epitope that is distinct from that recognized by CCRC-M7.
These monoclonal antibodies were developed under the sponsorship of the US National Science Foundation, through award number DBI-0421683. Their use in biomass characterization, study of biomass deconstruction and quantitation was developed under the sponsorship of the US Department of Energy through awards DE-PS02-06ER64304 and DE-AC05-00OR22725 (BioEenergy Science Center).
- Robin E. Young, Heather E. McFarlane, Michael G. Hahn, Tamara L. Western, George W. Haughn and A. Lacey Samuels. 2008. Analysis of the Golgi Apparatus in Arabidopsis Seed Coat Cells during Polarized Secretion of Pectin-Rich Mucilage. The Plant Cell June 2008 vol. 20 no. 6 1623-1638 .
- DeMartini, JD, Pattathil, S, Avci, U, Szekalski, K, Mazumder, K, Hahn, M.G., Wyman, CE: Application of monoclonal antibodies to investigate plant cell wall deconstruction for biofuels production. Energy Environ. Sci., 2011, 4, 4332-4339.
- Pattathil S, Avci U, Miller JS, Hahn MG. 2012. Immunological approaches to plant cell wall and biomass characterization: Glycome profiling. In: Himmel M (ed) Biomass Conversion: Methods and Protocols. Springer Science + Business Media, LLC, New York, NY, pp 61-72.
- A.P. de Souza, D.C.C. Leite, S. Pattahil, M.G. Hahn, M.S. Buckeridge. 2013. Composition and structure of sugarcane cell wall polysaccharides: Implications for second generation bioethanol production. Bioenergy Research 6: 564-579.
- J. Puhlmann, E. Bucheli, M. J. Swain, N. Dunning, P. Albersheim, A. G. Darvill, and M. G. Hahn. (1994) Generation of monoclonal antibodies against plant cell wall polysaccharides. I. Characterization of a monoclonal antibody to a terminal alpha-(1,2)-linked fucosyl-containing epitope. Plant Physiol. 104:699-710.
- G. Freshour, R. P. Clay, M. S. Fuller, P. Albersheim, A. G. Darvill, and M. G. Hahn. (1996) Developmental and tissue-specific structural alterations of the cell-wall polysaccharides of Arabidopsis thaliana roots. Plant Physiol. 110:1413-1429.
- G. Freshour, C. P. Bonin, W.-D. Reiter, P. Albersheim, A. G. Darvill, and M. G. Hahn. (2003) Distribution of fucose-containing xyloglucans in cell walls of the mur1 mutant of Arabidopsis thaliana. Plant Physiol. 131:1602-1612.
- Pattathil S, Avci U, Baldwin D, Swennes AG, McGill JA, Popper Z, Bootten T, Albert A, Davis RH, Chennareddy C, Dong R, O'Shea B, Rossi R, Leoff C, Freshour G, Narra R, O'Neil M, York WS, Hahn MG. (2010) A Comprehensive Toolkit of Plant Cell Wall Glycan-Directed Monoclonal Antibodies. Plant Physiol. 153:514-525.
- Pattathil S, Avci U, Miller JS, Hahn MG. 2012. Immunological approaches to plant cell wall and biomass characterization: Glycome profiling. In: Himmel M (ed) Biomass Conversion: Methods and Protocols. Springer Science + Business Media, LLC, New York, NY, pp 61-72.
- Pattathil S, Avci U, Baldwin D, et al. 2010. A comprehensive toolkit of plant cell wall glycan-directed monoclonal antibodies. Plant Physiology 153, 514-525.
- Pattathil S, Hahn MG, Dale BE, Chundawat SP. Insights into plant cell wall structure, architecture, and integrity using glycome profiling of native and AFEXTM-pre-treated biomass. J Exp Bot. 2015 Jul;66(14):4279-94.
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