Phosphosolutions公司Anti-Adenylate Cyclase III-NEW产品代理

 our focus 专业特色

PhosphoSolutions公司专注于蛋白质组学中的一个（10-20%）含量的小部分磷蛋白质。磷蛋白是监管控制组蛋白质的关键,这一部分是被称为phosphosome蛋白质。磷蛋白被认为是在神经系统疾病如老年痴呆症和癌症方面的关键元素，实质上,phosphosome是蛋白质组学作物的精华。

公司目标

简明概述：我们要成为世界上的磷蛋白组的提供者。

方案#1， 特异性磷抗体：首先我们要准备磷蛋白组。在激活或磷酸化状态下磷蛋白组是蛋白质识别研究中的*关键工具。

Antibodies 抗体

特异性磷抗体：Detection and quantitation of changes in the state of phosphorylation of specific proteins is of great utility in the quest to establish the function of a given protein and the consequences of its reversible phosphorylation. Two methods commonly used to measure protein phosphorylation and dephosphorylation in cell preparations employ prelabeling with 32Pi or back phosphorylation. These methods continue to be very effective and have advantages for many test systems, but they do have several practical and theoretical limitations （Nestler and Greengard, 1984）. Based in large part on the successful use of short synthetic peptides to produce epitope-targeted antibodies （Lerner, 1982;Sutcliffe et al., 1983）, an immunochemical approach became an attractive alternative for detecting changes in the state of phosphorylation of specific proteins at a specific site. The use of phosphorylation state-specific antibodies takes advantage of the sensitivity and selectivity afforded by immunochemical methodology, combined with relatively simple preparation and potentially broad applications.

The first report of phosphorylation-dependent antibodies appeared in 1981, when polyclonal antibodies that could detect phosphotyrosine-containing proteins were produced by immunization with benzyl phosphonate conjugated to keyhole limpet hemocyanin （KLH） （Ross et al., 1981）. Shortly thereafter, Nairn and colleagues reported the production of serum antibodies that distinguished between the phospho- and dephospho-forms of G-substrate, a protein localized to cerebellar Purkinje cells and phosphorylated by cGMP-dependent protein kinase （Nairn et al., 1982）. A synthetic heptapeptide, Arg-Lys-Asp-Thr-Pro-Ala-Leu, corresponding to a repeated sequence surrounding two phosphorylated threonyl residues in the intact protein, served as antigen. Rabbit antisera against a peptide-KLH conjugate were specific for the dephospho-form of G-substrate. Phospho-specific antibodies were prepared by immunization of rabbits with the purified phosphoprotein, phosphorylated in vitro to a stoichiometry of 2 mol/mol with cGMP-dependent protein kinase. Despite this initial success, other attempts in our laboratory to produce phospho-specific polyclonal antisera by immunization with the phospho-form of intact proteins were not very successful, probably because of two significant factors. First, many phosphorylated proteins are believed to undergo rapid dephosphorylation during immunization, regardless of the route of injection, leading to the loss of the desired phospho-epitope. Second, holoproteins generally contain multiple immunogenic epitopes; this decreases the probability that colonal dominance for a phospho-specific epitope will be obtained.

Taking a more direct approach utilizing phosphorylated and unphosphorylated forms of synthetic phosphopeptides, we developed a general protocol for the production of phosphorylation state-specific antibodies for substrates with established site（s） of phosphorylation （Czernik et al., 1991））. In early stages of our development of this methodology, phosphopeptides were routinely prepared by enzymatic phosphorylation （Czernik et al., 1991）. Although this approach remains perfectly valid today, the preparation of synthetic phosphopeptides using Fmoc derivatives of phosphoamino acids has become the state-of-the-art （Czernik et al., 1995;Czernik et al., 1996）. Likewise, we have examined the use of both polyclonal and monoclonal techniques for antibody production. Given the high success rate that we and others have obtained with the polyclonal technique, it has become the method of choice, because it is an easier and less costly method for the average laboratory. However, when appropriate, this approach can be readily adapted for monoclonal antibody production.

参考文献

1. Czernik AJ, Girault J-A, Nairn AC, Chen J, Snyder G, Kebabian J, Greengard P （1991） Production of phosphorylation state-specific antibodies. Methods Enzymol 201: 264-283.

2. Czernik AJ, Mathers J, Mische SM （1997） Phosphorylation state-specific antibodies. Neuromethods: Regulatory Protein Modification: Techniques & Protocols 30: 219-250.

3. Czernik AJ, Mathers J, Tsou K, Greengard P, Mische SM （1995） Phosphorylation state-specific antibodies: preparation and applications. Neuroprotocols 6: 56-61.

4. Lerner, R. A. Tapping the immunological repertoire to produce antibodies of predetermined specificity. Nature 299, 593-596. 1982.

5. Nairn AC, Detre JA, Casnellie JE, Greengard P （1982） Serum antibodies that distinguish between the phospho- and dephospho-forms of a phosphoprotein. Nature （Lond ） 299: 734-736.

6. Nestler, E. J. and Greengard, P. Protein Phosphorylation in the Nervous System. Nestler and Greengard. Protein Phosphorylation in the Nervous System. [8], 255-299. 1984. New York, Wiley. 

8. Sutcliffe JG, Shinnick TM, Green N, Lerner RA （1983） Antibodies that react with predetermined sites on proteins. Science 219: 660-666.

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Item:	Anti-Adenylate Cyclase III-NEW!
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SKU/Catalog Number:	85-AC3
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