A Chemical Approach to the Pharmaceutical Optimization of an Anti-HIV Protein

Chemical protein synthesis is important for dissecting the molecular basis of protein function. Here we advance its scope by demonstrating the significant improvement of the multifaceted pharmaceutical profile of small proteins exclusively via a chemical-based approach. The focus of this work center...

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Veröffentlicht in:	Journal of the American Chemical Society 2007-10, Vol.129 (43), p.13153-13159
Hauptverfasser:	Miranda, Les P, Shao, Haiyan, Williams, Jason, Chen, Shiah-Yun, Kong, Ting, Garcia, Rod, Chinn, Yvonne, Fraud, Nathalie, O'Dwyer, Bill, Ye, Jay, Wilken, Jill, Low, Donald E, Cagle, E. Neil, Carnevali, Maia, Lee, Alexander, Song, Di, Kung, Ada, Bradburne, James A, Paliard, Xavier, Kochendoerfer, Gerd G
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Sprache:	eng
Schlagworte:	Amino Acids - chemistry Animals Anti-HIV Agents - chemistry Anti-HIV Agents - pharmacokinetics Chromatography, Gel HIV Antibodies - immunology Human Immunodeficiency Virus Proteins - immunology Male Models, Molecular Molecular Structure Polymers - chemistry Rats Receptors, G-Protein-Coupled - metabolism
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creator	Miranda, Les P Shao, Haiyan Williams, Jason Chen, Shiah-Yun Kong, Ting Garcia, Rod Chinn, Yvonne Fraud, Nathalie O'Dwyer, Bill Ye, Jay Wilken, Jill Low, Donald E Cagle, E. Neil Carnevali, Maia Lee, Alexander Song, Di Kung, Ada Bradburne, James A Paliard, Xavier Kochendoerfer, Gerd G
description	Chemical protein synthesis is important for dissecting the molecular basis of protein function. Here we advance its scope by demonstrating the significant improvement of the multifaceted pharmaceutical profile of small proteins exclusively via a chemical-based approach. The focus of this work centered on CCL-5 (RANTES) derivatives with potent anti-HIV activity. The overall chemical strategy involved a combination of coded and noncoded amino acid mutagenesis, peptide backbone engineering, and site-specific polymer attachment. The ability to alter specific protein residues, as well as precise control of the position and type of polymer attachment, allows for the exploration of specific molecular designs and resulted in novel CCL-5 analogues with significant differences in their respective biochemical and pharmaceutical properties. Using this approach, the complex-interplay of variables contributing to the noncovalent self-association (aggregation) state, CCR-5 specificity, in vivo elimination half-life, and anti-HIV activity of CCL-5-based protein analogues could be empirically evaluated via total chemical synthesis. This work has led to the identification of potent (sub-nanomolar) anti-HIV proteins with significantly improved pharmaceutical profiles, and illustrates the increasing value of protein chemical synthesis in contemporary therapeutic discovery. These antiviral molecules provide a novel mechanism of action for the development of a new generation of anti-HIV therapeutics which are still desperately needed.
doi_str_mv	10.1021/ja073982h
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The overall chemical strategy involved a combination of coded and noncoded amino acid mutagenesis, peptide backbone engineering, and site-specific polymer attachment. The ability to alter specific protein residues, as well as precise control of the position and type of polymer attachment, allows for the exploration of specific molecular designs and resulted in novel CCL-5 analogues with significant differences in their respective biochemical and pharmaceutical properties. Using this approach, the complex-interplay of variables contributing to the noncovalent self-association (aggregation) state, CCR-5 specificity, in vivo elimination half-life, and anti-HIV activity of CCL-5-based protein analogues could be empirically evaluated via total chemical synthesis. This work has led to the identification of potent (sub-nanomolar) anti-HIV proteins with significantly improved pharmaceutical profiles, and illustrates the increasing value of protein chemical synthesis in contemporary therapeutic discovery. 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The overall chemical strategy involved a combination of coded and noncoded amino acid mutagenesis, peptide backbone engineering, and site-specific polymer attachment. The ability to alter specific protein residues, as well as precise control of the position and type of polymer attachment, allows for the exploration of specific molecular designs and resulted in novel CCL-5 analogues with significant differences in their respective biochemical and pharmaceutical properties. Using this approach, the complex-interplay of variables contributing to the noncovalent self-association (aggregation) state, CCR-5 specificity, in vivo elimination half-life, and anti-HIV activity of CCL-5-based protein analogues could be empirically evaluated via total chemical synthesis. This work has led to the identification of potent (sub-nanomolar) anti-HIV proteins with significantly improved pharmaceutical profiles, and illustrates the increasing value of protein chemical synthesis in contemporary therapeutic discovery. These antiviral molecules provide a novel mechanism of action for the development of a new generation of anti-HIV therapeutics which are still desperately needed.</description><subject>Amino Acids - chemistry</subject><subject>Animals</subject><subject>Anti-HIV Agents - chemistry</subject><subject>Anti-HIV Agents - pharmacokinetics</subject><subject>Chromatography, Gel</subject><subject>HIV Antibodies - immunology</subject><subject>Human Immunodeficiency Virus Proteins - immunology</subject><subject>Male</subject><subject>Models, Molecular</subject><subject>Molecular Structure</subject><subject>Polymers - chemistry</subject><subject>Rats</subject><subject>Receptors, G-Protein-Coupled - metabolism</subject><issn>0002-7863</issn><issn>1520-5126</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2007</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNpt0D1PwzAQBmALgWgpDPwB5IWBIeCP2E7GqAJa0dJKBFbLThzFpfmQ40rAryeQqixMp9M9utO9AFxidIsRwXcbhQSNI1IegTFmBAUME34MxgghEoiI0xE467pN34YkwqdghEWMWcSjMVgmcFqaymZqC5O2dY3KSugb6EsD16VylcrMzv-OV623lf1S3jY1bAqoapjU3gaz-Rtcu8YbW5-Dk0JtO3OxrxPw-nCfTmfBYvU4nyaLQFGGfcBVbkIc59TQkGQcGxEpwwpMYlyILI6YNoVWmOpYKxYXmjOkBeK5EKE2WDM6ATfD3sw1XedMIVtnK-U-JUbyJxJ5iKS3V4Ntd7oy-Z_cZ9CDYAC28-bjMFfuXXJBBZPp-kWKWfq0mKZL-dz768GrrJObZufq_tV_Dn8DMfF2xg</recordid><startdate>20071031</startdate><enddate>20071031</enddate><creator>Miranda, Les P</creator><creator>Shao, Haiyan</creator><creator>Williams, Jason</creator><creator>Chen, Shiah-Yun</creator><creator>Kong, Ting</creator><creator>Garcia, Rod</creator><creator>Chinn, Yvonne</creator><creator>Fraud, Nathalie</creator><creator>O'Dwyer, Bill</creator><creator>Ye, Jay</creator><creator>Wilken, Jill</creator><creator>Low, Donald E</creator><creator>Cagle, E. 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The overall chemical strategy involved a combination of coded and noncoded amino acid mutagenesis, peptide backbone engineering, and site-specific polymer attachment. The ability to alter specific protein residues, as well as precise control of the position and type of polymer attachment, allows for the exploration of specific molecular designs and resulted in novel CCL-5 analogues with significant differences in their respective biochemical and pharmaceutical properties. Using this approach, the complex-interplay of variables contributing to the noncovalent self-association (aggregation) state, CCR-5 specificity, in vivo elimination half-life, and anti-HIV activity of CCL-5-based protein analogues could be empirically evaluated via total chemical synthesis. This work has led to the identification of potent (sub-nanomolar) anti-HIV proteins with significantly improved pharmaceutical profiles, and illustrates the increasing value of protein chemical synthesis in contemporary therapeutic discovery. These antiviral molecules provide a novel mechanism of action for the development of a new generation of anti-HIV therapeutics which are still desperately needed.</abstract><cop>United States</cop><pub>American Chemical Society</pub><pmid>17915868</pmid><doi>10.1021/ja073982h</doi><tpages>7</tpages></addata></record>
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subjects	Amino Acids - chemistry Animals Anti-HIV Agents - chemistry Anti-HIV Agents - pharmacokinetics Chromatography, Gel HIV Antibodies - immunology Human Immunodeficiency Virus Proteins - immunology Male Models, Molecular Molecular Structure Polymers - chemistry Rats Receptors, G-Protein-Coupled - metabolism
title	A Chemical Approach to the Pharmaceutical Optimization of an Anti-HIV Protein
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