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Generating New Molecular Function: A Lesson from Nature

Identifieur interne : 002448 ( Istex/Curation ); précédent : 002447; suivant : 002449

Generating New Molecular Function: A Lesson from Nature

Auteurs : David R. Liu ; Peter G. Schultz

Source :

Angewandte Chemie International Edition [ 1433-7851 ] ; 1999-01-15.

RBID : ISTEX:D243E53A20449131F184C16875EAD73207151498

English descriptors

Teeft :
- Acad, Acyl transfer reactions, Amino, Amino acid, Amino acids, Amplification, Angew, Antibody, Antibody diversity, Antibody molecule, Bacterial expression, Bind, Bind antibodies, Binding affinities, Binding affinity, Binding site, Biological properties, Biosynthetic machinery, Broader range, Building blocks, Carbon carbon bond, Catalysis, Catalyst, Catalytic, Catalytic activity, Catalytic antibodies, Catalytic function, Catalyze, Chem, Chemical properties, Chemical structures, Chemical synthesis, Combinatorial, Combinatorial approaches, Combinatorial arrays, Combinatorial association, Combinatorial libraries, Combinatorial library, Combinatorial methods, Combinatorial processes, Combinatorial strategies, Combinatorial synthesis, Computational methods, Conformational diversity, Crystal structure, Cyclic peptides, Diverse collections, Diverse populations, Dower, Drug discovery, Extracellular domain, Ferroelectric materials, Filamentous phage, General scheme, Hapten, High affinity, High sensitivity, Howard hughes, Hydrogen bonds, Immune, Immune system, Immunological diversity, Important role, Impressive examples, Ketone substrate, Large libraries, Large number, Lerner, Ligand, Major impact, Materials science, Metal oxides, Molecular diversity, Molecular diversity reviews, Molecular structure, Molecule, Monomer, Multipin synthesis, Mutant, Mutant proteins, Mutation, Natl, Natural diversity, Natural ligand, Natural products, Nonpolymeric molecules, Novel properties, Nucleic, Nucleic acids, Oligomeric molecules, Oligonucleotide, Oligonucleotide probes, Other receptors, Peptide, Peptide sequences, Pericyclic reactions, Personal communication, Phage, Phage display, Phage display techniques, Physical properties, Polypeptide, Polypeptide chain, Porphyrin ring, Prebiotic world, Proc, Protein catalysts, Protein function, Protein sequence, Recent example, Receptor, Ribozyme, Rna, Schematic representation, Schultz, Selective ligands, Side chains, Significant impact, Similar approaches, Small molecules, Small number, Solid support, Somatic mutation, Somatic mutations, Structural basis, Structural information, Successful isolation, Such example, Synthetic diversity, Synthetic molecules, Szostak, Tangent loss, Tetrahedron lett, Transition state, Unpublished results, Wang, Wide array, Wide variety, Xiang.

Abstract

Trying to model nature: Nature has evolved new molecular function by creating diverse collections of chemical structures and selecting for molecules with desired biological properties. An example of this is the recombination of germ‐line genes for the formation of antibodies with refined specificities (see scheme). Chemists, biologists, and physicists are now employing this combinatorial approach with great success to generate molecules with properties never before observed in nature or in the laboratory.

Url:

https://api.istex.fr/ark:/67375/WNG-R8G1JBSV-3/fulltext.pdf

DOI: 10.1002/(SICI)1521-3773(19990115)38:1/2<36::AID-ANIE36>3.0.CO;2-I

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David R. Liu

<affiliation><mods:affiliation>Howard Hughes Medical Institute (and) Department of Chemistry, University of California, Berkeley, Berkeley, CA 94720–1460 (USA), Fax: (+1) 510‐643‐6890</mods:affiliation>
<wicri:noCountry code="subField">(+1) 510‐643‐6890</wicri:noCountry>
</affiliation>

Peter G. Schultz

<affiliation><mods:affiliation>E-mail: pgschultz@lbl.gov</mods:affiliation>
<wicri:noCountry code="no comma">E-mail: pgschultz@lbl.gov</wicri:noCountry>
</affiliation>

Le document en format XML

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<term>Acyl transfer reactions</term>
<term>Amino</term>
<term>Amino acid</term>
<term>Amino acids</term>
<term>Amplification</term>
<term>Angew</term>
<term>Antibody</term>
<term>Antibody diversity</term>
<term>Antibody molecule</term>
<term>Bacterial expression</term>
<term>Bind</term>
<term>Bind antibodies</term>
<term>Binding affinities</term>
<term>Binding affinity</term>
<term>Binding site</term>
<term>Biological properties</term>
<term>Biosynthetic machinery</term>
<term>Broader range</term>
<term>Building blocks</term>
<term>Carbon carbon bond</term>
<term>Catalysis</term>
<term>Catalyst</term>
<term>Catalytic</term>
<term>Catalytic activity</term>
<term>Catalytic antibodies</term>
<term>Catalytic function</term>
<term>Catalyze</term>
<term>Chem</term>
<term>Chemical properties</term>
<term>Chemical structures</term>
<term>Chemical synthesis</term>
<term>Combinatorial</term>
<term>Combinatorial approaches</term>
<term>Combinatorial arrays</term>
<term>Combinatorial association</term>
<term>Combinatorial libraries</term>
<term>Combinatorial library</term>
<term>Combinatorial methods</term>
<term>Combinatorial processes</term>
<term>Combinatorial strategies</term>
<term>Combinatorial synthesis</term>
<term>Computational methods</term>
<term>Conformational diversity</term>
<term>Crystal structure</term>
<term>Cyclic peptides</term>
<term>Diverse collections</term>
<term>Diverse populations</term>
<term>Dower</term>
<term>Drug discovery</term>
<term>Extracellular domain</term>
<term>Ferroelectric materials</term>
<term>Filamentous phage</term>
<term>General scheme</term>
<term>Hapten</term>
<term>High affinity</term>
<term>High sensitivity</term>
<term>Howard hughes</term>
<term>Hydrogen bonds</term>
<term>Immune</term>
<term>Immune system</term>
<term>Immunological diversity</term>
<term>Important role</term>
<term>Impressive examples</term>
<term>Ketone substrate</term>
<term>Large libraries</term>
<term>Large number</term>
<term>Lerner</term>
<term>Ligand</term>
<term>Major impact</term>
<term>Materials science</term>
<term>Metal oxides</term>
<term>Molecular diversity</term>
<term>Molecular diversity reviews</term>
<term>Molecular structure</term>
<term>Molecule</term>
<term>Monomer</term>
<term>Multipin synthesis</term>
<term>Mutant</term>
<term>Mutant proteins</term>
<term>Mutation</term>
<term>Natl</term>
<term>Natural diversity</term>
<term>Natural ligand</term>
<term>Natural products</term>
<term>Nonpolymeric molecules</term>
<term>Novel properties</term>
<term>Nucleic</term>
<term>Nucleic acids</term>
<term>Oligomeric molecules</term>
<term>Oligonucleotide</term>
<term>Oligonucleotide probes</term>
<term>Other receptors</term>
<term>Peptide</term>
<term>Peptide sequences</term>
<term>Pericyclic reactions</term>
<term>Personal communication</term>
<term>Phage</term>
<term>Phage display</term>
<term>Phage display techniques</term>
<term>Physical properties</term>
<term>Polypeptide</term>
<term>Polypeptide chain</term>
<term>Porphyrin ring</term>
<term>Prebiotic world</term>
<term>Proc</term>
<term>Protein catalysts</term>
<term>Protein function</term>
<term>Protein sequence</term>
<term>Recent example</term>
<term>Receptor</term>
<term>Ribozyme</term>
<term>Rna</term>
<term>Schematic representation</term>
<term>Schultz</term>
<term>Selective ligands</term>
<term>Side chains</term>
<term>Significant impact</term>
<term>Similar approaches</term>
<term>Small molecules</term>
<term>Small number</term>
<term>Solid support</term>
<term>Somatic mutation</term>
<term>Somatic mutations</term>
<term>Structural basis</term>
<term>Structural information</term>
<term>Successful isolation</term>
<term>Such example</term>
<term>Synthetic diversity</term>
<term>Synthetic molecules</term>
<term>Szostak</term>
<term>Tangent loss</term>
<term>Tetrahedron lett</term>
<term>Transition state</term>
<term>Unpublished results</term>
<term>Wang</term>
<term>Wide array</term>
<term>Wide variety</term>
<term>Xiang</term>
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<front><div type="abstract" xml:lang="en">Trying to model nature: Nature has evolved new molecular function by creating diverse collections of chemical structures and selecting for molecules with desired biological properties. An example of this is the recombination of germ‐line genes for the formation of antibodies with refined specificities (see scheme). Chemists, biologists, and physicists are now employing this combinatorial approach with great success to generate molecules with properties never before observed in nature or in the laboratory.</div>
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Generating New Molecular Function: A Lesson from Nature

Generating New Molecular Function: A Lesson from Nature

Source :

English descriptors

Abstract

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