Polypeptides, catalysis

Keywords Design, Polypeptide, Catalysis, Metalloprotein, Heme, Structure, Protein folding, Glycopeptide. 

MSA Polypeptide Catalysis on Clays, Chemical Evolution NIH Bioadhesives, Adsorption of Macromolecules, Rheology. 

Carboxypeptidases are zinc-containing enzymes that catalyze the hydrolysis of polypeptides at the C-terminal peptide bond. The bovine enzyme form A is a monomeric protein comprising 307 amino acid residues. The structure was determined in the laboratory of William Lipscomb, Harvard University, in 1970 and later refined to 1.5 A resolution. Biochemical and x-ray studies have shown that the zinc atom is essential for catalysis by binding to the carbonyl oxygen of the substrate. This binding weakens the C =0 bond by... 

Serine proteinases such as chymotrypsin and subtilisin catalyze the cleavage of peptide bonds. Four features essential for catalysis are present in the three-dimensional structures of all serine proteinases a catalytic triad, an oxyanion binding site, a substrate specificity pocket, and a nonspecific binding site for polypeptide substrates. These four features, in a very similar arrangement, are present in both chymotrypsin and subtilisin even though they are achieved in the two enzymes in completely different ways by quite different three-dimensional structures. Chymotrypsin is built up from two p-barrel domains, whereas the subtilisin structure is of the a/p type. These two enzymes provide an example of convergent evolution where completely different loop regions, attached to different framework structures, form similar active sites. 

The aldehyde oxidoreductase from Desulfovibrio gigas shows 52% sequence identity with xanthine oxidase (199, 212) and is, so far, the single representative of the xanthine oxidase family. The 3D structure of MOP was analyzed at 1.8 A resolution in several states oxidized, reduced, desulfo and sulfo forms, and alcohol-bound (200), which has allowed more precise definition of the metal coordination site and contributed to the understanding of its role in catalysis. The overall structure, composed of a single polypeptide of 907 amino acid residues, is organized into four domains two N-terminus smaller domains, which bind the two types of [2Fe-2S] centers and two much larger domains, which harbor the molybdopterin cofactor, deeply buried in the molecule (Fig. 10). The pterin cofactor is present as a cytosine dinucleotide (MCD) and is 15 A away from the molecular surface,... 

The peptidyl transferase centre of the ribosome is located in the 50S subunit, in a protein-free environment (there is no protein within 15 A of the active site), supporting biochemical evidence that the ribosomal RNA, rather than the ribosomal proteins, plays a key role in the catalysis of peptide bond formation. This confirms that the ribosome is the largest known RNA catalyst (ribozyme) and, to date, the only one with synthetic activity. Adjacent to the peptidyl transferase centre is the entrance to the protein exit tunnel, through which the growing polypeptide chain moves out of the ribosome. 

DR. KENNETH KUSTIN (Brandeis University) Some years ago, you studied reactions of the type MX + Y = MY + X and found some interesting effects, such as chain reactions and phenomena of that sort. You also found that there was autocatalysis of such ligand substitution reactions by, I believe, triglycine. Has that turned up again Are other tripeptides or polypeptides autocatalytic How does that fit in with the base catalysis concept ... 

A research area in which obvious applications are to be found include the design of new catalysts and a number of examples have nowbeen reported of the catalysis of chemical reactions by designed folded polypeptides [11 -13]. So far, enzyme-like selectivities and efficiencies have not been achieved but, eventual-... 

Zinc proteases carboxypeptidase A and thermolysin have been extensively studied in solution and in the crystal (for reviews, see Matthews, 1988 Christianson and Lipscomb, 1989). Both carboxypeptidase A and thermolysin hydrolyze the amide bond of polypeptide substrates, and each enzyme displays specificity toward substrates with large hydrophobic Pi side chains such as phenylalanine or leucine. The exopeptidase carboxypeptidase A has a molecular weight of about 35K and the structure of the native enzyme has been determined at 1.54 A resolution (Rees et ai, 1983). Residues in the active site which are important for catalysis are Glu-270, Arg-127, (liganded by His-69, His-196, and Glu-72 in bidentate fashion), and the zinc-bound water molecule (Fig. 30). 

What can we do then in our laboratory We can resort to the observation of Eschemoser and Kisakiirek (1996) already mentioned in Chapter 1, according to which what is important is to show that the pathway is possible - in this particular case, that it is possible to construct many identical copies of a given long polypeptide or nucleotide sequence, capable of binding and catalysis. 

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