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C terminus

An amino acid sequence is ambiguous unless we know the direction m which to read It—left to right or right to left We need to know which end is the N terminus and which IS the C terminus As we saw m the preceding section carboxypeptidase catalyzed hydrolysis cleaves the C terminal ammo acid and so can be used to identify it What about the N terminus ... [Pg.1131]

Sanger also determined the sequence of the A chain and identified the cysteine residues involved m disulfide bonds befween fhe A and B chains as well as m fhe disulfide linkage wifhin fhe A chain The complefe insulin sfruefure is shown m Figure 27 11 The sfruefure shown is fhaf of bovine insulin (from cattle) The A chains of human insulin and bovine insulin differ m only fwo ammo acid residues fheir B chains are identical except for the ammo acid at the C terminus... [Pg.1132]

When Sanger s method for N terminal residue analysis was discussed you may have wondered why it was not done sequentially Simply start at the N terminus and work steadily back to the C terminus identifying one ammo acid after another The idea is fine but It just doesn t work well m practice at least with 1 fluoro 2 4 dimtrobenzene... [Pg.1134]

Deprotect the ammo group at the N terminus and the carboxyl group at the C terminus... [Pg.1137]

Its N terminus with a Z group and at its C terminus as a benzyl ester can be completely deprotected m a single operation... [Pg.1139]

Knowing how the protein chain is folded is a key ingredient m understanding the mechanism by which an enzyme catalyzes a reaction Take carboxypeptidase A for exam pie This enzyme catalyzes the hydrolysis of the peptide bond at the C terminus It is... [Pg.1146]

This reaction forms the basis of one method of terminal residue analysis A peptide is treated with excess hydrazine in order to cleave all the peptide linkages One of the terminal amino acids is cleaved as the free amino acid and identified all the other ammo acid residues are converted to acyl hydrazides Which amino acid is identified by hydrazmolysis the N terminus or the C terminus ... [Pg.1154]

Critical micelle concentration (Section 19 5) Concentration above which substances such as salts of fatty acids aggre gate to form micelles in aqueous solution Crown ether (Section 16 4) A cyclic polyether that via lon-dipole attractive forces forms stable complexes with metal 10ns Such complexes along with their accompany mg anion are soluble in nonpolar solvents C terminus (Section 27 7) The amino acid at the end of a pep tide or protein chain that has its carboxyl group intact—that IS in which the carboxyl group is not part of a peptide bond Cumulated diene (Section 10 5) Diene of the type C=C=C in which a single carbon atom participates in double bonds with two others... [Pg.1280]

Human growth hormone is a single polypeptide chain of 191 amino acids (qv) having two disulfide bonds, one between Cys-53 and Cys-165, forming a large loop in the molecule, and the other between Cys-182 and Cys-189, forming a small loop near the C-terminus. The stmcture of hGH is shown in Figure 1 molecular mass is 22,125 the empirical formula is C qH 29N 262 300 7 ... [Pg.195]

The smallest sequence possessing most of the neurotensin spectmm of activities and its high potency is the hexapeptide C-terminus (1). [D-Trp ]-Neurotensin acts like a neurotensin antagonist in perfused heart preparations, but acts like a full agonist in guinea pig atria and rat stomach strips (122). [Pg.204]

Atrial Natriuretic Peptide, a-Atrial natriuretic peptide [85637-73-6] (ANP) (55), also known as atrial natriuretic factor (ANF), brain natriuretic peptide (BNP) (56), and type C natriuretic peptide (CNP) (57) are members of the ANP family (28). These atrial peptides arise from a common 128 amino acid precursor where the active form of ANP is the 28 amino acid peptide at the C terminus. [Pg.528]

Figure 2.5 Schematic illustrations of antiparallel (3 sheets. Beta sheets are the second major element of secondary structure in proteins. The (3 strands are either all antiparallel as in this figure or all parallel or mixed as illustrated in following figures, (a) The extended conformation of a (3 strand. Side chains are shown as purple circles. The orientation of the (3 strand is at right angles to those of (b) and (c). A p strand is schematically illustrated as an arrow, from N to C terminus, (bj Schematic illustration of the hydrogen bond pattern in an antiparallel p sheet. Main-chain NH and O atoms within a p sheet are hydrogen bonded to each other. Figure 2.5 Schematic illustrations of antiparallel (3 sheets. Beta sheets are the second major element of secondary structure in proteins. The (3 strands are either all antiparallel as in this figure or all parallel or mixed as illustrated in following figures, (a) The extended conformation of a (3 strand. Side chains are shown as purple circles. The orientation of the (3 strand is at right angles to those of (b) and (c). A p strand is schematically illustrated as an arrow, from N to C terminus, (bj Schematic illustration of the hydrogen bond pattern in an antiparallel p sheet. Main-chain NH and O atoms within a p sheet are hydrogen bonded to each other.
The fundamental unit of tertiary structure is the domain. A domain is defined as a polypeptide chain or a part of a polypeptide chain that can fold independently into a stable tertiary structure. Domains are also units of function. Often, the different domains of a protein are associated with different functions. For example, in the lambda repressor protein, discussed in Chapter 8, one domain at the N-terminus of the polypeptide chain binds DNA, while a second domain at the C-terminus contains a site necessary for the dimerization of two polypeptide chains to form the dimeric repressor molecule. [Pg.29]

The GAL4 recognition module therefore contains only one protein side chain, Lys 18, that provides specific interactions with the DNA. The remaining specific interactions with DNA are from main-chain atoms and depend critically on the correct conformation of the protein. The correct positioning of the C-terminus of the a helix is particularly important for recognition. This is to date the only example of a protein-DNA interaction in which... [Pg.188]

Figure 16.21 Structure of one subunit of the core protein of Slndbls virus. The protein has a similar fold to chymotrypsin and other serine proteases, comprising two Greek key motifs separated by an active site cleft. The C-terminus of the protein is bound in the catalytic site, making the coat protein inactive (Adapted from S. Lee et al., Structure 4 531-541, 1996.)... Figure 16.21 Structure of one subunit of the core protein of Slndbls virus. The protein has a similar fold to chymotrypsin and other serine proteases, comprising two Greek key motifs separated by an active site cleft. The C-terminus of the protein is bound in the catalytic site, making the coat protein inactive (Adapted from S. Lee et al., Structure 4 531-541, 1996.)...
Each precursor protein molecule is cleaved only once to generate one molecule of the coat protein, and catalytic activity is restricted to the precursor protein. Why is the coat protein itself catalytically inactive The structure of the coat protein shows that its C-terminus is bound in the active site cleft and thereby prevents other proteins entering the cleft and being cleaved. Tbis arrangement allows the precursor protein to fulfill its function to generate the coat protein and prevents the coat protein from destroying other proteins in the infected cell, including other coat proteins. [Pg.341]


See other pages where C terminus is mentioned: [Pg.1127]    [Pg.1128]    [Pg.1142]    [Pg.1148]    [Pg.288]    [Pg.98]    [Pg.98]    [Pg.248]    [Pg.176]    [Pg.202]    [Pg.203]    [Pg.339]    [Pg.444]    [Pg.447]    [Pg.359]    [Pg.16]    [Pg.100]    [Pg.146]    [Pg.168]    [Pg.171]    [Pg.187]    [Pg.188]    [Pg.189]    [Pg.189]    [Pg.189]    [Pg.268]    [Pg.318]    [Pg.357]    [Pg.358]    [Pg.382]    [Pg.1127]    [Pg.1128]   
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