Peptide bonds main chain

Figure 1.2 Proteins are built up by amino acids that are linked by peptide bonds to form a polypeptide chain, (a) Schematic diagram of an amino acid. Illustrating the nomenclature used in this book. A central carbon atom (Ca) is attached to an amino group (NH2), a carboxyl group (COOH), a hydrogen atom (H), and a side chain (R). (b) In a polypeptide chain the carboxyl group of amino acid n has formed a peptide bond, C-N, to the amino group of amino acid + 1. One water molecule is eliminated in this process. The repeating units, which are called residues, are divided into main-chain atoms and side chains. The main-chain part, which is identical in all residues, contains a central Ca atom attached to an NH group, a C =0 group, and an H atom. The side chain R, which is different for different residues, is bound to the Ca atom.

Figure 1.2 shows one way of dividing a polypeptide chain, the biochemist s way. There is, however, a different way to divide the main chain into repeating units that is preferable when we want to describe the structural properties of proteins. For this purpose it is more useful to divide the polypeptide chain into peptide units that go from one Ca atom to the next Ca atom (see Figure 1.5). Each C atom, except the first and the last, thus belongs to two such units. The reason for dividing the chain in this way is that all the atoms in such a unit are fixed in a plane with the bond lengths and bond angles very nearly the same in all units in all proteins. Note that the peptide units of the main chain do not involve the different side chains (Figure 1.5). We will use both of these alternative descriptions of polypeptide chains—the biochemical and the structural—and discuss proteins in terms of the sequence of different amino acids and the sequence of planar peptide units.

Figure 1.6 Diagram showing a polypeptide chain where the main-chain atoms are represented as rigid peptide units, linked through the atoms. Each unit has two degrees of freedom it can rotate around two bonds, its Ca-C bond and its N-Ca bond. The angle of rotation around the N-Ca bond is called phi (cj)) and that around the Co-C bond is called psi (xj/). The conformation of the main-chain atoms is therefore determined by the values of these two angles for each amino acid.

The most important aspect of Table 27.1 is that the 20 anino acids that occur in proteins share the common feature of being a-anino acids, and the differences fflnong them are in their side chains. Peptide bonds linking carboxyl and a-anino groups characterize the structure of proteins, but it is the side chains that are mainly responsible for theh properties. The side chains of the 20 commonly occuning amino acids encompass both large and small differences. The major differences between amino acid side chains concern ... 

The geometry of the peptide bond is planar- and the main chain is arianged in an anti conformation (Section 27.7). 

Fig. 54. An asparagine side chain making a hydrogen-bond to the main chain NH of residue n + 2, an arrangement which helps stabilize the central peptide of a tight turn. Residues 91-93 from chymotrypsin.

The new crystal structure of the ribosome—RFl complex sheds more light into the interactions between the GGQ motif and the peptidyltransferase center. This complex represents the product state of peptide release since a deacylated tRNA is bound to the P site. Importantly, the main chain amide of the conserved glutamine hydrogen bonds to the 3 OH of A76 in the P site, which is the leaving group of the hydrolysis... 

TTie TOCSY 2D NMR experiment correlates all protons of a spin system, not just those directly connected via three chemical bonds. For the protein example, the alpha proton, Ft , and all the other protons are able to transfer magnetization to the beta, gamma, delta, and epsilon protons if they are connected by a continuous chain—that is, the continuous chain of protons in the side chains of the individual amino acids making up the protein. The COSY and TOCSY experiments are used to build so-called spin systems—that is, a list of resonances of the chemical shift of the peptide main chain proton, the alpha proton(s), and all other protons from each aa side chain. Which chemical shifts correspond to which nuclei in the spin system is determined by the conventional correlation spectroscopy connectivities and the fact that different types of protons have characteristic chemical shifts. To connect the different spin systems in a sequential order, the nuclear Overhauser effect spectroscopy... 

All amino acids have at least two ionizable groups, and their net charge therefore depends on the pH value. The COOH groups at the a-C atom have plmonocarboxylic acids. The basicity of the a-amino function also varies, with pKa values of between 8.8 and 10.6, depending on the amino acid. Acidic and basic amino acids have additional ionizable groups in their side chain. The plside chains are listed on p.60. The electrical charges of peptides and proteins are mainly determined by groups in the side chains, as most a-car-boxyl and a-amino functions are linked to peptide bonds (see p. 66). 

---