A-amino acid side chain

Beumer, R. Reiser, O. /j-Aminocyclopropane-carboxylic acids with a-amino acid side chain functionality. Tetrahedron 2001, 57, 6497-6503. 

The vinyltin moiety can form part of a diene system and undergo coupling with a dienyl iodide to form a tetraene [23] (Scheme 4-3). Crisp and Glink [24] have carried out a number of couplings directed towards a-amino acid side-chain elaboration steps and observed the occurrence of ipso-substitution as a side reaction. 

Figure I. Conformational changes mediated by Cu(II) eoordination to the bipyridine group of the transoid 6,6 -bis-(acylanuno)-2,2 -bipyridine-peptide 3 to complex 4 having a cisoid conformation R = a-amino acid side chain (adapted from [8]).

Kish, M.M., Ohanessian, G. and Wesdemiotis, C. (2003) The Na+ affinities of a-amino acids side-chain substituent effects. Int. J. Mass Spectrom., 227, 509-524. 

The comparison of both data sources qualitatively shows a similar picture. Regions of high mobflity are located especially between the secondary structure elements, which are marked on the abscissa of the plot in Figure 7-17. Please remember that the fluctuations plotted in this example also include the amino acid side chains, not only the protein backbone. This is the reason why the side chains of large and flexible amino acids like lysine or arginine can increase the fluctuations dramatically, although the corresponding backbone remains almost immobile. In these cases, it is useful to analyze the fluctuations of the protein backbone and side chains individually. 

Similar ligand-ligand interactions have been reported for a large number of ternary -amino acid complexes, built up of two different amino acid.s. A compilation of 72 examples is presented in reference 39. The extra stabilisation due to ligand-ligand interactions in these complexes depends on the character of the amino-acid side chains and amounts to 0.34 - 0.57 kJ/mole for combinations of aromatic and aliphatic side chains and 0.11 - 6.3 kJ/mole when arene - arene interactions are possible. ... 

Much of protein engineering concerns attempts to explore the relationship between protein stmcture and function. Proteins are polymers of amino acids (qv), which have general stmcture +H3N—CHR—COO , where R, the amino acid side chain, determines the unique identity and hence the stmcture and reactivity of the amino acid (Fig. 1, Table 1). Formation of a polypeptide or protein from the constituent amino acids involves the condensation of the amino-nitrogen of one residue to the carboxylate-carbon of another residue to form an amide, also called peptide, bond and water. The linear order in which amino acids are linked in the protein is called the primary stmcture of the protein or, more commonly, the amino acid sequence. Only 20 amino acid stmctures are used commonly in the cellular biosynthesis of proteins (qv). 

Fig. 2. Protein secondary stmcture (a) the right-handed a-helix, stabilized by intrasegmental hydrogen-bonding between the backbone CO of residue i and the NH of residue t + 4 along the polypeptide chain. Each turn of the helix requires 3.6 residues. Translation along the hehcal axis is 0.15 nm per residue, or 0.54 nm per turn and (b) the -pleated sheet where the polypeptide is in an extended conformation and backbone hydrogen-bonding occurs between residues on adjacent strands. Here, the backbone CO and NH atoms are in the plane of the page and the amino acid side chains extend from C ...

Through combined effects of noncovalent forces, proteins fold into secondary stmctures, and hence a tertiary stmcture that defines the native state or conformation of a protein. The native state is then that three-dimensional arrangement of the polypeptide chain and amino acid side chains that best facihtates the biological activity of a protein, at the same time providing stmctural stabiUty. Through protein engineering subde adjustments in the stmcture of the protein can be made that can dramatically alter its function or stabiUty. 

Fig. 1. The two principal elements of secondary stmcture in proteins, (a) The a-helix stabilized by hydrogen bonds between the backbone of residue i and i + 4. There are 3.6 residues per turn of helix and an axial translation of 150 pm per residue. represents the carbon connected to the amino acid side chain, R. (b) The P sheet showing the hydrogen bonding pattern between neighboring extended -strands. Successive residues along the chain point...

Other immobilization methods are based on chemical and physical binding to soHd supports, eg, polysaccharides, polymers, glass, and other chemically and physically stable materials, which are usually modified with functional groups such as amine, carboxy, epoxy, phenyl, or alkane to enable covalent coupling to amino acid side chains on the enzyme surface. These supports may be macroporous, with pore diameters in the range 30—300 nm, to facihtate accommodation of enzyme within a support particle. Ionic and nonionic adsorption to macroporous supports is a gentle, simple, and often efficient method. Use of powdered enzyme, or enzyme precipitated on inert supports, may be adequate for use in nonaqueous media. Entrapment in polysaccharide/polymer gels is used for both cells and isolated enzymes. 

Advantages of chromatography for protein separations include the large number of possible chemical interactions resulting from variations in the frequency and distribution of the amino-acid side chains on the surfaces of the proteins, and the availability of a wide array of different adsorption media. Chromatography has high efficiency and selectivity, and adequate scale-up potential. 

Fhe amino acid side chains project out from the a helix (see Figure 2.2e) and do not interfere with it, except for proline. The last atom of the proline side... 

It is interesting to note that the amino acid side chains may be either neutral as in valine, acidic as in glutamic acid or basic as in lysine. The presence of both acidic and basic side chains leads to proteins such as casein acting as amphoteric electrolytes and their physical behaviour will depend on the pH of the environment in which the molecules exist. This is indicated by Figure 30.2, showing a simplified protein molecule with just one acidic and one basic side group. 

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 ... 

Proteins are the indispensable agents of biological function, and amino acids are the building blocks of proteins. The stunning diversity of the thousands of proteins found in nature arises from the intrinsic properties of only 20 commonly occurring amino acids. These features include (1) the capacity to polymerize, (2) novel acid-base properties, (3) varied structure and chemical functionality in the amino acid side chains, and (4) chirality. This chapter describes each of these properties, laying a foundation for discussions of protein structure (Chapters 5 and 6), enzyme function (Chapters 14-16), and many other subjects in later chapters. 

FIGURE 15.2 Enzymes regulated by covalent modification are called interconvertible enzymes. The enzymes protein kinase and protein phosphatase, in the example shown here) catalyzing the conversion of the interconvertible enzyme between its two forms are called converter enzymes. In this example, the free enzyme form is catalytically active, whereas the phosphoryl-enzyme form represents an inactive state. The —OH on the interconvertible enzyme represents an —OH group on a specific amino acid side chain in the protein (for example, a particular Ser residue) capable of accepting the phosphoryl group. 

John.son, L. N., and Barford, D., 1994. Electro.static effects in die control of glycogen pho.sphoryla.se by pho.sphorylation. Protein Science 3 1726-1730. Di.scn.s.sion of die pho.sphate group s ability to deliver two negative charges to a protein, a property that no amino acid side chain can provide. 

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