Loop region

The secondary structure elements, formed in this way and held together by the hydrophobic core, provide a rigid and stable framework. They exhibit relatively little flexibility with respect to each other, and they are the best-defined parts of protein structures determined by both x-ray and NMR techniques. Functional groups of the protein are attached to this framework, either directly by their side chains or, more frequently, in loop regions that connect sequentially adjacent secondary structure elements. We will now have a closer look at these structural elements. 

Loop regions exposed to solvent are rich in charged and polar hydrophilic residues. This has been used in several prediction schemes, and it has proved possible to predict loop regions from an amino acid sequence with a higher degree of confidence than a helices or p strands, which is ironic since the loops have irregular structures. 

Figure 2.8 Adjacent antiparallel P strands are joined by hairpin loops. Such loops are frequently short and do not have regular secondary structure. Nevertheless, many loop regions in different proteins have similar structures, (a) Histogram showing the frequency of hairpin loops of different lengths in 62 different proteins, (b) The two most frequently occurring two-residue hairpin loops Type I turn to the left and Type II turn to the right. Bonds within the hairpin loop are green, [(a) Adapted from B.L. Sibanda and J.M. Thornton, Nature 316 170-174, 1985.]...

Long loop regions are often flexible and can frequently adopt several different conformations, making them "invisible" in x-ray structure determinations and undetermined in NMR studies. Such loops are frequently involved in the function of the protein and can switch from an "open" conformation, which allows access to the active site, to a "closed" conformation, which shields reactive groups in the active site from water. 

The simplest motif with a specific function consists of two a helices joined by a loop region. Two such motifs, each with its own characteristic geometry and amino acid sequence requirements, have been observed as parts of many protein structures (Figure 2.12). 

Figure 2.12 Two a helices that are connected by a short loop region in a specific geometric arrangement constitute a helix-turn-helix motif. Two such motifs are shown the DNA-binding motif (a), which is further discussed in Chapter 8, and the calcium-binding motif (b), which is present in many proteins whose function is regulated by calcium.

The loop region between the two a helices binds the calcium atom. Carboxyl side chains from Asp and Glu, main-chain C =0 and H2O form the ligands to the metal atom (see Figure 2.13b). Thus both the specific main-chain conformation of the loop and specific side chains are required to provide the function of this motif. The helix-loop-helix motif provides a scaffold that holds the calcium ligands in the proper position to bind and release calcium. 

The hairpin motif is a simple and frequently used way to connect two antiparallel p strands, since the connected ends of the p strands are close together at the same edge of the p sheet. How are parallel p strands connected If two adjacent strands are consecutive in the amino acid sequence, the two ends that must be joined are at opposite edges of the p sheet. The polypeptide chain must cross the p sheet from one edge to the other and connect the next p strand close to the point where the first p strand started. Such CTossover connections are frequently made by a helices. The polypeptide chain must turn twice using loop regions, and the motif that is formed is thus a p strand followed by a loop, an a helix, another loop, and, finally, the second p strand. 

Secondary structure occurs mainly as a helices and p strands. The formation of secondary structure in a local region of the polypeptide chain is to some extent determined by the primary structure. Certain amino acid sequences favor either a helices or p strands others favor formation of loop regions. Secondary structure elements usually arrange themselves in simple motifs, as described earlier. Motifs are formed by packing side chains from adjacent a helices or p strands close to each other. 

Domains are formed by different combinations of secondary structure elements and motifs. The a helices and p strands of the motifs are adjacent to each other in the three-dimensional structure and connected by loop regions. Sequentially adjacent motifs, or motifs that are formed from consecutive regions of the primary structure of a polypeptide chain, are usually close together in the three-dimensional structure (Figure 2.20). Thus to a first approximation a polypeptide chain can be considered as a sequential arrangement of these simple motifs. The number of such combinations found in proteins is limited, and some combinations seem to be structurally favored. Thus similar domain structures frequently occur in different proteins with different functions and with completely different amino acid sequences. 

Figure 2.21 illustrates the 24 possible ways in which two adjacent p hairpin motifs, each consisting of two antiparallel p strands connected by a loop region, can be combined to make a more complex motif. 

The proteins thus adapt to mutations of buried residues by changing their overall structure, which in the globins involves movements of entire a helices relative to each other. The structure of loop regions changes so that the movement of one a helix is not transmitted to the rest of the structure. Only movements that preserve the geometry of the heme pocket are accepted. Mutations that cause such structural shifts are tolerated because many different combinations of side chains can produce well-packed helix-helix interfaces of similar but not identical geometry and because the shifts are coupled so that the geometry of the active site is retained. 

The most frequent of the domain structures are the alpha/beta (a/P) domains, which consist of a central parallel or mixed P sheet surrounded by a helices. All the glycolytic enzymes are a/p structures as are many other enzymes as well as proteins that bind and transport metabolites. In a/p domains, binding crevices are formed by loop regions. These regions do not contribute to the structural stability of the fold but participate in binding and catalytic action. 

Figure 4.5 The polypeptide chain of the enzyme pyruvate kinase folds into several domains, one of which is an a/p barrel (red). One of the loop regions in this barrel domain is extended and comprises about 100 amino acid residues that fold into a separate domain (blue) built up from antiparallel P strands. The C-terminal region of about 140 residues forms a third domain (green), which is an open twisted a/p structure.

Figure 4.8 The active site in all a/p barrels is in a pocket formed by the loop regions that connect the carboxy ends of the p strands with the adjacent a helices, as shown schematically in (a), where only two such loops are shown, (b) A view from the top of the barrel of the active site of the enzyme RuBisCo (ribulose bisphosphate carboxylase), which is involved in CO2 fixation in plants. A substrate analog (red) binds across the barrel with the two phosphate groups, PI and P2, on opposite sides of the pocket. A number of charged side chains (blue) from different loops as welt as a Mg ion (yellow) form the substrate-binding site and provide catalytic groups. The structure of this 500 kD enzyme was determined to 2.4 A resolution in the laboratory of Carl Branden, in Uppsala, Sweden. (Adapted from an original drawing provided by Bo Furugren.)...

Figure 4.13 (a) The active site in open twisted a/p domains is in a crevice outside the carboxy ends of the P strands. This crevice is formed by two adjacent loop regions that connect the two strands with a helices on opposite sides of the P sheet. This is illustrated by the curled fingers of two hands (b), where the top halves of the fingers represent loop regions and the bottom halves represent the P strands. The rod represents a bound molecule in the binding... 

In almost every one of the more than 100 different known a/p structures 1 of this class the active site is at the carboxy edge of the p sheet. Functional residues are provided by the loop regions that connect the carboxy end of the strands with the amino end of the a helices. In this one respect a fun-I damental similarity therefore exists between the a/p-barrel structures and the I open a/p-sheet structures. 

The general shapes of the active sites are quite different, however. Open I a/p structures cannot form funnel-shaped active sites like the barrel struc-Itures. Instead, they form crevices at the edge of the p sheet. Such crevices loccur when there are two adjacent connections that are on opposite sides of Ithe P sheet. One of the loop regions in these two connections goes out from... 

Figure 4.16 A schematic view of the active site of tyrosyl-tRNA synthetase. Tyrosyl adenylate, the product of the first reaction catalyzed by the enzyme, is bound to two loop regions residues 38-47, which form the loop after p strand 2, and residues 190-193, which form the loop after P strand 5. The tyrosine and adenylate moieties are bound on opposite sides of the P sheet outside the catboxy ends of P strands 2 and 5.

Figure 4.17 Schematic diagram of bound tyrosine to tyrosyl-tRNA synthetase. Colored regions correspond to van der Waals radii of atoms within a layer of the structure through the tyrosine ring. Red is bound tyrosine green is the end of P strand 2 and the beginning of the following loop region yellow is the loop region 189-192 and brown is part of the a helix in loop region 173-177.

Figure 4.18 Side chains of the tyrosyl-tRNA synthetase that form hydrogen bonds to tyrosyl adenylate. Green residues are from p strand 2 and the following loop regions, yellow residues are from the loop after P strand S, and brown residues are from the a helix before P strand S. (Adapted from T. Wells and A. Fersht, Nature 316 656-657, 1985.)...

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