E. James Milner-White

One type of gamma-turn, rather than the other gives rise to chain-reversal in proteins.

Gamma-turns may be defined by a hydrogen bond between the carbonyl group of one amino acid residue and the amino group of the acid two residues ahead in the sequence. They occur as two types, inverse gamma-turns and classic gamma-turns (classic gamma-turns are usually called just gamma-turns but we prefer to add the adjective classic to distinguish them from the word gamma-turn, referring collectively to both). Of the two, classic gamma-turns are less common and are considered by all authors to be extreme rarities in proteins. However, we find that a number do occur in a sample of proteins of known three-dimensional structure. One occurs at the edge of the second hypervariable region of the light chain in some immunoglobulins. All classic gamma-turns except one are associated with a reversal in the main chain direction. In most cases, the turn lies at the loop end of a beta-hairpin. By contrast, inverse gamma-turns, although giving rise to a kink in the chain, rarely occur within beta-hairpins and are seldom situated at a position of reversal, by 180 degrees, in chain direction.

Pyrrolidine ring puckering in cis and trans-proline residues in proteins and polypeptides: Different puckers are favoured in certain situations

In a set of proteins studied at high resolution by X-ray crystallography over a half of all cis and trans-proline residues could be unambiguously assigned to one of the two forms of pyrrolidine ring puckering, called UP and DOWN. Of these, 89% of the cis-proline residues exhibit the DOWN pucker, while the trans-proline residues, on average, are about evenly distributed between the two forms. Of trans-proline residues found in alpha-helices, 79% have the UP ring pucker. trans-proline residues occurring in other situations are more equally distributed between the two forms of pucker, although further generalizations may be possible. Proline residues in a set of crystal structures of short polypeptides were also examined. As in the protein sample, a tendency for the cis-proline residues to have the DOWN pucker was observed, but the effect was less pronounced.

Structural differences between valine‐12 and aspartate‐12 Ras proteins may modify carcinoma aggression

Recent evidence associates the codon 12 valine‐for‐glycine (G12V) mutant Ki‐Ras protein with higher stage and increased lethality of colorectal carcinomas, while the codon 12 aspartate‐for‐glycine (G12D) Ras mutation shows no such association. Several observations may be relevant to this phenomenon. First, GTPase activity of G12V Ras is one‐quarter that of G12D Ras and one‐tenth that of wild‐type (WT) Ras. Second, binding of the GTP analogue GppNp to G12D Ras is 8‐fold weaker than its binding to G12V or WT Ras and crystal structures indicate that electrostatic repulsion between the carboxylate group of the G12D Asp‐12 side‐chain and the γ phosphate of the bound nucleotide may make GTP binding to G12D Ras weaker even than that of GppNp. It is proposed that this lowering of affinity for GTP allows G12D Ras an escape from the oncogenic GTP‐bound state, whereas GTP tightly bound to G12V mutant Ras generates a more persistent, potentially oncogenic, signal. Structural comparisons also suggest that differences between the Switch I (effector) region of G12D and G12V Ras could modify interactions with downstream signalling molecules such as Raf‐1, neurofibromin, and phosphatidylinositol 3‐hydroxy‐kinase. Other differences between the G12D and G12V mutant Ras proteins include a lower affinity of the GTPase activating protein GAP for G12V than for G12D or WT Ras; but, as both G12D and G12V Ras are refractory to GTPase activation by GAP binding, this may be less significant. These studies complement experimental data showing that such Ras mutations differ in their effects in vitro and in vivo and, with recent data indicating heterogeneity of ras mutation in colorectal carcinomas and other tumours, make it plausible that codon 12 Ras mutations differ in carcinogenic potential and prognostic significance. Copyright

Coulombic attractions between partially chargedmain-chain atoms stabilise the right-handed twist found in most β-strands

The use of Lennard-Jones potentials gives rise to an expected energy distribution for main-chain polypeptide conformations in the Ramachandran plot that matches well the observed distribution of phi, psi values in high-resolution proteins. The position of the energy minimum in the beta-strand conformation region is situated where there is a substantial contribution from the electrostatic attraction between the partial charge of the carbonyl carbon atom of one amino acid residue and that of the carbonyl oxygen atom of an adjacent residue. This attraction gives rise to a preference for the right-twisted beta-strand conformation compared with the left-twisted conformation. The majority of beta-sheets are twisted, almost always in one direction. Looking along a single strand, the twist is to the right. This twist also helps provide a rationale for the characteristic topology of the strand-helix-strand unit often observed in alpha/beta proteins. The electrostatic explanation for the twist we propose has not, to our knowledge, been explicitly suggested previously. The factor that has been most widely proposed to explain the twist is steric hindrance involving side-chain atoms. We provide evidence that the electrostatic effect is of comparable significance. Right-twisted beta-strands are geometrically closely related to polyproline II helices and to collagen helices, both of which are left-handed. Short regions of polyproline II type helices, which are sometimes, but not always, rich in proline residues, are common at protein surfaces. We point out that these helices are stabilised by the same carbonyl-carbonyl interactions as in right-twisted beta-strands.

Loops, bulges, turns and hairpins in proteins

Abstract The structures of commonly occurring loop motifs and β -hairpins are described, with emphasis on their inter-main chain hydrogen bond patterns. Especially new is the realization that β -hairpins occur in four distinct classes that are of evolutionary and structural significance. Certain of the loop motifs are often found at the ends of particular classes of β -hairpins. Computer-generated pictures allow the three-dimensional hydrogen bond patterns of loops and secondary structural features to be displayed, in simplified form, in entire proteins.

Recurring loop motif in proteins that occurs in right-handed and left-handed forms: its relationship with alpha-helices and beta-bulge loops

A common feature of alpha-helices in proteins is a loop at the C-terminal end, with a characteristic hydrogen bond pattern. It is noted that several loops with the same structural features occur independently of alpha-helices; two are even situated at the loop ends of beta-hairpins. The name paperclip is suggested for loops possessing the appropriate hydrogen bonds. A number of features of paperclips are described: they exist in two classes, depending on the number of residues at the loop end; one class is very much commoner than the other. Two paperclips are found that belong to the common class, except that the main-chain conformation of each is the mirror image of that normally found. The majority of paperclips are shown to have tightly clustered sets of main-chain dihedral angles. These are somewhat similar to, but distinct from, a subgroup of another common family of loops that have been called beta-bulge loops; in the latter, the dihedral angles are also tightly clustered. The high degree of clustering in both cases is likely to be a result of steric constraints associated with hydrogen bond patterns at the ends of loops.Abstract A common feature of alpha-helices in proteins is a loop at the C-terminal end, with a characteristic hydrogen bond pattern. It is noted that several loops with the same structural features occur independently of alpha-helices; two are even situated at the loop ends of beta-hairpins. The name paperclip is suggested for loops possessing the appropriate hydrogen bonds. A number of features of paperclips are described: they exist in two classes. depending on the number of residues at the loop end; one class is very much commoner than the other. Two paperclips are found that belong to the common class, except that the main-chain conformation of each is the mirror image of that normally found. The majority of paperclips are shown to have tightly clustered sets of main-chain dihedral angles. These are somewhat similar to, but distinct from, a subgroup of another common family of loops that have been called beta-bulge loops; in the latter, the dihedral angles are also tightly clustered. The high degree of clustering in both cases is likely to be a result of steric constraints associated with hydrogen bond patterns at the ends of loops.

SITES FOR PHOSPHATES AND IRON-SULFUR THIOLATES IN THE FIRST MEMBRANES: 3 TO 6 RESIDUE ANION-BINDING MOTIFS (NESTS)

Nests are common three to six amino acid residue motifs in proteins where successive main chain NH groups bind anionic atoms or groups. On average 8% of residues in proteins belong to nests. Nests form a key part of a number of phosphate binding sites, notably the P-loop, which is the commonest of the binding sites for the phosphates of ATP and GTP. They also occur regularly in sites that bind [Fe2S2](RS)4 [Fe3S4](RS)3 and [Fe4S4](RS)4 iron-sulfur centers, which are also anionic groups. Both phosphates and iron-sulfur complexes would have occurred in the precipitates within hydrothermal vents of moderate temperature as key components of the earliest metabolism and it is likely existing organisms emerging in this milieu would have benefited from evolving molecules binding such anions. The nest conformation is favored by high proportions of glycine residues and there is evidence for glycine being the commonest amino acid during the stage of evolution when proteins were evolving so it is likely nests would have been common features in peptides occupying the membranes at the dawn of life.

Coulombic interactions between partially charged main-chain atoms not hydrogen-bonded to each other influence the conformations of α-helices and antiparallel β-sheet. A new method for analysing the forces between hydrogen bonding groups in proteins includes all the Coulombic interactions

An angle named gamma has been employed to describe the geometry at a hydrogen bond between main-chain atoms of polypeptides. In antiparallel beta-sheet, gamma is normally positive, whereas, in parallel beta-sheet and alpha-helices, it is negative. Although intriguing, no particular explanation has been offered to explain this result. We provide evidence that, in each case, the angular preference maximises the favourable Coulombic interaction between the partial negative charge on the carbonyl oxygen atom and the partial positive charge on the carbonyl carbon atom adjacent to the NH group to which it is hydrogen-bonded. Analyses of helices and beta-sheets in native proteins using Lennard-Jones potentials suggest that these carbonyl-carbonyl interactions are significant components of the attractive forces holding main-chain CONH groups together and are even in some cases larger than the hydrogen bonds themselves. A novel technique for analysing the forces holding together hydrogen-bonding groups in proteins is presented. It can be regarded as a development of the Kabsch and Sander method of calculating the energy of hydrogen bonds between main-chain atoms. In their program, electrostatic interactions are calculated between appropriate pairs of atoms, i.e. NH binding to CO. Instead, in our method, the four N, H, C, and O atoms, in a peptide bond are taken as a unit and the interaction between two NHCO groups calculated. We also use a Lennard-Jones potential, rather than just measuring the Coulombic interaction. With this approach, account is taken of all types of interactions between partially charged atoms, not only the hydrogen bonds.

On the antiquity of metalloenzymes and their substrates in bioenergetics

Many metalloenzymes that inject and extract reducing equivalents at the beginning and the end of electron transport chains involved in chemiosmosis are suggested, through phylogenetic analysis, to have been present in the Last Universal Common Ancestor (LUCA). Their active centres are affine with the structures of minerals presumed to contribute to precipitate membranes produced on the mixing of hydrothermal solutions with the Hadean Ocean ~4 billion years ago. These mineral precipitates consist of transition element sulphides and oxides such as nickelian mackinawite ([Fe>Ni]2S2), a nickel-bearing greigite (~FeSS[Fe3NiS4]SSFe), violarite (~NiSS[Fe2Ni2S4]SSNi), a molybdenum bearing complex (~Mo(IV/VI)2Fe3S(0/2-)9) and green rust or fougerite (~[Fe(II)Fe(III)(OH)4](+)[OH](-)). They may be respectively compared with the active centres of Ni-Fe hydrogenase, carbon monoxide dehydrogenase (CODH), acetyl coenzyme-A synthase (ACS), the complex iron-sulphur molybdoenzyme (CISM) superfamily and methane monooxygenase (MMO). With the look of good catalysts - a suggestion that gathers some support from prebiotic hydrothermal experimentation - and sequestered by short peptides, they could be thought of as the original building blocks of proto-enzyme active centres. This convergence of the makeup of the LUCA-metalloenzymes with mineral structure and composition of hydrothermal precipitates adds credence to the alkaline hydrothermal (chemiosmotic) theory for the emergence of life, specifically to the possibility that the first metabolic pathway - the acetyl CoA pathway - was initially driven from either end, reductively from CO2 to CO and oxidatively and reductively from CH4 through to a methane thiol group, the two entities assembled with the help of a further thiol on a violarite cluster sequestered by peptides. By contrast, the organic coenzymes were entirely a product of the first metabolic pathways. This article is part of a Special Issue entitled: Metals in Bioenergetics and Biomimetics Systems.

Predicting the conformations of peptides and proteins in early evolution

Considering that short, mainly heterochiral, polypeptides with a high glycine content are expected to have played a prominent role in evolution at the earliest stage of life before nucleic acids were available, we review recent knowledge about polypeptide three-dimensional structure to predict the types of conformations they would have adopted. The possible existence of such structures at this time leads to a consideration of their functional significance, and the consequences for the course of evolution.This article was reviewed by Bill Martin, Eugene Koonin and Nick Grishin.