Neville R. Kallenbach

Hydrogen exchange and structural dynamics of proteins and nucleic acids.

Though the structures presented in crystallographic models of macromolecules appear to possess rock-like solidity, real proteins and nucleic acids are not particularly rigid. Most structural work to date has centred upon the native state of macromolecules, the most probable macromolecular form. But the native state of a molecule is merely its most abundant form, certainly not its only form. Thermodynamics requires that all other possible structural forms, however improbable, must also exist, albeit with representation corresponding to the factor exp( — G i / RT ) for each state of free energy G i (see Moelwyn-Hughes, 1961), and one appreciates that each molecule within a population of molecules will in time explore the vast ensemble of possible structural states.

Polyproline II structure in a sequence of seven alanine residues

A sequence of seven alanine residues—too short to form an α-helix and whose side chains do not interact with each other—is a particularly simple model for testing the common description of denatured proteins as structureless random coils. The 3JHNα coupling constants of individual alanine residues have been measured from 2 to 56°C by using isotopically labeled samples. The results display a thermal transition between different backbone conformations, which is confirmed by CD spectra. The NMR results suggest that polyproline II is the dominant conformation at 2°C and the content of β strand is increased by approximately 10% at 55°C relative to that at 2°C. The polyproline II conformation is consistent with recent studies of short alanine peptides, including structure prediction by ab initio quantum mechanics and solution structures for both a blocked alanine dipeptide and an alanine tripeptide. CD and other optical spectroscopies have found structure in longer “random coil” peptides and have implicated polyproline II, which is a major backbone conformation in residues within loop regions of protein structures. Our result suggests that the backbone conformational entropy in alanine peptides is considerably smaller than estimated by the random coil model. New thermodynamic data confirm this suggestion: the entropy loss on alanine helix formation is only 2.2 entropy units per residue.

Is polyproline II a major backbone conformation in unfolded proteins

Publisher Summary Protein folding is a process by which a polypeptide chain acquires its native structure from an unfolded state through a transition state. Recent studies of the unfolded states of proteins are based on a modification of the random coil model, recognizing that in many cases some residual native or non-native structure persists.. Combined evidence from the theoretical study of a blocked alanine peptide in aqueous solution and a variety of spectroscopic studies, including ultraviolet circular dichroism (CD), nuclear magnetic resonance (NMR), two-dimensional vibrational spectroscopy, vibrational circular dichroism (VCD), and vibrational Raman optical activity (VROA) reveal that the polyproline II (P II ) conformation is the dominant conformation in a variety of short model peptides. This chapter discusses the evidence from short peptides. It reviews the circular dichroism of unfolded proteins and addresses the role of P II in unfolded proteins.

Design of immobile nucleic acid junctions.

Nucleic acids that interact to generate structures in which three or more double helices emanate from a single point are said to form a junction. Such structures arise naturally as intermediates in DNA replication and recombination. It has been proposed that stable junctions can be created by synthesizing sets of oligonucleotides of defined sequence that can associate by maximizing Watson-Crick complementarity (Seeman N. C., 1981, Biomolecular Stereodynamics. Adenine Press, New York. 1: 269-278; Seeman, N. C., 1982, J. Theor. Biol. 99:237-247.) To make it possible to design molecules that will form junctions of specific architecture, we present here an efficient algorithm for generating nucleic acid sequences that optimize two fundamental properties: fidelity and stability. Fidelity refers to the relative probability of forming the junction complex relative to all alternative paired structures. Calculations are described that permit approximate prediction of the melting curves for junction complexes.

A seven-helix coiled coil

Coiled-coil proteins contain a characteristic seven-residue sequence repeat whose positions are designated a to g. The interacting surface between α-helices in a classical coiled coil is formed by interspersing nonpolar side chains at the a and d positions with hydrophilic residues at the flanking e and g positions. To explore how the chemical nature of these core amino acids dictates the overall coiled-coil architecture, we replaced all eight e and g residues in the GCN4 leucine zipper with nonpolar alanine side chains. Surprisingly, the alanine-containing mutant forms a stable α-helical heptamer in aqueous solution. The 1.25-Å resolution crystal structure of the heptamer reveals a parallel seven-stranded coiled coil enclosing a large tubular channel with an unusual heptad register shift between adjacent staggered helices. The overall geometry comprises two interleaved hydrophobic helical screws of interacting cross-sectional a and d layers that have not been seen before. Moreover, asparagines at the a positions play an essential role in heptamer formation by participating in a set of buried interhelix hydrogen bonds. These results demonstrate that heptad repeats containing four hydrophobic positions can direct assembly of complex, higher-order coiled-coil structures with rich diversity for close packing of α-helices.

Base-pair opening and closing reactions in the double helix: A stopped-flow hydrogen exchange study in poly(rA) · poly(rU)

Abstract The hydrogen-deuterium exchange of AMP, uridine, poly(rA), and poly(rA) · poly(rU) was investigated by a spectral difference method using stopped-flow spectrophotometry. Proton exchange rates were measured as a function of pH, added catalysts, temperature and salt concentration. The results confirm and extend previous conclusions on the H-exchange chemistry of the bases, on the large equilibrium opening of the double helix, and on its slow opening and closing rates, but an alternative conformation for the major open state is considered. Two H-exchange rate classes are found in poly(rA) · poly(rU). The slower class represents the two exocyclic amino protons of A which exchange through a pre-equilibrium opening mechanism, therefore revealing the fraction of time the helix is open. Base-pairs are open 5% of the time at 25 °C. The faster class is assigned to the U-N-3 H proton, the rate of which is limited by helix opening. Both opening and reclosing of the duplex are slow, 2 s −1 and 40 s −1 , respectively, at 25 °C. Thermodynamic parameters for the equilibrium helix opening and for the rate of opening were determined. These properties may be consistent with a simple opening involving swinging out of the U base while retaining A more or less stacked within the duplex. The results demonstrate that no faster or more populated helix-open state occurs (when structure is stable). It appears that, unlike opening—closing reactions at a helix end or a helix-coil boundary, internal base opening and closing are innately slow. One implication of this is that any chemical or biological process requiring access to sequences in the interior of a closed stable DNA duplex may be constrained to proceed only on a time scale of seconds, and not in milliseconds or microseconds.

Energetic contribution of solvent-exposed ion pairs to alpha-helix structure ☆

Understanding the role of amino acid side-chain interactions in forming secondary structure in proteins is useful for deciphering how proteins fold and for predicting folded structures of proteins from their sequence. Analysis of the secondary structure as a function of pH in two designed synthetic peptides with identical composition but different sequences, affords a quantitative estimate of the free energy contribution of a single ion pair to the stability of an isolated alpha-helix. One peptide contains repeated blocks of Glu4Lys4. The second has repeated blocks of Glu2Lys2. The former contains significant helical structure at neutral pH while the latter has none, based on ultraviolet light circular dichroism measurements and 1H nuclear magnetic resonance spectroscopy. The difference is attributed to formation of helix-stabilizing salt-bridges between Glu- and Lys+ spaced at i, i + 4 intervals in the former peptide. The free energy of formation of a single Glu(-)-Lys+ salt-bridge can be evaluated by using a statistical model of the helix-coil transition that explicitly includes salt-bridges: the result is -0.50(+/- 0.05) kcal/mol at 4 degrees C and neutral pH in 10 mM salt, in agreement with a value derived for a single salt-bridge in a helix on the surface of a globular protein.

Length Effects in Antimicrobial Peptides of the (RW)n Series

ABSTRACT A class of antimicrobial peptides involved in host defense consists of sequences rich in Arg and Trp-R and -W. Analysis of the pharmacophore in these peptides revealed that chains as short as trimers of sequences such as WRW and RWR have antimicrobial activity (M. B. Strom, B. E. Haug, M. L. Skar, W. Stensen, T. Stiberg, and J. S. Svendsen, J. Med. Chem. 46:1567-1570, 2003). To evaluate the effect of chain length on antimicrobial activity, we synthesized a series of peptides containing simple sequence repeats, (RW)n-NH2 (where n equals 1, 2, 3, 4, or 5), and determined their antimicrobial and hemolytic activity. The antimicrobial activity of the peptides increases with chain length, as does the hemolysis of red blood cells. Within the experimental error, longer peptides (n equals 3, 4, or 5) show similar values for the ratio of hemolytic activity to antibacterial activity, or the hemolytic index. The (RW)3 represents the optimal chain length in terms of the efficacy of synthesis and selectivity as evaluated by the hemolytic index. Circular dichroism spectroscopy indicates that these short peptides appear to be unfolded in aqueous solution but acquire structure in the presence of phospholipids. Interaction of the peptides with model lipid vesicles was examined using tryptophan fluorescence. The (RW)n peptides preferentially interact with bilayers containing the negatively charged headgroup phosphatidylglycerol relative to those containing a zwitterionic headgroup, phosphatidylcholine.

Individual breathing reactions measured in hemoglobin by hydrogen exchange methods.

Protein hydrogen exchange is generally believed to register some aspects of internal protein dynamics, but the kind of motion at work is not clear. Experiments are being done to identify the determinants of protein hydrogen exchange and to distinguish between local unfolding and accessibility-penetration mechanisms. Results with small molecules, polynucleotides, and proteins demonstrate that solvent accessibility is by no means sufficient for fast exchange. H-exchange slowing is quite generally connected with intramolecular H-bonding, and the exchange process depends pivotally on transient H-bond cleavage. At least in alpha-helical structures, the cooperative aspect of H-bond cleavage must be expressed in local unfolding reactions. Results obtained by use of a difference hydrogen exchange method appear to provide a direct measurement of transient, cooperative, local unfolding reactions in hemoglobin. The reality of these supposed coherent breathing units is being tested by using the difference H-exchange approach to tritium label the units one at a time and then attempting to locate the tritium by fragmenting the protein, separating the fragments, and testing them for label. Early results demonstrate the feasibility of this approach.

Hydrogen exchange study of some polynucleotides and transfer RNA.

Abstract The apparent disagreement between published transfer RNA hydrogen exchange results and the tRNA cloverleaf model, prompted a re-investigation of the relationship between hydrogen exchange data and nucleic acid structure. Hydrogen-tritium exchange experiments were carried out with samples of pure and mixed tRNA and with the synthetic polynucleotide bihelices: poly(rA) · poly(rU), poly(rI) · poly(rC), poly(rG) · poly(rC) and poly(dG) · poly (dC). Studies With the synthetic polynucleotides show that, to interpret nucleic acid hydrogen exchange data in terms of quantity of base-paired structure, one must count 5 H for each G · C pair and 2 or 3 for A · U. Both poly(rG) · poly(rC) and poly(dG) · poly(dC) clearly show 5 slowly exchanging H per base pair. For A · U and I · C only 2 were detected, though other workers have found 3 for some A-T systems. These are all base-pair-bound H. The ribose OH is too fast to measure. The reasons for the surprisingly slow exchange of the exposed NH2 protons are unknown. The hydrogen exchange-rate behavior found for the polynucleotides suggests that some local structural distortion is necessary for any of the exchangeable H to react, including the exposed NH2 protons, and that the distortion important for hydrogen exchange is different from that occurring in thermal denaturation. All the tRNA samples show very similar hydrogen exchange profiles. The pure samples (formylmethionine and tyrosine tRNA from Escherichia coli) have ~120 slowly exchanging protons, far more than the ~55 Watson-Crick hydrogen bonds in the simple cloverleaf models. With the above numeration, however, the cloverleaf models for the two pure tRNA samples account for all but approx-imately 20 of their slowly exchanging H. The excess of 20 H is very close to the number required by models having extra tertiary structure. The tRNAs were found to exchange more slowly even than poly(rG) · poly(rC) and to have a unique salt and pH dependence. These anomalies could also be explained by the presence of some tertiary folding. Unacylated and 70% aminoacylated E. coli tRNAfMet were found to have identical hydrogen exchange behavior, suggesting absence of structure change upon aminoacylation. A method was developed for isolating authentic poly(rG) from normally heterodisperse mixtures by Sephadex gel filtration in 90% dimethyl sulfoxide. Formation of the 1:1 poly(rG) · poly(rC) complex was achieved by mixing-experiments in concentrated urea solutions at high temperature.