Conformational properties of the isolated 1-23 fragment of human hemoglobin alpha-chain

Biophysical characterization of the alpha-globin binding protein alpha-hemoglobin stabilizing protein

Alpha-hemoglobin stabilizing protein (AHSP) is a small (12 kDa) and abundant erythroid-specific protein that binds specifically to free alpha-(hemo)globin and prevents its precipitation. When present in excess over beta-globin, its normal binding partner, alpha-globin can have severe cytotoxic effects that contribute to important human diseases such as beta-thalassemia. Because AHSP might act as a chaperone to prevent the harmful aggregation of alpha-globin during normal erythroid cell development and in diseases of globin chain imbalance, it is important to characterize the biochemical properties of the AHSP.alpha-globin complex. Here we provide the first structural information about AHSP and its interaction with alpha-globin. We find that AHSP is a predominantly alpha-helical globular protein with a somewhat asymmetric shape. AHSP and alpha-globin are both monomeric in solution as determined by analytical ultracentrifugation and bind each other to form a complex with 1:1 subunit stoichiometry, as judged by gel filtration and amino acid analysis. We have used isothermal titration calorimetry to show that the interaction is of moderate affinity with an association constant of 1 x 10(7) m(-1) and is thus likely to be biologically significant given the concentration of AHSP (approximately 0.1 mm) and hemoglobin (approximately 4 mm) in the late pro-erythroblast.

A limitation of two-state analysis for transitions between disordered and weakly ordered states

BACKGROUND

The stability of the secondary structure of particular peptide regions is often used to investigate the involvement of the region in protein folding. When analysing the relatively small populations of associated states that are formed by weak interactions (i.e. those interactions that are comparable to thermal energies), it is common practice to characterise the associated state by a parameter that is measured when this state is highly occupied. The accuracy of this method, however, has not yet been determined.

RESULTS

Using as a model the vancomycin group of antibiotics, either forming dimers or binding to cell wall precursors, we have investigated the dependence of the limiting (i.e. fully associated) chemical shifts of two protons on the equilibrium constants for the formation of the fully associated states. The chemical shift shows a large variation with the equilibrium constant for the formation of the fully associated state.

CONCLUSIONS

The results demonstrate, in two systems, that a parameter representing a fully associated state (chemical shift) varies greatly with the equilibrium constant for the formation of that associated state. The results have implications for two-state analyses of populations of protein fragments in which a parameter representing the fully associated state is taken to be independent of the equilibrium constant for its formation. Using two-state analysis to determine the population of associated states of protein fragments could result in an underestimation of the population of these associated states.

Effect of pH on the conformation and backbone dynamics of a 27-residue peptide in trifluoroethanol. An NMR and CD Study

The C-terminal fragment, residues 385-411, from human fibrinogen gamma-chain, i.e. KIIPFNRLTIGEGQQHHLG-GAKQAGDV, shows multiple turn conformations in aqueous solution (Mayo, K. H., Burke, C., Lindon, J. N., and Kloczewiak, M. (1990) Biochemistry 29, 3277-3286). The present study investigates the effect of pH and trifluoroethanol on the conformation and backbone dynamics of this 27-residue peptide. Both circular dichroism (CD) and 1H-NMR data indicate the normally observed increased helical conformations as a function of increasing trifluoroethanol. 1H-NMR structural studies done in the presence of 40% trifluoroethanol, pH 5.3, yield a network of nuclear Overhauser effects consistent with significant populations of helix-like conformation. Distance geometry calculations based on nuclear Overhauser effect-derived distance constraints yield a family of structures with relatively well defined N- and C-terminal conformations and an ill defined mid-peptide region from Gly397 to Gly403. Similar conformational populations are observed at pH 2.5. CD studies, however, indicate an increase in average alpha-helix content on decreasing the pH from 6 to 2. This apparent conflict between CD and NMR results may be explained by a transition from multiple beta-turn character at pH 5.3 to increased alpha-helix structure at pH 2.5. 13C alpha NMR relaxation data analyzed with the Lipari-Szabo model-free approach provide order parameters that demonstrate little if any influence of pH on backbone motional restrictions within the more flexible mid-peptide domain. At low pH, however, motions become less restricted within N-terminal residues Lys385-Phe389 and more restricted within C-terminal residues Ala405-Val411.

Structural analysis of peptides encompassing all alpha-helices of three alpha/beta parallel proteins: Che-Y, flavodoxin and P21-ras: implications for alpha-helix stability and the folding of alpha/beta parallel proteins

In an attempt to delineate the early folding events of structurally related proteins with no sequence homology, peptides including all five alpha-helices of three alpha/beta parallel open-sheet proteins, Che-Y, flavodoxin and P21-ras, have been analyzed by circular dichroism (far-UV CD) and nuclear magnetic resonance (NMR) in water and 30% (v/v) trifluoroethanol (TFE). Comparison between the helical content estimations from far-UV CD and the results from the NMR analysis renders a reasonably good qualitative correlation, indicating that the same phenomenon is underlined by both methods. Helix limits, as indicated by the existence of (i,i + 3) nuclear Overhauser effect (NOE) cross-correlations and significant up-field conformational shifts of the C alpha H protons, are practically coincident with those in the folded protein. On the other hand, the conformation of the side-chains differs markedly from those in the folded protein. Observation of NOE cross-correlations between pairs of residues at positions i,i + 3 has been used to statistically quantify free energies of i,i + 3 side-chain-side-chain interactions between the different pairs of residues in an alpha-helix. This analysis indicates that interactions between hydrophobic side-chains seem to be quite favorable for helix formation. The behaviour in aqueous solution of the structural equivalent peptides for the three proteins is quite unrelated except for the peptides corresponding to helices two and five. We postulate that, in the alpha/beta parallel proteins, those helices that join two beta-strands flanking another non-consecutive beta-strand should not be stable for folding reasons.

Conformation and molecular dynamics calculations on uteroglobin fragment 18-47

The conformational properties of fragment 18-47 of rabbit uteroglobin in aqueous solution containing SDS micelles were investigated by two-dimensional nmr spectroscopy and molecular dynamics calculations. The fragment comprises helices II and III and the beta-turn connecting the two helices. The nmr results and nmr-restrained molecular dynamics calculations showed that in the isolated fragment the elements of secondary structure present in the intact protein are preserved only in part. Specifically, a well-defined alpha-helix was found in the sequence 33-44, corresponding to helix III of uteroglobin, while the regions of helix II and beta-turn are characterized by high flexibility in the fragment.

Helix formation by the phospholipase A2 38-59 fragment: influence of chain shortening and dimerization monitored by nmr chemical shifts

The solution structure of a peptide fragment corresponding to the 38-59 region of porcine phospholipase A2 has been investigated using CD, nmr chemical shifts, and nuclear overhauser effects (NOEs). This isolated fragment of phospholipase forms an alpha-helix spanning residues 38-55, very similar to the one found in the native protein, except for residues 56-58, which were helical in the crystal but found random in solution. Addition of triflouroethanol (TFE) merely increased helix population but it did not redefine helix limits. To investigate how the folding information, in particular that concerning eventual helix start and stop signals, was coded in this particular amino acid sequence, the helices formed by synthetic peptides reproducing sections of this phospholipase 38-59 fragment, namely 40-59, 42-59, 38-50, and 45-57, were characterized using NOEs and helix populations quantitatively evaluated on different peptide chain segments using nmr chemical shifts in two solvents (H2O and 30% TFE/H2O). A set of nmr spectra was also recorded and assigned under denaturing conditions (6M urea) to obtain reliable values for the chemical shifts of each peptide in the random state. Based on chemical shift data, it was concluded that the helix formed by the phospholipase 38-59 fragment was not abruptly, but progressively, destabilized all along its length by successive elimination of residues at the N end, while the removal of residues at the C end affected helix stability more locally and to a lesser extent. These results are consistent with the idea that there are not single residues responsible for helix initiation or helix stability, and they also evidence an asymmetry for contributions to helix stability by residues located at the two chain ends. The restriction of molecular mobility caused by linking with a disulphide bridge at Cys 51 two identical 38-59 peptide chains did not increase helix stability. The helix formed by the covalently formed homodimer was very similar in length and population to that formed by the monomer.

Periodic properties of proton conformational shifts in isolated protein helices. An experimental study

In this work, the helix-forming residues in fragments of several proteins (ribonuclease, thermolysin, tendamistat and angiogenin) were identified by NOE and the helix proton shifts were measured as delta changes associated with helix-population increments driven by trifluoroethanol addition. When estimated in this way, a regular pattern of helix conformational shifts was clearly seen in the delta delta versus sequence profiles of all the peptides studied. The helix periodicity of the H alpha and H beta resonances was especially clear, an observation that earlier statistical studies of protein delta values failed to predict. Amide protons showed the largest helix shifts, but with a less-sharply defined periodic character. Aromatic residues considerably distorted the periodicity of the helix amide shifts in some peptides, as evidenced by the delta shifts of a RNase A fragment 1-15 analog in which the two aromatic residues were replaced by Ala. The relationship between helix periodicity and peptide amphiphatic character is discussed.

The homologous angiogenin and ribonuclease N-terminal fragments fold into very similar helices when isolated

The solution structure of the N-terminal hexadecapeptide of human angiogenin, a protein of unknown tertiary structure, has been precisely delineated by the combined use of CD, NOE and secondary shift data. A helix that starts just after Ser 3 and ends at Asp 14 was stabilized in 30% trifluoroethanol. This helix is strikingly similar in origin and length to the one formed by its homologous, the S-peptide of Ribonuclease (conformationally reexamined here), despite their quite different sequences (only four conserved residues). These results support the idea that individual start and stop signals indeed govern the location and size of natural isolated helices.

Tendamistat (12-26) fragment. NMR characterization of isolated beta-turn folding intermediates

In order to determine whether regions of a protein that are turns in the native structure are able to maintain such a structure when isolated, we have studied the conformational properties of various peptide fragments corresponding to the 12-26-peptide region of the alpha-amylase inhibitor tendamistat, by NMR. Amide solvent accessibility, NOE spectroscopy (NOESY) and rotating-frame NOE spectroscopy (ROESY) data strongly support the conclusion that the 12-26 and 15-23 peptides adopt in aqueous solution, a set of turn-like structures located around the central region of their corresponding polypeptidic chains, the same region where a beta turn exists in the native protein. Such a set of structures are destabilized when one residue located within the native beta turn of the 15-23 peptide is modified Trp18----Ser. Our results indicate that the tendency to bend in a predetermined region of a protein chain seems to exist from the very beginning of the folding process and therefore it could drive the folding instead of being a consequence of the tertiary assembly of the protein.

Solution structure of the isolated ribonuclease C-terminal 112-124 fragment

The conformational properties of the ribonuclease C-terminal 112-124 fragment have been studied by CD and 1H- and 13C-NMR in an attempt to determine whether native secondary structure elements other than alpha-helices have stability enough to be detected when isolated in aqueous solution. Only sequential alpha N and intraresidue NOE cross-peaks are observed in the NOESY spectra, a fact which points towards an essentially extended polypeptidic chain. Observed spectral variations with temperature, pH and urea addition allowed the identification of two non-random regions within the chain. The first one is located within residues 119-121, the same region where a native salt bridge (H119...D121) exists in the native protein, and the stability of that structure is affected by the protonation state of carboxylate groups. The second one involves the S123 and V124 residues at the C-terminal end. No signs of the native 112-115 beta-turn were detected which suggests that, in contrast to alpha-helices, long range interactions may be needed to stabilize these secondary structure elements.

Underlying assumptions in the estimation of secondary structure content in proteins by circular dichroism spectroscopy--a critical review

Recombinant DNA technology has made possible the large-scale production of proteins for pharmaceutical applications. As a result, there has been a renaissance in methodology which can provide information on the structural stability and character of these materials. Circular dichroism (CD) spectroscopy, with its sensitivity to the secondary structure adopted by the polypeptide chain, is a powerful tool in this regard. Quantitative analysis of the CD spectra of proteins is now wide-spread, aided by the availability of such algorithms on commercial instrumentation. However, there are basic assumptions made when conducting these calculations, many of which have not been addressed or summarized. Some of these assumptions are independent of the selection of basis spectra and the algorithm employed. These assumptions are listed and the available data concerning their validity is presented and discussed.