Effects of side-chain characteristics on stability and oligomerization state of a de novo-designed model coiled-coil: 20 amino acid substitutions in position "d"

We describe the de novo design and biophysical characterization of a model coiled-coil protein in which we have systematically substituted 20 different amino acid residues in the central "d" position. The model protein consists of two identical 38 residue polypeptide chains covalently linked at their N termini via a disulfide bridge. The hydrophobic core contained Val and Ile residues at positions "a" and Leu residues at positions "d". This core allowed for the formation of both two-stranded and three-stranded coiled-coils in benign buffer, depending on the substitution at position "d". The structure of each analog was analyzed by CD spectroscopy and their relative stability determined by chemical denaturation using GdnHCI (all analogs denatured from the two-stranded state). The oligomeric state(s) was determined by high-performance size-exclusion chromatography and sedimentation equilibrium analysis in benign medium. Our results showed a thermodynamic stability order (in order of decreasing stability) of: Leu, Met, Ile, Tyr, Phe, Val, Gln, Ala, Trp, Asn, His, Thr, Lys, Ser, Asp, Glu, Arg, Orn, and Gly. The Pro analog prevented coiled-coil formation. The overall stability range was 7.4 kcal/mol from the lowest to the highest analog, indicating the importance of the hydrophobic core and the dramatic effect a single substitution in the core can have upon the stability of the protein fold. In general, the side-chain contribution to the level of stability correlated with side-chain hydrophobicity. Molecular modelling studies, however, showed that packing effects could explain deviations from a direct correlation. In regards to oligomerization state, eight analogs demonstrated the ability to populate exclusively one oligomerization state in benign buffer (0.1 M KCl, 0.05 M K(2)PO(4)(pH 7)). Ile and Val (the beta-branched residues) induced the three-stranded oligomerization state, whereas Tyr, Lys, Arg, Orn, Glu and Asp induced the two-stranded state. Asn, Gln, Ser, Ala, Gly, Phe, Leu, Met and Trp analogs were indiscriminate and populated two-stranded and three-stranded states. Comparison of these results with similar substitutions in position "a" highlights the positional effects of individual residues in defining the stability and numbers of polypeptide chains occurring in a coiled-coil structure. Overall, these results in conjunction with other work now generate a relative thermodynamic stability scale for 19 naturally occurring amino acid residues in either an "a" or "d" position of a two-stranded coiled-coil. Thus, these results will aid in the de novo design of new coiled-coil structures, a better understanding of their structure/function relationships and the design of algorithms to predict the presence of coiled-coils within native protein sequences.

Structural cassette mutagenesis in a de novo designed protein: proof of a novel concept for examining protein folding and stability

The solution to the protein folding problem lies in defining the relative energetic contributions of short-range and long-range interactions. In other words, the tendency of a stretch of amino acids to adopt a final secondary structural fold is context dependent. Our approach to this problem is to address whether an amino acid sequence, a "cassette," with a defined secondary structure in the three-dimensional structure of a native protein, can adopt a different conformation when placed into a different protein environment. Thus, we designed de novo a disulfide-bridged two-stranded alpha-helical parallel coiled coil, where each polypeptide chain consisted of 39 residues, as a "cassette holder." The 11-residue cassette would be inserted into the center of each polypeptide chain between the two nucleating alpha-helices to replace the control sequence. This Structural Cassette Mutagenesis model permits the analysis of short-range interactions within the inserted cassette as well as long-range interactions between the nucleating helices and the cassette region. The cassette holder, with a control sequence as the cassette, had a GdnHCl transition midpoint during denaturation of 5.6M. To demonstrate the feasibility of our model, an 11-residue beta-strand cassette from an immunoglobulin fold was inserted. The cassette was fully induced into the alpha-helical conformation with a [GdnHCl]1/2 value of 3.2M. To demonstrate the importance of short-range interactions (beta-sheet/alpha-helical propensities of amino acid side chains) in modulating structure and stability, a series of 1-5 threonine residues (highest beta-sheet propensity) were substituted into the solvent-exposed portions of the cassette in the alpha-helical conformation. Each successive substitution systematically decreased the stability of the coiled coil with peptide T4b (4 Thr residues) having a [GdnHCl]1/2 value of 2.2M. The single substitution of Ile in the hydrophobic core of the cassette with Ala or Thr had the most dramatic effect on protein stability (peptide 120T, [GdnHCl]1/2 value of 1.4M). Though these substitutions were able to modulate stability, they were not able to disrupt the alpha-helical conformation of the cassette, showing the importance of the nucleating alpha-helices on either side of the cassette in controlling conformation of the cassette. We have demonstrated the feasibility of our model protein to accept a beta-strand cassette. The effect of cassettes containing other beta-strands, beta-turns, loops, regions of undefined structure, and helical segments on conformation and stability of our model protein will also be determined.

Hydrophilic interaction/cation-exchange chromatography for the purification of synthetic peptides from closely related impurities: serine side-chain acetylated peptides

Mixed-mode hydrophilic interaction/cation-exchange chromatography (HILIC/CEC) is a novel HPLC technique which has excellent potential for peptide separations. Separations by HILIC/CEC are carried out by subjecting peptides to linear increasing salt gradients in the presence of high levels of acetonitrile, which promotes hydrophilic interactions overlayed on ionic interactions with the cation-exchange matrix. Complex peptide mixtures produced by solid-phase synthesis are a frequently encountered and challenging purification problem. In the present study a two-step protocol, consisting of HILIC/CEC followed by RPC, was required for the successful purification of a 21-residue synthetic amphipathic alpha-helical peptide from serine side-chain acetylated impurities, with HILIC/CEC proving to be highly sensitive to subtle differences in hydrophilicities between the acetylated peptides and the desired product. Investigation of the three potential sites of serine acetylation through solid-phase synthesis of acetylated analogues of the desired peptide (peptides of the same sequence and secondary structure, but acetylated at different positions on the hydrophilic face of the alpha-helix) demonstrated that acetylation was occurring at different sites on the peptide. HILIC/CEC was able to take advantage of very subtle changes in environment around the acetylation sites and thus effect a separation of these analogues not achievable by RPC or CEC alone.

Hydrophilic interaction/cation-exchange chromatography for separation of amphipathic alpha-helical peptides

Mixed-mode hydrophilic interaction/cation-exchange chromatography (HILIC/CEX) is a novel high-performance technique which has excellent potential for peptide separations. Separations by HILIC/CEX are carried out by subjecting peptides to linear increasing salt gradients in the presence of high levels of acetonitrile, which promotes hydrophilic interactions overlaid on ionic interactions with the cation-exchange matrix. In the present study, HILIC/CEX has been applied to the separation of synthetic amphipathic alpha-helical peptides, varying in amphipathicity and the nature of side-chain substitutions in the centre of the hydrophobic or hydrophilic face. Observation of the retention behaviour of these amphipathic alpha-helical peptide analogues during HILIC/CEX and reversed-phase chromatography (RPLC) enabled the establishment of general rules concerning the applicability of these complementary HPLC techniques to peptides displaying a secondary structural motif of common occurrence.

Effect of mobile phase on the oligomerization state of alpha-helical coiled-coil peptides during high-performance size-exclusion chromatography

Important structural motifs involving amphipathic helices include two-stranded and multiple-stranded coiled-coils. High-performance size-exclusion chromatography (HPSEC) is a useful tool to examine both the oligomerization state of coiled-coils as well as the stability of such motifs, due to the facile manipulation of the mobile phase and the lack of interaction of the peptide solutes with the stationary phase. In the present study, HPSEC was applied to two series of de novo designed model amphipathic alpha-helical peptides with the sequences (1) Ac-(E-A-L-K-A-E-I)n-E-A-C-K-A-amide, where n = 1 or 3, Ac-E-I-(E-A-L-K-A-E-I)4-E-A-C-K-A-amide and (2) Ac-(K-L-E-A-L-E-A)n-amide, where n = 1, 2 or 4. Observation of the retention behaviour of Series 1 under both denaturing and non-denaturing conditions at pH 7.0 offered insights into the effect of polypeptide chain length and disulphide bridge formation on the stability of alpha-helical coiled-coils. In contrast, the Series 2 peptides showed promise as peptide standards to monitor the effect of environment on the multi-strandedness of coiled-coils, since the 28-residue peptide of this series was eluted as a monomer, dimer or trimer depending on mobile phase conditions.

Use of sodium perchlorate at low pH for peptide separations by reversed-phase liquid chromatography. Influence of perchlorate ion on apparent hydrophilicity of positively charged amino acid side-chains

The reversed-phase liquid chromatography (RPLC) behavior of synthetic model peptides containing positively charged amino acid residues was studied in the presence or absence of 100 mM sodium perchlorate in order to determine the effect on apparent side-chain hydrophilicity of a charged residue at low pH. The peptides used in this study were either non-helical peptides or amphipathic alpha-helical peptides, where the effect of the negatively charged perchlorate ion on a charged residue in either the hydrophobic face or hydrophilic face of the helix was monitored. We have shown that the addition of 100 mM perchlorate to RPLC separations of positively charged peptides performed in a 20 mM aqueous phosphoric acid-acetonitrile system resulted in an increase in retention time of a peptide relative to the same peptide in the absence of perchlorate. This effect occurred independent of conformation, i.e., whether comparing the effect of positively charged residue substitutions in the hydrophobic or hydrophilic face of an amphipathic alpha-helix or in a peptide with negligible secondary structure. From these results, suggesting that positively charged side-chain hydrophilicity is decreased by ion-pairing with the perchlorate ion, we have shown practical examples where mixtures of non-helical and amphipathic alpha-helical peptides showed enhanced resolution in the presence of perchlorate at pH 2, compared to in its absence. In addition, it was shown that an aqueous phosphoric acid-perchlorate-acetonitrile mobile phase may show markedly different selectivity for peptide separations at low pH compared to the more traditional aqueous trifluoroacetic acid-acetonitrile system.

Selectivity due to conformational differences between helical and non-helical peptides in reversed-phase chromatography

The reversed-phase retention behaviour of two series of peptides, one non-helical and the other alpha-helical, was studied under various linear AB gradients in order to determine the effect of peptide conformation on selectivity of the separation. The non-helical series, designated X1, with the sequence Ac-XLGAKGAGVG-amide, exhibited negligible alpha-helical content in a hydrophobic medium; whereas, the amphipathic alpha-helical series, designated AX9, with the sequence Ac-EAEKAAKEXEKAAKEAEK-amide, exhibited high alpha-helical content in a hydrophobic medium. We have shown that plots of log k vs. phi (where k is the median capacity factor and phi is the median volume fraction of organic solvent) are very similar for any one peptide conformation, i.e., peptides from either the non-helical or amphipathic alpha-helical series exhibit similar S (solute parameter) values and the b (gradient steepness parameter) values are also similar for 17 different amino acid substitutions within each series of peptides. If mixtures of peptides from the two different series are separated using either increasing or decreasing gradient rates, large increases in resolution occur due to selectivity, which may be attributed to the difference in the log k vs. phi plots for each series of peptides. In addition, by using a polymer of an X1 peptide, which is 20 residues in length, it has been shown that the molecular mass difference between the X1 and the AX9 series of peptides is not sufficient to account for the selectivity difference. The S value of a non-amphipathic alpha-helical peptide further suggested that the difference in selectivity between the two series of peptides was due to differences in conformation. We believe that the peptide mixtures presented here provide a good model for studying selectivity effects due to conformational differences between peptides, an important concern when attempting to develop rational approaches to the prediction and optimization of peptide separation protocols from primary sequence information alone.

Reversed-phase chromatography of synthetic amphipathic alpha-helical peptides as a model for ligand/receptor interactions. Effect of changing hydrophobic environment on the relative hydrophilicity/hydrophobicity of amino acid side-chains

To mimic a hydrophobic protein binding domain, which is a region on the surface of a protein that has a preference or a specificity to interact with a complementary surface, we have designed amphipathic alpha-helical peptides where the non-polar face interacts with the non-polar surface of a reversed-phase stationary phase. Two series of potentially amphipathic alpha-helical peptides, a native Ala peptide (AA9) and a native Leu peptide (LL9), were designed where the native peptide contains 7 residues of either Ala or Leu, respectively, in its non-polar face. This design results in an overall hydrophobicity of the non-polar face of the Leu peptide that is greater than that of the non-polar face of the native Ala peptide. Mutants of the native Ala-face peptide, AX9, and the native Leu-face peptide, LX9, were designed by replacing one residue in the centre of the non-polar face in both series of peptides. Therefore, by changing the hydrophobicity of the environment surrounding the mutated amino acid side-chain, the effect on the hydrophilicity/hydrophobicity of each amino acid side-chain could be determined. Using the substitutions Ala, Leu, Lys and Glu, it was shown that the maximum hydrophilicity of these amino acid side-chains could be determined when the environment surrounding the mutation is maximally hydrophobic; whereas its maximum hydrophobicity can be determined when the environment surrounding the mutation is minimally hydrophobic. This procedure was further extended to the remaining amino acids commonly found in proteins and it was determined that this general principle applies to all 20 amino acids. These results have major implications to understanding the hydrophilicity/hydrophobicity of amino acid side-chains and the role side-chains play in the folding and stability of proteins.

Reversed-phase liquid chromatography as a useful probe of hydrophobic interactions involved in protein folding and protein stability

We have evaluated the potential of reversed-phase liquid chromatography (RPLC) as a probe of hydrophobic interactions involved in protein folding and stability. Our approach was to apply RPLC to a de novo designed model protein system, namely a two-stranded alpha-helical coiled coil. It was shown that the reversed-phase retention behaviour of various synthetic analogues of monomeric alpha-helices and dimeric coiled-coil structures correlated well with their stability in solution, as monitored by circular dichroism during guanidine hydrochloride and temperature denaturation studies. In addition, an explanation is offered as to why amphipathic coiled coils, an important structural motif in many biological systems, are more stable at low pH compared to physiological pH values. The results of this study suggest that not only may RPLC prove to be a useful and rapid complementary technique for understanding protein interactions, but also the de novo designed coiled-coil model described here is an excellent model system for such studies.

Effect of the alpha-amino group on peptide retention behaviour in reversed-phase chromatography. Determination of the pK(a) values of the alpha-amino group of 19 different N-terminal amino acid residues

We have examined the contribution of the alpha-amino group to retention behaviour for peptides in reversed-phase chromatography using two series of peptide analogues, one containing an N alpha-acetylated terminal and the other containing an alpha-amino group (non-acetylated). The effect of the alpha-amino group, at pH 2, on the hydrophobicity of the side-chain of the N-terminal residue was obtained by referencing the retention time of the acetylated or non-acetylated peptide to the retention time of a glycine analogue. It was shown that the presence of an alpha-amino group could decrease or increase the hydrophobicity of the side-chain of the N-terminal residue with respect to the hydrophobicity of the side-chain in the absence of an alpha-amino group. The effect was also shown to be sequence dependent, with respect to the N-terminal residue. Increasing pH was shown to increase retention time dramatically for the non-acetylated analogues, through the deprotonation of the alpha-amino group. By separating pairs of acetylated/non-acetylated analogues over the pH range 2-9, it was possible to determine the pK(a) of the alpha-amino group, where it was shown that the pK(a) was dependent on two probable factors: (1) the inherent hydrophobicity of the stationary phase; and (2) the amino acid substituted in the N-terminal position. Interestingly, the pK(a) values determined were very similar to that found in proteins. It was also possible to determine the pK(a) values of some of the substituted amino acids containing ionizable side-chains. This study shows that, in order to understand fully the retention behaviour of peptides containing an alpha-amino group in reversed-phase chromatography, one must incorporate an alpha-amino group contribution and its effect on the hydrophobicity of the side-chain of the N-terminal residue.

Hydrophilic-interaction chromatography of peptides on hydrophilic and strong cation-exchange columns

Hydrophilic-interaction chromatography (HILIC) was recently introduced as a potentially useful separation mode for the purification of peptides and other polar compounds. The elution order of peptides in HILIC, which separates solutes based on hydrophilic interactions, should be opposite to that obtained in reversed-phase chromatography, which separates solutes based on hydrophobic interactions. Three series of peptides, two of which consisted of positively charged peptides (independent of pH at pH less than 7) and one of which consisted of uncharged or negatively charged peptides (dependent on pH), and which varied in overall hydrophilicity/hydrophobicity, were utilized to examine the separation mechanism and efficiency of HILIC on hydrophilic and strong cation-exchange columns.

Comparison of silica-based cyanopropyl and octyl reversed-phase packings for the separation of peptides and proteins

The performance of a silica-based C8 packing was compared with that of a less hydrophobic, silica-based cyanopropyl (CN) packing during their application to reversed-phase high-performance liquid chromatography (linear trifluoroacetic acid-water to trifluoroacetic acid-acetonitrile gradients) of peptides and proteins. It was found that: (1) the CN column showed excellent selectivity for peptides which varied widely in hydrophobicity and peptide chain length; (2) peptides which could not be resolved easily on the C8 column were widely separated on the CN column; (3) certain mixtures of peptides and small organic molecules which could not be resolved on the C8 column were completely separated on the CN column; (4) impurities arising from solid-phase peptide synthesis were resolved by a wide margin on the CN column, unlike on the C8 column, where these compounds were eluted very close to the peptide product of interest: and (5) specific protein mixtures exhibited superior resolution and peak shape on the CN column compared with the C8 column. The results clearly demonstrate the effectiveness of employing stationary phases of different selectivities (as opposed to the more common optimization protocol of manipulating the mobile phase) for specific peptide and protein applications, an approach underestimated in the past.

Multi-column preparative reversed-phase sample displacement chromatography of peptides

Preparative reversed-phase sample displacement chromatography (SDC) of peptides was examined utilizing a multi-column approach. The effects of various SDC run parameters (flow-rate, run time and sample load) on the distribution of a single purified peptide and a mixture of three synthetic peptides was examined. The peptides in the mixture were closely related in hydrophobicity and mixed in a 1:4:1 ratio designed to mimic a typical preparative separation problem frequently encountered in crude synthetic peptide mixtures, that is, where there exist both hydrophobic and hydrophilic synthetic impurities close to the product of interest. Based on the results of these model systems, a SDC protocol was applied to the preparative purification of a crude synthetic peptide. The multi-column SDC approach provides rapid separations that are easy to employ because isocratic elution is utilized both in the separation process and in elution of the column segments. There is minimal fraction analysis, minimal use of organic solvents and increased utilization of the stationary phase such that the method involves considerably lower costs than traditional gradient-elution chromatography.

Effect of preferred binding domains on peptide retention behavior in reversed-phase chromatography: amphipathic alpha-helices

A nonpolar environment, such as the hydrophobic stationary phase of a reversed-phase chromatographic packing, may induce helical structures in potentially helical molecules. If a molecule becomes helical on binding and contains a preferred binding domain, as in the case of an amphipathic helix, then some residues may not be contributing to the same extent to the overall hydrophobicity of the peptide. Amphipathic alpha-helical structures may play an important role in protein folding and the interaction of amphipathic alpha-helices with a hydrophobic surface during RPC is likely to be a good mimic of their hydrophobic interactions with other hydrophobic regions in the folded protein. We have designed and synthesized two sets of model peptides of 7, 14, 21, 28 and 35 residues having the same composition but different sequences (Ac-Lys-Cys-Ala-Glu-Gly-Glu-Leu-[Lys-Leu-Glu-Ala-Gly-Glu-Leu]n-amide and Ac-Lys-Cys-Ala-Glu-Leu-Glu-Gly-[Lys-Leu-Glu-Ala-Leu-Glu-Gly]n-amide, where n = 1-4). Circular dichroism studies demonstrated that both sets of peptides had a high potential to form alpha-helical structure in a nonpolar environment, one set representing amphipathic alpha-helical structures and the other set representing non-amphipathic alpha-helical structures. Size-exclusion chromatography confirmed that all of the peptides in both sets were monomeric when bound to a reversed-phase matrix and also under the conditions used for circular dichroism measurements. Peptides with the same amino acid composition and similar secondary structure could be separated by reversed-phase chromatography. The difference in retention time between peptides of the same length increased with the peptide chain length, ranging from a difference of 2.9 min on a C8 column for the two 14-residue peptides up to a maximum difference of 7.3 min for the 35-residue peptides. From the observed and predicted retention times of these two sets of peptides during reversed-phase chromatography, we have demonstrated that it is possible not only to predict the retention behavior of amphipathic alpha-helices during reversed-phase chromatography, but also to deduce the presence of amphipathic alpha-helical structure in peptides based upon their retention data. If from studies such as these we are eventually able to predict, from only amino acid sequence information, the secondary structure of a peptide on binding to a hydrophobic matrix, we may be able to extrapolate this predictive facility to the conformation of the same sequence in larger polypeptides or proteins.

Reversed-phase chromatographic method development for peptide separations using the computer simulation program ProDigest-LC

A computer program, ProDigest-LC, has been developed that assists scientists in devising methods of size-exclusion, cation-exchange and reversed-phase high-performance liquid chromatography for the analytical separation and purification of biologically active peptides and peptide fragments from enzymatic and chemical digests of proteins. ProDigest-LC accurately predicts the retention behaviour of peptides of known composition, containing 2-50 amino acid residues, and simulates the elution profiles in all three modes of chromatography. In addition, ProDigest-LC is a user-friendly program, designed as a teaching aid for both students and researchers in selecting the correct conditions for chromatography, that is, the mode of chromatography, column selection and mobile-phase selection, and has the ability to examine the effects of gradient-rate, flow-rate and sample size on the separation. The simulation capabilities of ProDigest-LC as they apply to the reversed-phase chromatography of peptides were examined. The development of the reversed-phase simulation features of the program is described, stressing the importance of peptide standards in the development, testing and practical use of ProDigest-LC. The ease of use of the program is clearly demonstrated by presenting a step-by-step procedure to produce several of the simulations illustrated in the paper. The predictive accuracy of the program was rigorously tested by its application to retention time prediction, at different gradient-rates and flow-rates, for a sample mixture containing peptides exhibiting a wide range of size (11-50 residues), charge (+1 to +8 net charge), hydrophobicity and conformation (random coil to considerable alpha-helical structure). The excellent accuracy of these peptide retention time predictions complemented the successful simulation (in terms of peptide retention times, peptide resolution, peak heights and peak widths) of the effects of gradient-rate and flow-rate on the elution profile of a mixture of closely related peptide analogues.

Correlation of protein retention times in reversed-phase chromatography with polypeptide chain length and hydrophobicity

The use of amino acid retention or hydrophobicity coefficients for the prediction of peptide retention time behaviour on hydrophobic stationary phases is based on the premise that amino acid composition is the major factor affecting peptide retention in reversed-phase chromatography. Although this assumption holds up well enough for small peptides (up to ca. 15 residues), it is now recognized that polypeptide chain length must be taken into account when attempting to equate retention time behaviour of larger peptides and proteins with their overall hydrophobicity. In the present study, we have examined the reversed-phase retention behaviour of 19 proteins of known sequence on stationary phases of varying hydrophobicity and ligand density. From the observed protein retention behaviour on C4, C8 and C18 stationary phases under gradient elution conditions, we have been able to correlate the observed retention times of proteins ranging in molecular weight from 3500 to 32,000 dalton and in chain length from 30 to 300 residues with their overall hydrophobicity (based on retention parameters derived from small peptides) and the number of residues in the polypeptide chain. The retention behaviour of the proteins on the C4, C8 and C18 columns was also compared to that obtained on supports containing lower ligand densities (phenyl ligands). The maintenance of native or partially folded protein conformation on the phenyl columns, resulting in lower retention times than would be expected for fully denatured proteins, underlined the importance of efficient protein denaturation for satisfactory correlation of protein retention times with protein hydrophobicity. In addition, the effectiveness of increasing temperature and/or ligand density of the stationary phase in denaturing proteins was also demonstrated.

Strong cation-exchange high-performance liquid chromatography of peptides. Effect of non-specific hydrophobic interactions and linearization of peptide retention behaviour

Strong cation-exchange chromatography (strong CEX) is probably the most useful mode of high-performance ion-exchange chromatography (IEC) for peptide separations. Although the hydrophobic character of high-performance ion-exchange packings, often giving rise to mixed-mode contributions to solute separations, has long been recognized, a systematic approach to examining the effect and magnitude of the hydrophobicity of these packings during IEC of peptides has so far been lacking. In the present study, we report the synthesis of three series of positively charged peptide polymers which vary significantly in overall hydrophobicity and polypeptide chain length (5-50 amino acid residues): Ac-(Gly-Lys-Gly-Leu-Gly)n-amide, Ac-(Leu-Gly-Leu-Lys-Ala)n-amide and Ac-(Leu-Gly-Leu-Lys-Leu)n-amide (n = 1, 2, 4 6, 8, 10). We have examined non-specific hydrophobic interactions of these peptides with both silica-and polymer-based ion-exchange packings, demonstrating how these interactions are overcome by the addition of acetonitrile to the mobile phase. It was also shown that removal of non-specific hydrophobic interactions may be necessary just to elute peptides from the ion-exchange matrix. In addition, from the observed retention times of these three peptide polymer series and other peptides which vary substantially in charge density, net charge, polypeptide chain length and hydrophobicity, we have established a simple approach to linearization and, thus, prediction of peptide retention behaviour in CEX.

Computer simulation of high-performance liquid chromatographic separations of peptide and protein digests for development of size-exclusion, ion-exchange and reversed-phase chromatographic methods

A computer program, called Pro Digest-LC, has been developed which assists scientists in devising methods of size-exclusion, cation-exchange and reversed-phase high-performance liquid chromatography for the analytical separation and purification of biologically active peptides and peptide fragments from enzymatic and chemical digests of proteins. Pro Digest-LC accurately predicts the retention behaviour of peptides of known composition, containing 2-50 amino acid residues, and simulates the elution profiles in all three modes of chromatography. In addition, Pro Digest-LC is a user-friendly program, designed as a teaching aid for both students and researchers in selecting the correct conditions for chromatography, that is, the mode of chromatography, column selection, mobile-phase selection, and has the ability to examine the effects of flow-rate, gradient-rate, and sample size on the separation. We have designed a set of peptide standards for each mode of chromatography to aid the researcher in eliminating non-specific interactions, to standardize retention behaviour on the user's columns, to monitor column performance and to compare packing materials. In the development of each prediction mode, experimental peak heights, peak widths, and retention times from model synthetic peptide standards were incorporated directly into the program and can be used as default values. Pro Digest-LC is an interactive program, in that researchers can run peptide standards on their particular columns and enter the peak width at half-height, peak height, retention time and quantity injected to adjust the simulation to their particular column. The simulated experiments eliminate the time-consuming trial-and-error methods used to suitable separation or purification procedures. The researcher would perform the actual experiment only after predicting the optimized conditions, thereby saving valuable sample and research time. The general concepts of the program along with representative separations of protein digests are displayed.

Effect of peptide chain length on peptide retention behaviour in reversed-phase chromatography

The use of amino acid retention or hydrophobicity coefficients for the prediction of peptide retention time and/or the elution order on hydrophobic stationary phases is based on the premise that amino acid composition is the major factor affecting peptide retention in reversed-phase chromatography. Although this assumption generally agrees well for small peptides (up to ca. 15 residues), the retention times of increasingly larger peptides are less than expected from a simple summation of retention coefficients. In the present study, we report the synthesis of four series of peptide polymers which vary significantly in overall hydrophobicity and polypeptide chain length (5-50 amino acid residues, Ac = acetyl): Ac-(G-L-G-A-K-G-A-G-V-G)n-amide (n = 1-5), Ac-(G-K-G-L-G)n-amide (n = 1, 2, 4, 6, 8, 10), Ac-(L-G-L-K-A)n-amide (n = 1, 2, 4, 6, 8, 10) and Ac-(L-G-L-K-L)n-amide (n = 1, 2, 4). From the retention behaviour of these peptide polymers on C4, C8 and C18 stationary phases under gradient elution conditions, we have clearly established the effect of polypeptide chain length and hydrophobicity on peptide retention. This, in turn, has enabled us to extend the utility of retention time prediction for peptides containing up to 50 residues by introducing a peptide chain-length correction.

Protein design using model synthetic peptides

We have designed and synthesized a small, unique protein molecule with defined secondary, tertiary and quaternary structure. This 35-residue peptide, containing a cysteine residue at its N-terminal end, was oxidized to form a 70-residue disulfide-linked two-stranded alpha-helical coiled-coil with the two alpha-helices parallel and in-register. The major contribution to the formation and stabilization of the alpha-helical coiled-coil is hydrophobic interactions between positions 2 and 5 of the heptapeptide repeat (Lys-Leu-Glu-Ala-Leu-Glu-Gly). The protein (L-protein) contains nine leucine-leucine hydrophobic interactions between the alpha-helices of the coiled-coil. Circular dichroism studies demonstrated that this protein in its reduced ([L (r)] or oxidized (L (o)] state was essentially 100% alpha-helical ([theta]220 = -34,050 and -32,000 degrees respectively) at pH 2 (0.1% aqueous trifluoroacetic acid). Our objective was to modify systematically the structure of L to delineate the contribution that various amino acid side chains make to the formation and stabilization of its three-dimensional structure. A-protein, which contains alanine instead of leucine at positions 16 and 19 of the hydrophobic repeat in each chain of the coiled-coil, was compared to the L-protein. At pH 2, the oxidized form of the A-protein [A (o)] was essentially 100% helical. However, the protein was much less stable to temperature denaturation compared to the L-protein. The replacement of two leucine-leucine interactions by two alanine-alanine interactions has a dramatic effect on the formation and stability of the two-stranded alpha-helical coiled-coil structure. The results of this study clearly demonstrate the validity of this synthetic model protein approach to understanding the molecular aspects responsible for the folding and stabilization of protein molecules.