A Study of peptide-peptide interaction by matrix-assisted laser desorption/ionization

Matrix-assisted laser desorption/ionization (MALDI) mass spectrometry was used to study peptide-peptide interaction. The interaction was seen when 6-aza-2-thiothymine was used as a matrix (pH 5.4), but was disrupted with a more acidic matrix, alpha-cyano-4-hydroxycinnamic acid (pH 2.0). In the present study, we show that dynorphin, an opioid peptide, and five of its fragments that contain two adjacent basic residues (Arg6-Arg7), all interact noncovalently with peptides that contain two to five adjacent acidic residues (Asp or Glu). Two other nonrelated peptides containing two (Arg6-Arg7) or three (Arg1-Lys2-Arg3) adjacent basic amino acid residues were studied and exhibited the same behavior. However, peptides containing adjacent Lys or His did not form noncovalent complexes with acidic peptides. The noncovalent bonding was sufficiently stable that digestion with trypsin only cleaved Arg and Lys residues that were not involved in hydrogen bonding with the acidic residues. In an equimolar mixture of dynorphin, dynorphin fragments (containing the motif RR), and an acidic peptide (minigastrin), the acidic peptide preferentially complexed with dynorphin. If the concentration of minigastrin was increased 10 fold, noncovalent interaction was seen with dynorphin and all its fragments containing the motif RR. In the absence of dynorphin, minigastrin formed noncovalent complexes with all dynorphin fragments. These findings suggest that conformation, equilibrium, and concentration do play a role in the occurrence of peptide-peptide interaction. Observations from this study include: (1) ionic bonds were not disrupted by enzymatic digests, (2) conformation and concentration influenced complex formation, and (3) the complex did not form with fragments of dynorphin or unrelated peptides that did not contain the motifs RR or RKR, nor with a fragment of dynorphin where Arg7 was mutated to a phenylalanine residue. These findings strongly suggest that peptide-peptide interaction does occur, and can be studied by MALDI if near physiologic pH is maintained.     

A modified peptide mapping strategy for quantifying site-specific deamidation by electrospray time-of-flight mass spectrometry

A modified peptide mapping strategy using electrospray time-of-flight mass spectrometry with high-performance liquid chromatography (HPLC/MS) provides an improved measure of deamidation by performing proteolytic digestion at low temperature (4 degrees C), low pH (6.0) and in organic solvent (> or =10% acetonitrile). HPLC resolution of the native (N) and deamidated (D) peptides is achieved, and the ratio of ion counts is converted into percent deamidation. The percent deamidation is established for a reference lot using a time course of digestion (24-120 h) and extrapolation to time zero. Test samples are compared against the reference lot to quantitate changes in site-specific deamidation. A recombinant purified protein (antigen A) having a single labile Asn-Gly site is analyzed using this strategy. The N and D peptides from an endoproteinase Lys C (Lys C) digestion (pH 6, 4 degrees C) resolve to near homogeneity on HPLC which results in equivalent percent deamidation when calculated by either UV or ion counts. Deamidation increases with time and pH of proteolysis. Lys C peptide maps of antigen A and bovine serum albumin (BSA) digested at pH 5-8 are comparable. A Lys C digestion time course of a reference lot of antigen A extrapolates to 18% deamidation of the Asn-Gly site at time zero. This strategy may be generally applicable to protease-protein combinations for improved accuracy in measuring site-specific deamidation by peptide mapping LC/MS.     

ZnCl2与氧化胰岛素B链结合位点和切割位点的质谱指认

采用电喷雾质谱和串联质谱研究了氧化胰岛素B链与ZnCl₂的键合作用并成功地确定了切割位点。质谱研究显示在pH值2.5及40 ℃条件下，Zn²⁺通过与氧化胰岛素B链的氨基酸侧链His5,His10和Arg22结合，选择性地水解了肽键Asn3-Gln4, His5-Leu6, Gly8-Ser9和Glu21-Arg22。     

Electrospray low energy CID and MALDI PSD fragmentations of protonated sulfinamide cross-linked peptides

Murine S100A8 (A8) is a major cytoplasmic neutrophil protein and is converted to novel oxidation products containing Cys-epsilon amino-Lys sulfinamide cross-links and Met-sulfoxide by the neutrophil oxidant HOCl. Seven products were separated using RP-HPLC, with electrospray ionization mass spectrometry (ESI-MS) masses after deconvolution of 10,354, 10,388, +/- 1, and 20,707, +/- 3 Da, and all were resistant to reduction by dithiothreitol. The major products with masses of 10,354 Da contained Cys41-Lys34/35 intramolecular cross-links. Additional isomeric products with identical masses (10,354 Da) were isolated and peptide mapping and ESI/MS indicated that Cys41 forms covalent sulfinamide cross-links with either Lys6, Lys76, Lys83, or Lys87 present in A8. Electrospray low energy collisionally induced (CID) spectra of multiply-charged AspN digest peptides with sulfinamide cross-links contained characteristic fragmentations that corresponded to simple cleavage of the nitrogen-sulfur bond with charge retention on either of the fragment ions, allowing conformation of cross-linked peptides. Matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) post source decay spectra of [M + H] + ions of the same sulfinamide-containing cross-linked peptides fragment similarly, but additional facile fragmentation reactions corresponding to formation of a protonated peptide containing de-hydroalanine were attributed to cleavage of the carbon-sulfur bond. In addition, lose of methanesulfenic acid from Met-sulfoxide was observed. A sulfinamide-containing adduct was isolated after incubation of the A8/HOCl reaction mixture with Lys or alpha N-acetyl Lys with masses of 10,500 or 10,542 Da. ESI/MS/MS and MALDI/post decay source (PSD) analysis of A8(32)-(57)-sulfinamide showed the same characteristic fragmentations as those in the sulfinamide cross-linked peptides, confirming the Cys41-Lys sulfinamide cross-link and suggesting that peptide-peptide sulfinamides may all fragment similarly, allowing ready identification of these cross-links in proteins from more complex biological materials.     

Products of Cu(II)-catalyzed oxidation of alpha-synuclein fragments containing M1-D2 and H50 residues in the presence of hydrogen peroxide

Metal-catalyzed oxidation (MCO) of proteins is mainly a site-specific process in which one or a few amino acids at metal-binding sites on the protein are preferentially oxidized. The oxidation of proteins by MCO can lead to oxidation of amino acid residue side chains, cleavage of the peptide bonds and formation of covalent protein-protein cross-linked derivatives. In an attempt to elucidate the products of the copper(II)-catalyzed oxidation of the 29-56, M29-D30-56 and Ac-M29-D30-56 fragments of alpha-synuclein, high performance liquid chromatography (HPLC) and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) methods and Cu(II)/hydrogen peroxide as a model oxidizing system were employed. The peptide solution (0.50 mM) was incubated at 37 degrees C for 24 h with metal : peptide : hydrogen peroxide 1 : 1 : 4 molar ratio in phosphate buffer, pH 7.4. Oxidation targets for all studied peptides are the histidine residues coordinated to the metal ions. For the M29-D30-56 and Ac-M29-D30-56 peptides the oxidation of the methionine residue to methionine sulfoxide and sulfone is observed. The cleavage of the peptide bond M29-D30 for the M29-D30-56 peptide was detected as metal binding residues. The fragmentations of the M29-D30-56 peptide near the Lys residues were observed supporting the participation of this (Lys) residue in the coordination of the copper(II) ions.     

Multidimensional NMR spectroscopy for the study of histone H4-Ni(II) interaction

The N-terminal 30-amino acid tail of histone H4, a nuclear protein, was studied as a model for the interaction of this protein with Ni(ii) ions. The behaviour of the ends-blocked Ac-SGRGKGGKGLGKGGA(15)K(16)R(17)H(18)R(19)KVLRDNIQGIT-Am fragment towards Ni(ii) was analyzed with multidimensional NMR (1D, 2D TOCSY, NOESY) and UV-Vis spectroscopy. As expected, the coordination involved the imidazolic nitrogen of the His(18) residue and the three deprotonated amidic nitrogens of the His(18), Arg(17) and Lys(16) residues, respectively. A model for the structure of the complex was calculated from the inter-residual NOEs recorded in 2D NOESY spectra. The structure obtained shows that the interaction with the metal is responsible for deep changes in the conformation of the peptide, blocking the side chain of Arg(17) and Lys(16) residues above the coordination plane. These structural modifications may be physiologically relevant to the mechanism of nickel carcinogenesis.     

High-performance liquid chromatographic system for the separation of dynorphin A (1-17) fragments and its application in enzymolysis studies with rat nerve terminal membranes

A high-performance liquid chromatographic method capable of separating a large number of C- and N-terminal degradation fragments of dynorphin A (1-17) (dyn 1-17) in 1 h has been developed. The system has been applied to study the metabolism profiles of various dyn 1-17-derived peptides following in vitro incubation with rat striatum and spinal cord nerve terminal membranes. In addition to the removal of the N-terminal amino acid Tyr, major sites of cleavage between the following amino acids could be established: Leu5-Arg6 in dyn 1-7 (formation of dyn 1-5); Arg6-Arg7 and Leu5-Arg6 in dyn 1-8 (formation of dyn 1-6 and dyn 1-5, respectively); Arg7-Ile8 in dyn 1-9 (formation of dyn 1-7) and Arg9-Pro10 in dyn 1-10 (formation of dyn 1-9). Studies with inhibitors of the enzymes involved show that dyn 1-5 is formed directly from dyn 1-8 via an endopeptidase insensitive to the angiotensin-converting enzyme inhibitor MK 422 acting on the scissile Leu5-Arg6 bond in dyn 1-8. The method circumvents the use of [3H]Tyr-labelled dynorphins, which have the inherent drawback that fragments lacking the N-terminal Tyr cannot be detected. Owing to the high resolution, also for the larger dynorphins dyn 1-14, dyn 1-15 and dyn 1-16, the chromatographic system should prove especially useful in the elucidation of the enzymolysis pattern of dyn 1-17. Furthermore, the method offers a way to evaluate simultaneously the selectivity of new enzyme inhibitors for several cleavage sites in the same assay.     

Solvent extraction of amino acids into a room temperature ionic liquid with dicyclohexano-18-crown-6

Amino acids Trp, Gly, Ala, Leu are extracted efficiently from aqueous solution at pH 1.5–4.0 (Lys and Arg at pH 1.5–5.5) into the room temperature ionic liquid 1-butyl-3-methylimidazolium hexafluorophosphate (BmimPF₆) with dicyclohexano-18-crown-6 (CE). The most hydrophilic amino acids such as Gly are extracted as efficiently as the less hydrophilic (92–96%). The influence of pH, amino acid and crown ether concentration, volume ratio of aqueous and organic phases, and presence of some cations on amino acid recovery were studied. The ratio of amino acid to crown ether in the extracted species is 1:1 for cationic Trp, Leu, Ala, and Gly and to 1:2 for dicationic Arg and Lys. This ionic liquid extraction system was used successfully for the recovery of amino acids from pharmaceutical samples and fermentation broth, and was followed by fluorimetric determination.These results were published in part in Smirnova SV (2002) Ph.D. Thesis, Moscow State University.     

Mass spectrometry assisted assignments of binding and cleavage sites of Zn(Ⅱ)complex towards oxidized insulin B chain

The electrospray ionization mass spectrometry investigation showed that the binding sites of [ZnL]2+, where L is 2-[bis(2-aminoethyl)aminolethanol, with oxidized insulin B chain are Phe1, His5 and Arg22, which lead to the selective cleavages of the peptide bonds at Phe1-Val2, His5-Leu6, Glu21-Arg22, and Arg22-Gly23 of oxidized insulin B chain.     

Examination of the folding of a short alanine-based helical peptide with salt bridges using molecular dynamics simulation

A molecular dynamics simulation of the folding of a short alanine-based helical peptide of 17 residues with three Glu...Lys (i, i + 4) salt bridge pairs, referred to as the AEK17 peptide, was carried out. The simulation gave an estimated simulation folding time of 2.5 ns, shorter than 12 ns for an alanine-based peptide of 16 residues with three Lys residues only, referred to as the AK16 peptide, simulated previously. After folded, the AEK17 peptide had a helical content of 77%, in excellent agreement with the experimentally determined value of 80%. An examination of the folding pathways of AEK17 indicated that the peptide proceeded via three-turn helix conformations more than the helix-turn-helix conformation in the folding pathways. An analysis of interactions indicated that the formation of hydrogen bonds between Lys residue side chains and backbone carbonyls is a major factor in the abundant conformation of the three-turn helix intermediate. The substitution of three Ala with Glu residues reduces the extent of hydrophobic interaction in alanine-based AK peptides with the result that the breaking of the interactions of Lys epsilon-NH3+(side chain)...C=O(backbone) is a major activation action for the AEK17 to achieve a complete fold, in contrast to the AK16 peptide, in which breaking non-native hydrophobic interaction is the rate-determining step.     

Site-specifically cleavage of oxidized insulin B chain with Zn（Ⅱ） ion studied by electrospray ionization mass spectrometry

The electrospray ionization mass spectrometry and tandem mass spectrometry investigation showed that the binding sites of Zn^2＋ with oxidized insulin B chain are His 5, His 10, and Arg 22, which lead to the selective cleavages of the peptide bonds at Ash 3- Gin 4, His 5-Leu 6, Gly 8-Ser 9, and Glu 21-Arg 22 of oxidized insulin B chain.     

The role of water and K ion in the charge transfer between groups of DNA and the lysine and arginine side chains of histone proteins

We have calculated the charge transfer (CT) between the group of DNA and the lysine (Lys) and arginine (Arg) positive side chains of histones in presence of water and K⁺ ions. The calculations were performed at the HF + MP2 level, using the TZVP basis set. The calculations were corrected for basis set superposition error and besides Mulliken’s population analysis we have introduced the – for charged systems more reliable – natural population analysis. The results show that the bare -Lys and the -Arg interactions become weaker, mainly, due to the presence of the K⁺ ion. We have found 0.067e CT for Lys and 0.050e for Arg.     

Enzymatic coupling of specific peptides at nonspecific ligation sites: effect of Asp189Glu mutation in trypsin on substrate mimetic-mediated reactions

Two main drawbacks seriously restrict the synthetic value of proteases as reagents in peptide fragment coupling: (i) native proteolytic activity and, thus, risk of undesired peptide cleavage; (ii) limited enzyme specificities restricting the amino acid residues between which a peptide bond can be formed. While the latter can be overcome by the use of substrate mimetics achieving peptide bond formation at nonspecific ligation sites, the risk of proteolytic cleavage still remains and hinders the wide acceptance of this powerful strategy for peptide coupling. This paper reports on the effect of the trypsin point mutant Asp189Glu on substrate mimetic-mediated reactions. The effect of this mutation on the steady-state hydrolysis of substrate mimetics of the 4-guanidinophenyl ester type and on trypsin-specific Lys- and Arg-containing peptides was investigated. The results were confirmed by enzymatic coupling reactions using substrate mimetics as the acyl donor and specific amino acid-containing peptides as the acyl acceptor. The competition assay verifies the predicted shift in substrate preference from Lys and Arg to the substrate mimetics and, thus, from cleavage to synthesis of peptide bonds. The combination of results obtained qualifies the trypsin mutant D189E as the first substrate mimetic-specific peptide ligase.     

Artificial metalloprotease with active site comprising aldehyde group and Cu(II)cyclen complex

To design artificial proteases that cleave peptide backbones of a wide range of proteins at selected sites, artificial active sites comprising the Cu(II) complex of cyclen (Cu(II)Cyc) and aldehyde group were synthesized on a cross-linked polystyrene. The aldehyde group was employed as the binding site in view of its ability of reversible formation of imine bonds with epsilon-amino groups of Lys residues exposed on the surface of proteins and Cu(II)Cyc as the catalytic group for peptide hydrolysis. The two polymeric artificial metalloproteases synthesized in the present study cleaved all of the protein substrates examined (myoglobin, gamma-globulin, bovine serum albumin, human serum albumin, lysozyme, and ovalbumin), manifesting saturation kinetic behavior. At 50 degrees C and pH 9.0 or 9.5, K(m) was (1.3-22) x 10(-)(4) M, comparable to those of natural proteases, and k(cat) was (6.0-25) x 10(-)(4) s(-)(1), corresponding to half-lives of 4.6-19 min. Intermediacy of the imine complexes formed between the aldehyde group of the catalyst and the epsilon-amino groups of Lys residues of the substrates was confirmed by the trapping experiment with NaB(OAc)(3)H. MALDI-TOF MS of the proteolytic reaction mixtures revealed formation of various cleavage products. Structures of some of the cleavage products were determined by using carboxypeptidase A and trypsin. Among various cleavage sites thus identified, Gln(91)-Ser(92) and Ala(94)-Thr(95) were the major initial cleavage sites in the degradation of myoglobin by the two catalysts. The selective cleavage of Gln(91)-Ser(92) and Ala(94)-Thr(95) was attributed to general acid assistance in peptide cleavage by Tyr(146) located in proximity to the two peptide bonds. Broad substrate selectivity, high cleavage-site selectivity, and high proteolytic rate are achieved, therefore, by positioning the aldehyde group in proximity to Cu(II)Cyc attached to a cross-linked polystyrene.     

Application of an anhydrotrypsin-immobilized precolumn for selective separation of peptides having arginine or lysine at their C-termini by column-switching high-performance liquid chromatography

A column-switching high-performance liquid chromatographic (CS-HPLC) system which consisted of an anhydrotrypsin (AHT)-immobilized diol-silica precolumn and a reversed-phase analytical column was developed for the selective separation of peptides having Arg or Lys at their C-termini. Tuftsin (Thr-Lys-Pro-Arg) could be enriched almost quantitatively on the precolumn when loaded with water as a carrier solvent and the precolumn was washed with 10-30 mM acetate buffer (pH 5.0). An investigation of the affinity characteristics of 55 peptides to the AHT precolumn showed that among twelve peptides having Arg or ArgNH2 at their C-termini and more than four amino acid residues, ten were retained almost quantitatively on the precolumn, and eight out of nine peptides having Lys at their C-termini were less retained. The peptide having D-Arg at its C-termini was not retained. However, twelve out of thirty peptides having no Arg or Lys at their C-termini were also retained, but the retention was greatly decreased, in contrast to the Arg peptides, when the precolumn was washed with 20 mM calcium chloride solution. The results indicate that the CS-HPLC system equipped with an AHT precolumn offers new selectivity in the HPLC selectivity in the HPLC separation of peptides.     

Molecular dynamics simulation of folding of a short helical peptide with many charged residues

A molecular dynamics simulation of the folding of conantokin-T (con-T), a short helical peptide with 5 helical turns of 21 amino acids with 10 charged residues, was carried out to examine folding pathways for this peptide and to predict the folding rate. In the 18 trajectories run at 300 K, 16 trajectories folded, with an averaged folding time of approximately 50 ns. Two trajectories did not fold in up to 200 ns simulation. The folded structure in folded trajectories is in good agreement with experimental structure. An analysis of the trajectories showed that, at the beginning of a few nanoseconds, helix formation started from residues 5-9 with assistance of a hydrophobic clustering involving Tyr5, Met8, and Leu9. The peptide formed a U-shape mainly due to charge-charge interactions between charged residues at the N- and C-terminus segments. In the next approximately 10 ns, several nonnative charge-charge interactions were broken and nonnative Gla10-Lys18 (this denotes a salt bridge between Gal10 and Lys18) and/or Gla10-Lys19 interactions appeared more frequently in this folding step and the peptide became a fishhook J-shape. From this structure, the peptide folded to the folded state in 7 of all 16 folded trajectories in approximately 15 ns. Alternatively, in approximately 30 ns, the con-T went to a conformation in an L-shape with 4 helical turns and a kink at the Arg13 and Gla14 segment in the other 9 trajectories. Con-T in the L-shape then required another approximately 15 ns to fold into the folded state. In addition, in overall folding times, the former 7 trajectories folded faster with the total folding times all shorter than 45 ns, while the latter 9 trajectories folded at a time longer than 45 ns, resulting in an average folding time of approximately 50 ns. Two major folding intermediates found in 2 nonfolded trajectories are stabilized by charge clusters of 5 and 6 charged residues, respectively. With inclusion of friction and solvent-solvent interactions, which were ignored in the present GB/SA solvation model, the folding time obtained above should be multiplied by a factor of 1.25-1.7 according to a previous, similar simulation study. This results in a folding time of 65-105 ns, slightly shorter than the folding time of 127 ns for an alanine-based peptide of the same length. This suggests that the energy barrier of folding for this type of peptides with many charged residues is slightly lower than alanine-based helical peptides by less than 1 kcal/mol.     

Optimization of a nano‐enzymatic reactor for on‐line tryptic digestion of polypeptide conjugates by capillary electrophoresis

This work aims at studying the optimization of an on‐line capillary electrophoresis (CE)‐based tryptic digestion methodology for the analysis of therapeutic polypeptides (PP). With this methodology, a mixture of surrogate peptide fragments and amino acid were produced on‐line by trypsin cleavage (enzymatic digestion) and subsequently analyzed using the same capillary. The resulting automation of all steps such as injection, mixing, incubation, separation and detection minimizes the possible errors and saves experimental time. In this paper, we first study the differents parameters influencing PP cleavage inside the capillary (plug length, reactant concentration, incubation time, diffusion and electrophoretic plugs mixing). In a second part, the optimization of the electrophoretic separation conditions of generated hydrolysis products (nature, pH and ionic strength (I) of the background electrolyte (BGE)) is described. Using the optimized conditions, excellent repeatability was obtained in terms of separation (migration times) and proteolysis (number of products from enzymatic hydrolysis and corresponding amounts) demonstrating the robustness of the proposed methodology.     

Essential of Proline and Valine Residues in the Peptide Derived from Lactoferrin for Angiotensin Converting Enzyme Inhibition

We synthesized Leu‐Arg‐Pro‐Val‐Ala‐Ala‐Glu, the peptide contained in lactoferrin (Lf), to identify the angiotensin converting enzyme (ACE) inhibition. In an attempt to know the structure‐activity relationship of this peptide, we replaced Pro (the third amino acid residues from N‐terminal) or Val (the fourth amino acid residues from N‐terminal) with Ala (neutral amino acid), Glu (acidic amino acid) or Lys (basic amino acid) to produce six peptides. From the in vitro ACE inhibition (IC₅₀) of these synthesized peptides, the original peptide (Leu‐Arg‐Pro‐Val‐Ala‐Ala‐Glu) showed higher ACE inhibition than the replaced six peptides. Thus, replacement of Pro at the third amino acid residues or Val at the fourth position with Ala, Glu or Lys revealed the ACE inhibition to be lower than the original form of Leu‐Arg‐Pro‐Val‐Ala‐Ala‐Glu. Otherwise, we added one peptide at the C‐terminal of Leu‐Arg‐Pro‐Val‐Ala‐Ala‐Glu and found both products with an addition of Val (Leu‐Arg‐Pro‐Val‐Ala‐Ala‐Glu‐Val) or Ile (Leu‐Arg‐Pro‐Val‐Ala‐Ala‐Glu‐Ile) showing a lower ACE inhibition than the original one. The ACE inhibitions produced by both replaced peptides were without significance. Also, deletion of the last peptide at the C‐terminal (Leu‐Arg‐Pro‐Val‐Ala‐Ala) failed to produce a marked change of ACE inhibition as compared to the original one. These results suggest that Pro and Val are essential in the peptide for inhibition of ACE activity.     

Cellular Fatty Acid Composition of Vibrio parahaemolyticus by Reversed-Phase High-Performance Liquid Chromatography

Abstract

High-performance liquid chromatography was used to separate and identify cellular fatty acids isolated from Vibrio parahaemolyticus, a gram-negative estuarine microorganism associated with seafood-borne enteritis in man. Fatty acids were isolated from statically grown bacterial cultures, saponified, and derivatized with an ultraviolet tag. Aliquots of derivatized fatty acids were injected onto a reversed-phase column with water:acetonitrile gradient as the mobile phase and ultraviolet detection at 254 nm. The predominant fatty acids found for the V. parahaemolyticus strains studied were C12, C14, C16:1, C16, C18:1, and C18. In addition, previously unreported fatty acids C13, C17, C19, and C21 were identified. Comparison of HPLC with GLC fatty acid separations showed good agreement with the exception that HPLC was able to resolve previously unidentified fatty acid constituents.     

Electrokinetically-driven cation-exchange chromatography of proteins and its comparison with pressure-driven high-performance liquid chromatography.

This paper examines protein ion-exchange behavior in electrokinetically-driven open-tubular chromatography with columns produced by immobilization of poly(aspartic acid) on capillary walls. Retention and selectivity are similar in the electrokinetic elution mode to that observed in HPLC. The separation mechanism was found to depend on the relationship of mobile phase pH to that of protein pI and ionic strength. Column efficiency in the electrokinetic elution mode was found to be 10-100-times higher than in HPLC. The best separations were achieved at intermediate ionic strength and high pH. The great advantage of these low-phase-ratio, high-efficiency open tubular columns is that isocratic separations in the electrokinetic elution mode were equivalent to gradient elution in the HPLC mode. Low phase ratio has the net effect of collapsing the chromatogram into a narrow elution window while the very high efficiency produces the requisite resolution.