High-performance liquid chromatography column length designed for submicrogram scale protein isolation

Ultra-short columns for the chromatographic analysis of large molecules

Today, reverse phase liquid chromatography (RPLC) analysis of proteins is almost exclusively performed on conventional columns (100-150 mm) in gradient elution mode. However, it was shown many years ago that large molecules present an on/off retention mechanism, and that only a very short inlet segment of the chromatographic column retains effectively the large molecules. Much shorter columns - like only a few centimetres or even a few millimetres - can therefore be used to efficiently analyse such macromolecules. The aim of this review is to summarise the historical and more recent works related to the use of very short columns for the analysis of model and therapeutic proteins. To this end, we have outlined the theoretical concepts behind the use of short columns, as well as the instrumental limitations and potential applications. Finally, we have shown that these very short columns were also possibly interesting for other chromatographic modes, such as ion exchange chromatography (IEX), hydrophilic interaction chromatography (HILIC) or hydrophobic interaction chromatography (HIC), as analyses in these chromatographic modes are performed in gradient elution mode.

Ultra-short ion-exchange columns for fast charge variants analysis of therapeutic proteins

The purpose of this work was to study the potential of recently developed ultra-short column hardware for ion exchange chromatography (IEX). Various prototype and commercial columns having lengths of 5, 10, 15, 20 and 50 mm and packed with non-porous 3 µm particles were systematically compared. Both pH and salt gradient modes of elution were evaluated. Similarly, what has been previously reported for reversed phase liquid chromatography (RPLC) mode, an "on-off" retention mechanism was observed in IEX for therapeutic proteins and their fragments (25-150 kDa range). Because of the non-porous nature of the IEX packing material, the column porosity was relatively low (ε = 0.42) and therefore the volumes of ultra-short columns were very small. Based on this observation, it was important to reduce as much as possible all the sources of extra-column volumes (i.e. injection volume, extra-bed volume, detector cell volume and connector tubing volume), to limit peak broadening. With a fully optimized UHPLC system, very fast separations of intact and IdeS digested mAb products were successfully performed in about 1 min using an IEX column with dimensions of 15 × 2.1 mm. This column was selected for high-throughput separations, since it probably offers the best compromise between efficiency and analysis time. For such ultra-fast separations, PEEK tubing was applied to bypass the column oven (column directly connected) to the optical detector via a zero dead volume connection.

Single-step electrotransfer of reverse-stained proteins from sodium dodecyl sulfate-polyacrylamide gel onto reversed-phase minicartridge and subsequent desalting and elution with a conventional high-performance liquid chromatography gradient system for analysis

Isolation of proteins from polyacrylamide electrophoresis gels by a novel combination of techniques is described. A given protein band from a reverse stained (imidazol-sodium dodecyl sulfate--zinc salts) gel can be directly electrotransferred onto a reversed-phase chromatographic support, packed in a self-made minicartridge (2 mm in thickness, 8 mm in internal diameter, made of inert polymeric materials). The minicartridge is then connected to a high-performance liquid chromatography system and the electrotransferred protein eluted by applying an acetonitrile gradient. Proteins elute in a small volume ( < 700 microL) of high-purity volatile solvents (water, trifluoroacetic acid, acetonitrile) and are free of contaminants (gel contaminants, salts, etc). Electrotransferred proteins were efficiently retained, e.g., up to 90% for radioiodinated alpha-lactalbumin, by the octadecyl matrix, and their recovery on elution from the minicartridge was in the range typical for this type of chromatographic support, e.g., 73% for alpha-lactalbumin. The technique was successfully applied to a variety of proteins in the molecular mass range 6-68 kDa, and with amounts between 50 and 2000 pmol. The good mechanical and chemical stability of the developed minicartridges, during electrotransfer and chromatography, allowed their repeated use. This new technique permitted a single-step separation of two proteins unresolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis due to their different elution from the reversed-phase support. The isolated proteins were amenable to analysis by N-terminal sequencing, enzymic digestion and mass spectrometry of their proteolytic fragments. Chromatographic elution of proteins from the reversed-phase mini-cartridge was apparently independent of the specific loading mode employed, i.e., loading by conventional loop injection or by electrotransfer.

Protein blotting followed by microsequencing

The use of new membranes such as activated or derivatized glass fibers as well as synthetic membranes, which are compatible with the hazardous sequencing reagents, are described. Precautions to be taken in order to prevent N-terminal blockage of the proteins during electrophoresis and blotting are described, as well as the conditions for protein detection after blotting and protein treatment for in situ amino acid analysis, fragmentation and microsequencing. For a number of standard proteins and bacterial ribosomal proteins microsequence analysis is reported for two commercially available sequencers (Applied Biosystems and Knauer).

Food analysis on silica-bound HPLC phases

HPLC analysis of food on various silica bonded phases has been described. Technical and theoretical aspects of the materials such as normal-, reverse-, ion-exchange-, affinity-, chiral-, size-exclusion-, and ion-phases have been discussed. Special problems such as mobile phase or solvent-selection, selectivity and mechanisms of resolution on these bonded phases have been mentioned. Application of various bonded materials such as amino, cyano, diol, amino-cyano, C-18, C-8, anion-exchangers, strong and weak-cation exchangers, chiral and enzyme bound affinity phases to analyze and determine food components such as carbohydrates, food colors and pigments, flavors, proteins, vitamins and toxins has been described.

Isolation and sequence analysis of proteins from mouse forebrain using two-dimensional gel electrophoresis coupled to high-pressure liquid extrusion

This report presents a technique for recovery of mouse forebrain proteins from two-dimensional sodium dodecyl sulfate-polyacrylamide gels for subsequent primary structure determination. Proteins were visualized by Coomassie staining or salt precipitation and manually cut out of the gel. Excised spots were minced and loaded into an empty precolumn of a reversed-phase high-performance liquid chromatography system. Purified protein was extruded from a gel matrix by pressurized liquid, then separated from gel contaminants by reversed-phase gradient elution, and finally collected in siliconized tubes or on polybrene-coated filter disks for gas-phase sequencing. Several mouse and rat forebrain proteins were purified by this method and sequenced. Three previously unidentified mouse brain proteins with molecular weights of 4,000, 12,000, and 18,500 were partially sequenced and three hemoglobin fragments were structurally identified and mapped. Ribonuclease A, myoglobin, adrenocorticotropin, and bovine somatotropin were also subjected to two-dimensional (2-D) analysis and partially sequenced. Recovery values of 27-95% were obtained for extruded 14C-labeled ribonuclease, carbonic anhydrase, and bovine serum albumin out of sodium dodecyl sulfate-polyacrylamide gel electrophoretic gels. Losses resulting from the multiple handling steps of a 2-D gel separation process were also investigated. Recoveries of 12-17%, as determined by sequencing signals, were achieved. These latter recovery values reflect overall losses incurred in gel-focusing, gel-sizing, staining, destaining, high-pressure liquid extrusion, and N-terminal blockage. This work demonstrates that an array of protein spots can be systematically identified or defined by partial sequencing after high-pressure liquid extrusion from a 2-D gel matrix.(ABSTRACT TRUNCATED AT 250 WORDS)

Bidimensional reversed-phase high-pressure liquid chromatography analysis of cultured cell neuropeptides: application to atrial natriuretic factor

We report here a one-step procedure for extraction and analysis of neuropeptides in chromaffin cell culture media and acid extracts using reversed-phase HPLC. The bidimensional HPLC system consists of a precolumn connected to a six-port switching valve which is on-line with an analytical column. The direct injection of the biological samples onto the precolumn previously equilibrated with 15% acetonitrile allows the elimination of interfering substances. The samples purified on the precolumn can then be eluted onto the analytical column via the switching valve for neuropeptide separation. This trace-enrichment system allows a minimum of sample handling, both saving time and reducing possibilities of loss and contamination. This method has been applied to monitor the precursor and mature forms of atrial natriuretic factor from chromaffin cell secretion media and cell content extracts. The recovery of atrial natriuretic factor is in the range of 80-100%. This procedure could be applied to the study of the precursor-product relationship of any neuropeptide, e.g., from radiolabeled extracts of pulse-chase experiments performed on cultured chromaffin cells.

Micropreparative high-performance liquid chromatography of proteins and peptides

The use of short microbore reversed phase and ion-exchange HPLC columns in the preparation of low level (submicrogram) quantities of proteins and peptides is discussed. The sequential use of columns of differing selectivity to purify complex mixtures is described. An example is given of the use of microbore columns to purify a murine myeloid leukemia inhibitory factor prior to sequence analysis.

Separation of proteins by microcolumn liquid chromatography based on the reversed-phase and size-exclusion principles

Slurry-packed fused-silica microcolumns of 250 micron I.D., are characterized for use in high-performance liquid chromatographic studies of proteins. The present work utilizes the reversed-phase and size-exclusion chromatographic modes for the separation of standard protein mixtures. A 5-micron, 300-A octyl material is utilized for the reversed-phase studies, and the size-exclusion studies are accomplished with 5-micron diol material of 60-, 100- and 300-A pore sizes. Column efficiency and packing reproducibility, as well as sample capacity in a micropreparative mode, are discussed. In addition, the inherent mass sensitivity of a microcolumn liquid chromatography system as applied to protein detection is demonstrated.

Synthesis of a non-porous, polystyrene-based strong anion-exchange packing material and its application to fast high-performance liquid chromatography of proteins

Adsorbed coating technology has been used to produce a strong anion-exchange stationary phase on 3-micron non-porous poly(styrene-divinylbenzene) particles. In order to take full advantage of the excellent kinetic properties of the resultant packing material, small columns of 5 mm X 6 mm I.D. were used. These columns were pressure- and pH-stable and allowed protein separations to be made in less than 1 min at ambient temperature.

Applications of tandem microbore liquid chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis/electroblotting in microsequence analysis

Protein isolation by microbore HPLC is compared with sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)/electroblotting methods for several major proteins from rabbit muscle. Although single-mode HPLC or SDS-PAGE/electroblotting provides excellent speed and sensitivity for submicrogram-level protein purification, neither one alone has adequate resolution for separating such a complex protein mixture. Tandem procedures, utilizing two different modes of HPLC in separate steps or a combination of single HPLC separation and SDS-PAGE/electroblotting, offer the necessary versatility. One of the major concerns in this investigation was to evaluate electroblotting techniques for microsequencing. The Aebersold et al. procedure (R.H. Aebersold, D.B. Teplow, L.E. Hood, and S.B.H. Kent (1986) J. Biol. Chem. 261, 4229-4238) was substantially modified and improved; the details of this work will be published elsewhere. These changes significantly improve repetitive yields at the low microgram level without producing high backgrounds. At lower levels the recovery of sequenceable protein currently limits our ability to obtain useful results. Starting with 250-750 micrograms of rabbit muscle crude extract, several proteins (15-70 kDa) were isolated by tandem microbore LC and PAGE/electroblotting for amino-terminal sequence analysis. It appears that the combination of electroblotting and microbore LC represents a powerful approach for microsample preparation.

Resolution of proteins in linear gradient elution ion-exchange and hydrophobic interaction chromatography

The following equation was derived for the resolution, Rs, of proteins in linear gradient elution ion-exchange and hydrophobic interaction chromatography: Rs alpha [(column length.molecular diffusivity)/(slope of the gradient.column gel volume.linear mobile phase velocity.particle diameter2)]1/2. Experimental results obtained under a wide range of experimental conditions (column length, 1-30 cm; particle diameter, 37-92 micron; linear mobile phase velocity, 0.2-3.5 cm/min; temperature, 15-35 degrees C) have shown that this relationship is valid except for very short columns with a shallow slope of the gradient and for low flow-rates. The relationship is very useful for scaling-up the linear gradient elution of proteins from data obtained with small columns.

Column liquid chromatography of integral membrane proteins

Biological membranes have as a major function the compartmentation of biological processes in cells and organelles. They consist of a bilayer of phospholipid molecules in which proteins are embedded. These integral membrane proteins, which cross the bilayer once or several times, generally have a higher than average hydrophobicity and tend to aggregate. Detergents are needed to remove integral membrane proteins from the lipid bilayer and they have to be present during further chromatographic purification. Predominantly, four modes of HPLC have been used alone or in combination for the purification of integral membrane proteins. These are based on differences of proteins in size (size-exclusion chromatography, SEC), electrostatic interaction (ion-exchange chromatography, IEC), bioaffinity (bioaffinity chromatography, BAC) and hydrophobic interaction (reversed-phase chromatography, RPC, and hydrophobic-interaction chromatography, HIC). SEC, IEC, BAC and HIC are used under relatively mild conditions, and buffer systems generally contain a non-ionic detergent. RPC generally has a denaturing effect on the protein and should preferably be used for the purification of integral membrane proteins smaller than 50 kD.

Microbore flow-rates and protein chromatography

Reversed-phase chromatography of proteins on microbore columns can achieve sensitivities that exceed those for standard-bore columns by a factor of 10-20, when operated at the same linear velocities. These gains in sensitivity are accompanied by proportional reductions in peak volume. Sensitivities on standard- (4.6 mm I.D.) and narrow-bore (2.1 mm I.D.) columns have been further improved by reducing the flow-rates to those typical for microbore (1 mm I.D.) columns. We have investigated the role of flow-rate in determining peak volumes for a constant time gradient and found that flow-rate affects peak volume to a much greater extent than column diameter. Column length was not found to have a significant effect on either peak volume or sensitivity. We have found that a four-fold reduction in flow-rate results in at least a two-fold reduction in peak volume over the flow-rate range from 25 to 400 microliters/min. Recovery of proteins in smaller volumes should prove beneficial to subsequent protein characterization methodologies.