Isoelectric focusing of basic proteins: the problem of oxidation of cysteines

Separation of basic proteins from Leishmania using a combination of Free flow electrophoresis (FFE) and 2D electrophoresis (2-DE) under basic conditions

Basic proteins, an important class of proteins in intracellular organisms such as Leishmania, are usually underrepresented on 2D gels. This chapter describes a method combining basic proteins fractionation using Free flow electrophoresis in isoelectric focusing mode (IEF-FFE) followed by protein separation using two-dimensional gel electrophoresis (2-DE) in basic conditions. The combination of these two techniques represents a great improvement for the visualization of Leishmania proteins with basic pI using 2D gels.

A simple technique to improve the resolution of membrane acidic proteins of the haloarchaeon Haloferax volcanii by 2D electrophoresis

Proteins present in the archaeal cell envelope play key roles in a variety of processes necessary for survival in extreme environments. The haloarchaeon Haloferax volcanii is a good model for membrane proteomic studies because its genome sequence is known, it can be genetically manipulated, and a number of studies at the "omics" level have been performed in this organism. This work reports an easy strategy to improve the resolution of acidic membrane proteins from H. volcanii by 2DE. The method is based on the solubilization, delipidation, and salt removal from membrane proteins. Due to the abundance of the S-layer glycoprotein (SLG) in membrane protein extracts, other proteins from the envelope are consequently underrepresented. Thus, a protocol to reduce the amount of the SLG by EDTA treatment was applied and 11 cm narrow range pH (3.9-5.1) IPG strips were used to fractionate the remaining proteins. Using this method, horizontal streaking was substantially decreased and at least 75 defined spots (20% of the predicted membrane proteome within this pI/Mw range) were reproducibly detected. Two of these spots were identified as thermosome subunit 1 and NADH dehydrogenase from H. volcanii, confirming that proteins from the membrane fraction were enriched. Removal of the SLG from membrane protein extracts can be applied to increase protein load for 2DE as well as for other proteomic methods.

Quantitative neuroproteomics: classical and novel tools for studying neural differentiation and function

Mechanisms underlying neural stem cell proliferation, differentiation and maturation play a critical role in the formation and wiring of neuronal connections. This process involves the activation of multiple serial events, which guide the undifferentiated cells to different lineages via distinctive developmental programs, forming neuronal circuits and thus shaping the adult nervous system. Furthermore, alterations within these strictly regulated pathways can lead to severe neurological and psychiatric diseases. In this framework, the investigation of the high dynamic protein expression changes and other factors affecting protein functions, for example post-translational modifications, the alterations of protein interaction networks, is of pivotal importance for the understanding of the molecular mechanisms responsible for cell differentiation. More recently, proteomic studies in neuroscience ("neuroproteomics") are receiving increased interest for the primary understanding of the regulatory networks underlying neuronal differentiation processes. Besides the classical two-dimensional-based proteomic strategies, the emerging platforms for LC-MS shotgun proteomic analysis hold great promise in unraveling the molecular basis of neural stem cell differentiation. In this review, recent advancements in label-free LC-MS quantitative neuroproteomics are highlighted as a new tool for the study of neural differentiation and functions, in comparison to mass spectrometry-based labeling approaches. The more commonly used protein profiling strategies and model systems for the analysis of neural differentiation are also discussed, along with the challenging proteomic approaches aimed to analyze the nervous system-specific organelles, the neural cells secretome and the specific protein interaction networks.

Highlights on the capacities of "Gel-based" proteomics

Gel-based proteomic is the most popular and versatile method of global protein separation and quantification. This is a mature approach to screen the protein expression at the large scale, and a cheaper approach as compared with gel-free proteomics. Based on two independent biochemical characteristics of proteins, two-dimensional electrophoresis combines isoelectric focusing, which separates proteins according to their isoelectric point, and SDS-PAGE, which separates them further according to their molecular mass. The next typical steps of the flow of gel-based proteomics are spots visualization and evaluation, expression analysis and finally protein identification by mass spectrometry. For the study of differentially expressed proteins, two-dimensional electrophoresis allows simultaneously to detect, quantify and compare up to thousand protein spots isoforms, including post-translational modifications, in the same gel and in a wide range of biological systems. In this review article, the limits, benefits, and perspectives of gel-based proteomic approaches are discussed using concrete examples.

Two-dimensional electrophoresis in proteome expression analysis

Cell proteomes are complex, given they consist of several thousand proteins. Two-dimensional electrophoresis (2DE) is unique not only for its ability to simultaneously separate thousands of proteins but also for detecting post- and co-translational modifications, which cannot be predicted from genome sequences. This review will describe the protocols applied to prepare 2D gels properly, and analyse and summarise the major challenges for successful proteome analysis using 2DE, i.e. the ability to analyse very alkaline, hydrophobic and/or low or high M(r) proteins with high resolution and the ability to detect minor components. Challenges involving sample preparation and solubilisation prior to the first dimension IEF/IPG step will be studied in depth. Sample preparation is crucial in 2DE studies and greatly influences other stages of the technique. It is the aim of this review not only to describe the challenges and limitations of 2DE but also to suggest the avenues, the evolution, the potential and the future of 2DE in proteomics.

Reduction of proteins during sample preparation and two-dimensional gel electrophoresis of woody plant samples

Protein extraction procedure and the reducing agent content (DTT, dithioerythritol, tributyl phosphine and tris (2-carboxyethyl) phosphine (TCEP)) of the sample and rehydration buffers were optimised for European beech leaves and roots and Norway spruce needles. Optimal extraction was achieved with 100 mM DTT for leaves and needles and a mixture of 2 mM TCEP and 50 mM DTT for roots. Performing IEF in buffers containing hydroxyethyldisulphide significantly enhanced the quality of separation for all proteins except for acidic root proteins, which were optimally focused in the same buffer as extracted.

Comparison of theoretical proteomes: identification of COGs with conserved and variable pI within the multimodal pI distribution

BACKGROUND

Theoretical proteome analysis, generated by plotting theoretical isoelectric points (pI) against molecular masses of all proteins encoded by the genome show a multimodal distribution for pI. This multimodal distribution is an effect of allowed combinations of the charged amino acids, and not due to evolutionary causes. The variation in this distribution can be correlated to the organisms ecological niche. Contributions to this variation maybe mapped to individual proteins by studying the variation in pI of orthologs across microorganism genomes.

RESULTS

The distribution of ortholog pI values showed trimodal distributions for all prokaryotic genomes analyzed, similar to whole proteome plots. Pairwise analysis of pI variation show that a few COGs are conserved within, but most vary between, the acidic and basic regions of the distribution, while molecular mass is more highly conserved. At the level of functional grouping of orthologs, five groups vary significantly from the population of orthologs, which is attributed to either conservation at the level of sequences or a bias for either positively or negatively charged residues contributing to the function. Individual COGs conserved in both the acidic and basic regions of the trimodal distribution are identified, and orthologs that best represent the variation in levels of the acidic and basic regions are listed.

CONCLUSION

The analysis of pI distribution by using orthologs provides a basis for resolution of theoretical proteome comparison at the level of individual proteins. Orthologs identified that significantly vary between the major acidic and basic regions maybe used as representative of the variation of the entire proteome.

A simplified 2-D electrophoresis protocol with the aid of an organic disulfide

2-DE is still a relatively cumbersome and labor intensive method. Given the successful cysteinyl protection concept with hydroxyethyl disulfide (specific oxidation) during the first dimension separation, the possibility for a simplified equilibration procedure was investigated. This was achieved by maintaining the S-mercaptoethanol modified cysteinyls throughout the 2-D workflow including second dimension separation, spot handling, protein digestion, and protein identification. The traditional equilibration protocol encompassing thiol reduction and alkylation was compared with a one-step protocol employing continuous exposure to hydroxyethyl disulfide. Both equilibration protocols gave equally well-resolved spot maps with analytical protein loads regardless of IPG strip pH range. Using preparative protein loads, narrow range IPG strips gave comparable results for the two protocols while preparative load on wide range IPG strips was the only condition where classical reduction/alkylation outperformed hydroxyethyl disulfide equilibration. Moreover, with analytical protein loads, the hydroxyethyl disulfide equilibration time could be significantly reduced without apparent loss of spot map quality or quantitative protein transfer from the first- to the second dimension gel. MALDI-TOF mass spectrometric protein identification was successfully performed with either iodoacetamide or hydroxyethyl disulfide as the cysteine modifier, yielding comparable identification results with high confidence in protein assignment, sequence coverage, and detection of cysteine-containing peptides. The results provide a novel and simplified protocol for 2-DE where the concept of hydroxyethyl disulfide as the cysteinyl protecting agent is extended to cover the entire 2-D work flow.

A “de-streaking” method for two-dimensional electrophoresis using the reducing agent tris(2-carboxyethyl)-phosphine hydrochloride and alkylating agent vinylpyridine

Optimal isoelectric focusing in the alkaline region remains a challenge in two-dimensional gel electrophoresis (2-DE), though various attempts had been made to reduce basic end streaking. The present study reports the application of a novel reduction and alkylation step prior to 2-DE analysis using tris(2-carboxyethyl)-phosphine hydrochloride as a reducing agent and vinylpyridine as an alkylating agent. This simple sample preparation approach effectively eliminates basic end streaks, thereby enabling the analysis and identification of more protein spots resolved by 2-DE.

Current two-dimensional electrophoresis technology for proteomics

Two-dimensional gel electrophoresis (2-DE) with immobilized pH gradients (IPGs) combined with protein identification by mass spectrometry (MS) is currently the workhorse for proteomics. In spite of promising alternative or complementary technologies (e.g. multidimensional protein identification technology, stable isotope labelling, protein or antibody arrays) that have emerged recently, 2-DE is currently the only technique that can be routinely applied for parallel quantitative expression profiling of large sets of complex protein mixtures such as whole cell lysates. 2-DE enables the separation of complex mixtures of proteins according to isoelectric point (pI), molecular mass (Mr), solubility, and relative abundance. Furthermore, it delivers a map of intact proteins, which reflects changes in protein expression level, isoforms or post-translational modifications. This is in contrast to liquid chromatography-tandem mass spectrometry based methods, which perform analysis on peptides, where Mr and pI information is lost, and where stable isotope labelling is required for quantitative analysis. Today's 2-DE technology with IPGs (Görg et al., Electrophoresis 2000, 21, 1037-1053), has overcome the former limitations of carrier ampholyte based 2-DE (O'Farrell, J. Biol. Chem. 1975, 250, 4007-4021) with respect to reproducibility, handling, resolution, and separation of very acidic and/or basic proteins. The development of IPGs between pH 2.5-12 has enabled the analysis of very alkaline proteins and the construction of the corresponding databases. Narrow-overlapping IPGs provide increased resolution (delta pI = 0.001) and, in combination with prefractionation methods, the detection of low abundance proteins. Depending on the gel size and pH gradient used, 2-DE can resolve more than 5000 proteins simultaneously (approximately 2000 proteins routinely), and detect and quantify < 1 ng of protein per spot. In this article we describe the current 2-DE/MS workflow including the following topics: sample preparation, protein solubilization, and prefractionation; protein separation by 2-DE with IPGs; protein detection and quantitation; computer assisted analysis of 2-DE patterns; protein identification and characterization by MS; two-dimensional protein databases.

Electrically neutral microheterogeneity of human plasma transthyretin (prealbumin) detected by isoelectric focusing in urea gradients

Mutants of the human plasma transthyretin (TTR, prealbumin) have attracted interest due to their rather frequent association with the autosomal dominant disease familial amyloidotic polyneuropathy (FAP). Some three quarters of known TTR mutations produce electrically neutral amino acid substitutions undetectable via separation by charge. We have developed an electrophoretic procedure sensitive to differences in the stability of tetramers and monomers under partially denaturing conditions. The differential folding states were found to be fully reversible. Applying the procedure we found 14 electrically silent mutants of TTR among 2000 plasma samples from German donors. We demonstrate that the normal TTR monomer exists in different forms of variable stability and/or charge due to binding of sulfhydryls from plasma to the unique cysteine at position 10 of the primary structure as well as due to modification by treatment with an oxidant. We found that reduction of Cys10 increases the stability of the folded monomeric and tetrameric conformations. The conformational changes of TTR induced by isoelectric focusing in a urea gradient were found to be associated by a gain of three positive charge units. Using published crystallographic data we present structural sites in the TTR molecule which could explain the observed effects.

Isoelectric focusing as a tool for the investigation of post-translational processing and chemical modifications of proteins

It has been demonstrated that good agreement may be observed between computed and experimental isoelectric point (pI) values when proteins of known sequence are focused under denaturing conditions on immobilized pH gradient IPG slabs, at least in the pH range 4-7.5. Hence, discrepancies between expected and found in this experimental set-up may be reliably ascribed to some kind of post-transcriptional processing, or chemical modification, having taken place in the sample. This evaluation is made easier when the comparison is set between the pI of a parent molecule and that (or those) of one to several of its derivatives as resolved in a single experiment (for instance, as a spot row in two-dimensional maps); no previous knowledge is required in these cases about the amino acid composition of the primary structure. The effects on protein surface charge are discussed in this review mainly for two biologically relevant processes, glycosylation and phosphorylation. Then, the pI shifts are analysed for some protein modifications that may occur naturally but can also be artefactually elicited, such as NH2 terminus blocking, deamidation and thiol redox reactions. Finally, carboxymethylation and carbamylation are used to exemplify chemical treatments often applied in connection with electrophoretic techniques and involving charged residues. Procedures to be applied in order to verify whether a given modification has occurred, and often relying on the focusing of a treated specimen, are detailed in each section. Numerical examples on model proteins are also discussed. As an important field of application of the above concepts may be genetic engineering, an exhaustive bibliographic list dealing with pI evaluation and structural assessment on recombinant proteins is included.

Commercial automated gel electrophoresis apparatus: application to DNA, band dispersion, nonlinear Ferguson curves, and isolation

Recently available commercial automated gel electrophoresis apparatus with intermittent scanning of fluorescently labeled gel patterns (the HPGE-1000 apparatus of LabIntelligence, Menlo Park CA) was tested with regard to (i) its applicability to DNA in its native conformation, (ii) its ability to recognize the correct number of components, (iii) its capability to evaluate the width and shape of bands detected during electrophoresis, (iv) its ability to yield nonlinear Ferguson plots in a labor-saving fashion, and (v) its preparative potential. Ethidium homodimer (EtD) DNA (bp) ratios were systematically varied and the mobility of DNA fragments labeled at each ratio was measured in order to find a ratio which provided an unaltered mobility and presumably therefore an unaltered conformation of the fragment. That ratio was found to be 1/40 EtD/DNA (bp) or less. With such weak labeling of DNA, a representative fragment of 527 bp length requires a minimum load of 200 ng and a 2 micrograms load for a full-scale peak height. Using the baseline automatically selected by the software of the apparatus, the band areas of the 17 components of a DNA digest were consistently evaluated by the software, as evidenced by the proportionality between DNA length and area. The areas of the separated bands of DNA fragments of 1857 and 121 bp length were found to be constant with time of electrophoresis. The dispersion coefficient was found to decrease with agarose concentration in electrophoresis at 1 V/cm; however, at higher field strength, the band width of the 1857 bp fragment was surprisingly found to increase with gel concentration, presumably due to stretching.(ABSTRACT TRUNCATED AT 250 WORDS)

Solute focusing techniques for bioseparations

The growth of industrial biotechnology has had a major impact on the research and development of both analytical and preparative focusing techniques. Pioneering methods such as isoelectric focusing are being modified to overcome the limitations of batch mode operation, scale up difficulties, high power requirement, and excessive heat generation. present advances in focusing techniques have been made by either overcoming the limitations of standard techniques or by investigating new focusing systems. Here we review the background and history of isoelectric focusing and discuss several new focusing techniques including recycle isoelectric (RIEF), counteracting chromatographic electrophoresis (CACE), and countercurrent gradient chromatography (CGC).

Isoelectric focusing in immobilized pH gradient of melon (Cucumis melo L.) seed protein: methodical and genetic aspects, and application in breeding

Genetic variability of melon seed proteins was studied by separation of seed protein by isoelectric focusing in immobilized pH gradient (IEF-IPG) under denaturing conditions. A routine procedure was developed for IEF-IPG of hundreds of individual melon seeds per day. A group of 74 accessions from 19 morphologically distinct groups and from different geographic origin were studied by IEF-IPG using pH gradients of 4-10, 4-7 and 6-10. The electrophoretic analysis of the 74 accessions showed 270 reproducible seed protein bands of which 70 were variable. Genetic evaluation led to the conclusion that at least 20 loci govern the variation found. The phylogenetic trees constructed using the protein data on one hand and the morphological data on the other hand were compared and their use was evaluated. A number of commercial Cantaloup F1 hybrid descendants derived from the F1 hybrids by diplohaploidization or single plot descent were studied by IEF-IPG using pH gradients of 4-7 and 6-10. Among the F1 hybrids and their descendants 265 reproducible protein bands could be identified of which 72 were variable as to presence versus absence. The genetic interpretation of the protein pattern as found by IEF-IPG and the use of IEF-IPG in plant breeding was discussed. It was concluded that IEP-IPG of melon seed proteins is a valuable tool in breeding.

Reference points for comparisons of two-dimensional maps of proteins from different human cell types defined in a pH scale where isoelectric points correlate with polypeptide compositions

A highly reproducible, commercial and nonlinear, wide-range immobilized pH gradient (IPG) was used to generate two-dimensional (2-D) gel maps of [35S]methionine-labeled proteins from noncultured, unfractionated normal human epidermal keratinocytes. Forty one proteins, common to most human cell types and recorded in the human keratinocyte 2-D gel protein database were identified in the 2-D gel maps and their isoelectric points (pI) were determined using narrow-range IPGs. The latter established a pH scale that allowed comparisons between 2-D gel maps generated either with other IPGs in the first dimension or with different human protein samples. Of the 41 proteins identified, a subset of 18 was defined as suitable to evaluate the correlation between calculated and experimental pI values for polypeptides with known composition. The variance calculated for the discrepancies between calculated and experimental pI values for these proteins was 0.001 pH units. Comparison of the values by the t-test for dependent samples (paired test) gave a p-level of 0.49, indicating that there is no significant difference between the calculated and experimental pI values. The precision of the calculated values depended on the buffer capacity of the proteins, and on average, it improved with increased buffer capacity. As shown here, the widely available information on protein sequences cannot, a priori, be assumed to be sufficient for calculating pI values because post-translational modifications, in particular N-terminal blockage, pose a major problem. Of the 36 proteins analyzed in this study, 18-20 were found to be N-terminally blocked and of these only 6 were indicated as such in databases. The probability of N-terminal blockage depended on the nature of the N-terminal group. Twenty six of the proteins had either M, S or A as N-terminal amino acids and of these 17-19 were blocked. Only 1 in 10 proteins containing other N-terminal groups were blocked.

Electrophoretic artifacts arising from the use of thiol-containing reagents

Thiol reagents migrate as a curtain behind the salt front when loaded with the sample solution onto disc-electrophoresis gels. In immobilized pH gradients (IPG) the same compounds are driven by electrophoresis and electroosmosis from the alkaline to the neutral and acidic regions of the gradients. In either case, a dose-dependent sideways spreading results in spurious reduction between adjacent lanes if samples with and without reducing agent are loaded side by side.

Isolation and characterization of basic myotoxic phospholipases A2 from Bothrops godmani (Godman's pit viper) snake venom

Two basic myotoxic phospholipases A2 were purified to homogeneity from the venom of Bothrops godmani from Costa Rica by ion-exchange chromatography on CM-Sephadex. They have molecular weights of 14,300 (myotoxin I) and 13,400 (myotoxin II) and isoelectric points of 8.2 (myotoxin I) and 8.9 (myotoxin II). They behave as amphiphilic proteins in charge-shift electrophoresis and have similar amino acid compositions. Both toxins induce drastic myotoxic effects when injected in the gastrocnemius muscle of mice and induce release of peroxidase trapped in negatively charged liposomes. In addition, myotoxin I has high phospholipase A2 activity and is anticoagulant at doses higher than 0.3 microgram/ml, whereas myotoxin II has a very low phospholipase A2 activity and exerts anticoagulant effect only at concentrations higher than 50 micrograms/ml. Immunochemical data indicate that both toxins are immunologically related to Bothrops asper myotoxins, although B. godmani myotoxin II gives a stronger cross-reactivity when tested with antisera raised against B. asper myotoxins I and II.

Phenotyping of apolipoprotein E by immunoblotting in immobilized pH gradients

An immunoblotting method for the determination of apolipoprotein E (apoE) phenotypes has been developed. Delipidated plasma proteins are focused in an immobilized pH gradient, and transferred to polyvinylidene difluoride (PVDF) membranes. ApoE isomorphs are identified by immunoperoxidase staining. The method allows reproducible assignment of apoE phenotypes without isolation of triglyceride-rich lipoproteins. Only small amounts of serum are required. There are several important steps in the procedure: (i) delipidation is indispensable, (ii) carrier ampholytes have to be added to the gels and to the sample buffer, and, (iii) on immunostaining, polyvinylidene difluoride membranes provide an excellent signal-to-background ratio.

Separation of durum wheat proteins by ultrathin-layer isoelectric focusing: a new tool for the characterization and quantification of low molecular weight glutenins

An isoelectric focusing method capable of resolving all groups of storage protein of the wheat seed, including the most basic low molecular weight glutenin (LMWG), was developed. Ultrathin polyacrylamide gels were used after drying and rehydration with 8 M urea, 50 mM DTE and 2.4% carrier ampholytes (pH 4-9). Densitometric scanning of the isoelectric focusing gels permitted a more accurate and specific quantitation of LMWG components among various cultivars than patterns based on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The two main genetic types (i.e. 'gamma-42' and 'gamma-45') of durum wheats were separated on the basis of the proportion in LMWG in storage proteins, but no significant difference was found within these groups. Advantages of the system as regards reliability, high resolution, ability to abolish protein oxidation and preventing reaggregation of LMWG were also discussed.

Electrofocusing of acid phosphatases from frog liver, using an immobilized pH gradient

Isoelectric focusing on carrier ampholyte-containing immobilized pH gradient gels was applied (i) to gels submerged in silicone oil on a Peltier cooled apparatus, (ii) to the separation of the higher molecular weight (HMW, Mr 140,000) and the lower molecular weight (LMW, Mr 38,000) acid phosphatases (AcPases) from frog livers. (i) Electrofocusing was conducted on gels submerged under silicone oil cooled and stirred on a Peltier-thermoregulated horizontal gel support plate. This procedure aimed at a) improving the temperature control of the gel by direct contact of coolant with the gel surface, and thus at being able to focus at the maximal field strength and consequently highest resolution; b) preventing evaporation from the gel and c) excluding atmospheric carbon dioxide. Silicone oil submersion did not abolish water loss from the gel into the electrolyte strips during isoelectric focusing, or a rippled gel surface. Absence of water exudation on the ripples noted previously by Atland [1] was observed. (ii) The electrofocusing of AcPases on immobilized pH gradients yielded patterns which remained stationary as a function of time, by contrast to previous analyses on carrier ampholyte generated pH gradients. The total number of enzymatically active components found in the enzyme preparations from different stages of purification and in the isolated HMW and LMW AcPases was 18. The HMW and LMW AcPases focused in characteristic pH ranges and exhibited qualitative and quantitative pattern differences. Their band patterns add up to that of a crude preparation containing both enzymes. Neither polyacrylamide gel electrophoresis (PAGE) at any nondenaturing pH, nor isoelectric focusing in carrier ampholytes with pattern changes due to the pH gradient drift were able to yield that result.

Formulations for immobilized pH gradients including pH extremes

Formulations are given both for narrow (less than 2 pH units) and for wide range (up to 8 pH units) immobilized pH gradients, spanning between pH 2.5 and pH 11. The contribution from water to the buffering power (beta) at these pH extremes requires the recipes to be optimized (in terms of gradient linearity) for each desired level of beta av.

Moving and stationary boundaries in immobilized pH gradients

The relations describing the concentration changes at moving boundaries in a medium containing bound, buffering group are derived for a system which, except for hydrogen and hydroxyl ions, contains one anionic and one cationic mobile constituent. The relations found have been used to calculate concentrations and conductivities in zones developing in immobilized pH gradients. Assumptions used in the calculations as well as conductivity ratios between zones have been experimentally controlled and were found to reasonably agree with expectations. It is also shown how difference in transference numbers between sample droplet and gel will cause concentration and pH changes at the gel-sample droplet interfaces and it is explained how these changes are related to ionic concentrations in the gel. The high concentration zone generated at one of the interfaces will be transported into the gel. This transport has been numerically simulated and experimentally verified. The low concentration generated at the opposite interface will cause titration impeding sample entrance in the gel through this interface even when the gel contains ions other than H+ or OH- transported towards the interface. The described phenomena explain the dependence of lateral spreading, precipitation at the application site as well as streaking and smearing along sample lanes, on the type and concentration of low molecular weight ions originally present in the gel.

A new sample applicator for isoelectric focusing in horizontal polyacrylamide gels

A new sample applicator for horizontal flat gels is described. The applicator is practically safe against contamination from adjacent samples and can be used for all types of electrophoretic separations including a concentration step for either the sample (i.e. disc electrophoresis) or the separated zones (i.e. isoelectric focusing). The applicator is a piece of flat glass with 26 or 51 parallel 2 mm wide grooves, drilled at distances of 9 or 4.5 mm. Samples, maximally 25 or 50, are applied to the areas between the grooves. By inverting the applicator, the samples are brought into close vicinity to the gel surface and the pendant droplets expand by capillary attraction into the slits between the glass and gel with resultant even distribution across the lanes of 2.5 or 7 mm width. The applicator can be used for separations with and without protection of the electrophoretic setup by paraffin oil and allows for fast multiple handling of samples by means of appropriate syringes and microtiter plates.