EP1334353A1

EP1334353A1 - Method for separating and detecting proteins by means of electrophoresis

Info

Publication number: EP1334353A1
Application number: EP01996736A
Authority: EP
Inventors: Markus Hammermann; Herbert Platsch; Gerhard Weber; Heinz Eipel
Original assignee: BASF SE; Dr Weber GmbH
Current assignee: BASF SE; Dr Weber GmbH
Priority date: 2000-11-16
Filing date: 2001-11-14
Publication date: 2003-08-13
Also published as: AU1702902A; JP2004514136A; WO2002040983A1; CA2428372A1; NO20032209D0; NO20032209L; US20040031683A1

Abstract

The invention relates to a method for separating and detecting proteins or protein samples of cellular origin. Said proteins are contained in a separation buffer solution and the following steps are carried out: the protein samples are separated into individual fractions in a first separating step by means of free flow electrophoresis, isoelectric focusing (IEF) or isotachophoresis, and are linked with a marker; the protein fractions are separated into at least one capillary by means of capillary electrophoresis in a second separating step; and at least one marker linked with the protein fractions is detected in the at least one capillary.

Description

METHOD FOR SEPARATING AND DETECTING PROTEINS BY ELECTROPHORESIS

The invention relates to a method for separating and detecting proteins in order to accelerate proteome analysis.

A proteome is the term used to describe and quantify all proteins of an organism, a cell, an organelle or a body fluid at a defined point in time and under precisely defined conditions. In proteome analysis, proteins are examined to determine which proteins play which role in biological processes and which proteins are of particular importance in interaction with other proteins. Furthermore, the question of the extent to which chemicals, active substances and other external factors (environmental influences, heat, cold, lack of water, pH value, etc.) influence cellular protein expression is investigated in the context of proteome analysis. In toxicology and pharmacology, proteome analysis also tries to find out which proteins in which protein constellations can be responsible for which side effects. Finally, the question is examined whether the protein expression of microorganisms can be influenced in such a way that the space-time yields of fermentative production processes can be improved.

For technical reasons - regarding both the separation and the detection - a complete quantitative observation and evaluation of all proteins of a proteome has not been possible so far; Hydrophobic proteins, proteins of extreme size, be they particularly large or particularly small, strongly acidic or strongly basic, cause serious problems in the separation of such proteins, so that complete proteomes cannot be detected even under otherwise optimal conditions. It is currently assumed that significantly more than 50% of all expressed proteins can be quantified.

In view of the large number of expressed proteins, sample preparation poses a significant problem. In the sample preparation phase, the course is set to separate and identify even complex protein patterns. It has been found that the solubility has a significant influence on the separation of proteins. Proteins that dissolve quickly in water generally do not pose any problems with regard to separability.

Proteins with stable secondary or tertiary structures that are sparingly water-soluble are stabilized in terms of their solubility behavior by adding chaotropic substances such as guanidine hydrochloride or urea. However, undesired reactions of individual proteins can occur, whereby a protein originally present in one form changes into several forms and thus further increases the heterogeneity of the sample already present.

Membrane proteins, the natural environment of which are lipid membranes and which tend to agglomerate and become insoluble again when they are isolated from one another, are particularly difficult to handle. These hydrophobic proteins can only be kept in the dissolved state if detergents are added, which, however, can frequently impair the subsequent stages of protein separation.

High protein concentrations are highly desirable for most separation and evaluation procedures, but are associated with the risk that aggregations will form. In contrast, low protein concentrations, which have a positive effect on the solubility behavior, are associated with additional preparation steps before the actual separation.

The previous separation techniques in the area of the molar mass of proteins are electrophoresis on the one hand and chromatography on the other. However, neither of these two separation techniques can separate much more than 100 different components from proteins alone. However, since a simple cell usually contains several thousand different species of proteins and the amount of proteins contained in a sample can differ by a factor of 10 ⁶ , a sufficiently large separation capacity must be provided, which can only be achieved by coupled, multidimensional separation processes can be.

Proteins have the character of zwitterions and can therefore be positively or negatively charged. Using electrophoresis methods, individual components can be separated according to their mobility in the electrical field. The electrophoretic

Mobility of each protein is a characteristic value. As part of proteome analysis two electrophoresis methods are used, isoelectric focusing (IEF) and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE).

In isoelectric focusing, the individual proteins on the gel move within a pH gradient to their respective isoelectric point, at which they balance their net charge and thus lose their electrophoretic mobility. If a protein moves out of the pH region corresponding to the isoelectric charge due to thermal diffusion, it takes on a charge again and moves back in the electric field to the point in the pH gradient that corresponds to its isoelectric point.

The SDS-PAGE method provides for the loading of all proteins with sodium dodecyl sulfate (= SDS); the negative SDS-protein complexes move towards the anode in the electric field and can be separated according to their molecular sizes in the polyacrylamide matrix.

The combination of the IEF and SDS-PAGE methods gave rise to 2D gel electrophoresis (2D-PAGE) according to Klose and O'Farrell 1975 (J. Biol. Chem. 1975, 250, 4007 to 4020; human genetics 1975, 25, 231 to 245).

This method provides for the separation of the proteins in the first dimension with the isoelectric focusing according to their isoelectric point. The second dimension is a sodium dodecyl sulfate-polyacrylamide gel electrophoresis to separate the proteins according to their size. This method is currently the only procedure with which complex protein mixtures can be separated with high resolution. The advantages of the 2D-PAGE process are the two mutually complementary separation principles, namely IEF and SDS-PAGE processes according to load and molecular weight. In principle, this technique can be used with all proteins. The resolution of this method can be increased significantly by using narrow pH gradients in isoelectric focusing ("zoom gels").

On the other hand, there are disadvantages with this method; some experience and skill in sample preparation is required. The order quantity is limited so that weakly expressed proteins cannot be detected directly. Protein transfer from the first to the second dimension is difficult and difficult to reproduce. There is no simple automation option with this method. Not all proteins are detected by this method either. For molecular weights less than 10,000 and For molecular weights greater than 100,000, no satisfactory and meaningful results are obtained. After separation in the gel, the proteins still have to be stained in a complex manner.

Staining is carried out, for example, with dyes such as Coomassie blue, with colloidal silver, with zinc / imidazole or with fluorescent dyes such as Sypro ^® Ruby, Sypro ^® Orange or Sypro ^® Red. All dyeing methods used have in common that the bond between protein and dye reagent is not covalent , but on the basis of ionic, hydrophobic or Van der Waal interactions. After staining, the gels are usually digitized using a scanner or a fluorescence scanner.

US 6,043,025 and US 6,127,134 describe a process and a kit with which one can detect differences in two or more protein samples. The protein extracts from different samples are covalently labeled with different, positively charged fluorescent dyes, combined and subjected to 2D PAGE. Identical proteins from the different samples can then be detected and quantified on the basis of their different fluorescence wavelengths in the same gel. According to the solution disclosed in US Pat. No. 6,127,134, the proteins of a first cell are prepared using known treatment techniques, the first cell originating from a first group of cells. The proteins are covalently labeled with a first dye from a pair of dyes. Then a second cell is prepared using known treatment techniques that were taken from a second group of cells. The proteins of this second cell are covalently labeled with a second dye.

As an alternative to these staining methods, radioactive methods can also be used. For this purpose, the cells are mixed with certain isotope-labeled compounds such as ³⁵ S-cysteine or ³² PO ₄ ^{3 "} . After the 2D-PAGE, a phosphor imager is usually used for digitization in these cases. With image evaluation programs such as MELANIE, PDQUEST, IMAGEMASTER or The protein spots are then detected, quantified and assigned in the digitized gels obtained.The recognition of the individual spots and the assignment of the spots between the individual gels (= "matches") are very time-consuming and require manual intervention by the operator. The entire procedure from electrophoresis to staining, detection and quantification according to the 2D-PAGE method is very complex.

In view of the technical problems outlined, the object of the invention is to develop a separation method for proteins which reduces the use of gels, is quick and easy to carry out and can be automated, and allows simple quantification of the separated proteins.

According to the invention, this object is achieved by a method for the separation and detection of proteins, the protein samples being contained in a separation buffer solution and the following method steps being carried out:

In a first separation step, the protein samples are broken down into individual fractions according to free-flow electrophoresis with isoelectric focusing (IEF) or isotachophoresis and with a

Linked marking substance;

in a second separation step, the protein fractions are separated in one or more capillaries according to capillary electrophoresis, at least one labeling substance being detected in the individual capillary (s).

The advantages of the method proposed according to the invention can be seen above all in the fact that the separation of the proteins or the cellular proteins can now be carried out simultaneously with several samples in an automated manner. This significantly increases the sample throughput. Furthermore, with the method proposed according to the invention, the current complicated, personnel-intensive image evaluation can be dispensed with. Furthermore, the sample application quantity to be applied can be considerably reduced. A suitable labeling method such as fluorescent labeling can significantly increase the sensitivity and thus the resolution with regard to the detection of weakly expressed proteins.

In an advantageous embodiment variant of the method proposed according to the invention, protein fractions obtained after the first separation step are linked with a reactive fluorescent dye. This can be done, for example, by coupling the N-hydroxysuccinimide esters (NHS esters) or isothiocyanates of fluorescent dyes to free amino groups of the proteins. Free amino groups are preferably the N-termini or lysine selected as coupling sites. In contrast to fluorescent stains in polyacrylamide gel, the dyes can be covalently bound to the individual proteins in the process proposed according to the invention.

In an advantageous embodiment variant of the method proposed according to the invention, protein fractions obtained after the first separation step are mixed with a marking substance. This can be done, for example, by adding a fluorescent dye e.g. Sypro® Ruby, Sypro Orange or Sypro Red. The fluorescent dyes Sypro Ruby, Sypro Orange or Sypro®Red can be bound by adsorption, e.g. by hydrophobic, ionic or Van der Waal's forces.

In a second separation step, capillaries can be used which are either provided with a polyacrylamide gel or which do not contain this substance, i.e. are empty. The individual proteins are detected in the second separation step using laser-induced fluorescence. Sensitive fluorescence detection ensures a wide dynamic range and high sensitivity.

In order to improve the running behavior of the proteins in the context of capillary electrophoresis, sodium dodecyl sulfate can be added to the separation buffer. Due to the high separation performance of capillary electrophoresis, a significantly better resolution in the second dimension is achieved compared to the 2D-PAGE gel process; Furthermore, the high degree of automation of both separation steps, the FFE and the capillary electrophoresis, enables a significantly higher throughput and thus a better statistical validation of the results obtained. In order to ensure the parallel processing of a higher number of protein samples after free-flow electrophoresis, all wells of a microtiter plate can be detected and quantified separately in parallel by as many capillaries. This can be achieved, for example, by using a commercially available device for DNA sequencing.

Advantageously, several different fluorescent dyes can be detected simultaneously in each capillary in the second separation step. This means that several protein samples labeled with different fluorescent dyes can be separated simultaneously in one capillary. This enables protein samples from different experimental conditions according to the FFE-IEF method and Combine fluorescence labeling and separate in a single capillary electrophoresis run. The previously necessary assignment of the individual spots in the individual gels, the so-called matching, is no longer necessary.

The sensitive fluorescence detection ensures a large dynamic range and high sensitivity. Due to the high separation performance of capillary electrophoresis, a significantly better resolution in the second dimension is achieved compared to the 2D PAGE gel process. Due to the high degree of automation of both separation steps, FFE and capillary electrophoresis, a significantly higher throughput and thus a better statistical validation of the measured results is expected.

The separation of the protein samples in the first separation step can e.g. in an advantageous manner in a microtiter plate, a microtiter plate being used, the number of wells of which corresponds to that of the separated protein fractions. The number of capillaries used in the second separation step according to capillary electrophoresis advantageously corresponds to the number of sample fractions introduced into the microtiter plate.

The method proposed according to the invention, which is carried out in two separation steps using free-flow electrophoresis and capillary electrophoresis, will be described in more detail below, naming the components used.

In the free-flow electrophoresis developed by Hannig (Hannig in Electrophoresis 1982, 3, 235 - 243), a continuous flow flows into an electrical field

Buffer film. On one side of the free-flow electrophoresis chamber is on a defined

Place the protein sample fed.

In the first separation step, two different free-flow electrophoresis methods can be used for the method proposed according to the invention: isoelectric focusing and isotachophoresis.

For isoelectric focusing, with the help of carrier ampholytes (Gerhard Weber and Petr Bocek in Electrophoresis 1998, 19, 1649 - 1653), which are applied together with the buffer, a pH gradient between the two electrodes perpendicular to the Flow direction of the buffer film is generated, which separates the proteins due to their charge in the free flow (FFE-IEF). At the other end of the free-flow electrophoresis chamber, the individual fractions are collected through a series of tubes, for example in the individual wells of a microtiter plate.

As an alternative to FFE-IEF, isotachophoresis can be used in the first separation step. A potential gradient is formed in the electrical field in a discontinuous buffer system consisting of the lead and secondary electrolytes. The field strength is higher in the area of ions with low mobility than in the area of more mobile ions. Since all ions must migrate at the same speed, pure zones of the individual proteins are formed from the protein sample mixture. In the equilibrium state, the ion with the highest mobility follows the lead ion of the lead electrolyte, the one with the lowest mobility moves in front of the follow-up electrolyte, the others move in between in the order of decreasing mobility. In practice, interval isotachophoresis is performed (Gerhard Weber and Petr Bocek in Electrophoresis 1998, 19, 3090 - 3093). After the protein sample and the electrolytes have been applied to the free-flow electrophoresis chamber, high voltage is applied for 2 minutes to separate the proteins, then the separated fractions are conveyed without tension via a series of tubes into the individual wells of a microtiter plate.

For the first step proposed according to the invention for the separation of the proteins - both for FFE-IEF and for free-flow isotachophoresis - the electrophoresis device "OCTOPUS" from Dr. Weber GmbH used.

After isoelectric focusing (FFE-IEF) or isotachophoresis, individual protein fractions (preferably 96) are obtained in microtiter plates in this electrophoresis device. The proteins in these fractions can be linked both to a marker, for example a fluorescent dye such as Sypro®Orange, Sypro®Red or Sypro®Ruby, and to at least one reactive fluorescent dye. Derivatives such as the N-hydroxysuccinimide esters (NHS esters) or the isothiocyanates of fluorescent dyes, which are coupled to free amino groups of the proteins, are suitable for this. N-termini or lysine of the proteins or the protein fractions are particularly suitable. In addition, it is also readily possible to link corresponding derivatized fluorescent dyes to the carboxylate, thiol and hydroxyl groups of the proteins. The advantage that can be achieved with the use of covalently bound fluorescent dyes is above all in that notice that in each capillary several samples marked with different dyes can be detected simultaneously in the subsequent separation step.

In the second separation step, e.g. Separate covalently fluorescence-labeled proteins using capillary electrophoresis. The one or more capillary tubes used can be filled on the one hand with a polyacryamide gel, on the other hand the use of unloaded, i.e. empty capillary tube possible.

Detection preferably follows with laser-induced fluorescence, and sodium dodecyl sulfate can be added to the separation buffer to improve the running behavior of the proteins in capillary electrophoresis. Ideally, all wells of the microtiter plate are separately detected and quantified in parallel in as many capillaries. In a preferred and simple manner, a commercially available device for DNA sequencing is used, for example a Mega-BACE from Amersham Pharmacia or another device of a similar design. An advantage over conventional 2D gel electrophoresis with subsequent non-covalent staining with image evaluation for quantification is that the electropherograms obtained by the method described here can be easily quantified using commercially available software.

In one embodiment of the method proposed according to the invention, several different marking substances, such as, for example, fluorescent dyes, can be detected simultaneously in each capillary that can be used in the course of the second separation step as part of the capillary electrophoresis. In a modification of this method, only a fluorescent dye or fluorescent substance can be detected just as well. This means that several protein samples that have been labeled with different fluorescent dyes can be mixed and separated simultaneously in a single capillary. This fact leads to parallelization in the second process step, i.e. parallel processing of several samples simultaneously. Preferably, the multiple samples analyzed in one run are proteins from different cells or from cells in different stages of development or from cells that were exposed to different external conditions (such as heat, cold, active substances, chemicals, etc.).

The much more sensitive fluorescence detection ensures a large dynamic range and high sensitivity. Furthermore, due to the high separation performance within capillary electrophoresis, a much better one

Dissolution of the protein samples or the protein samples of cellular origin in the second Dimension compared to the 2D PAGE method can be achieved. Due to the significantly better automatability of both methods, free-flow electrophoresis and capillary electrophoresis, a significantly higher throughput and thus a better statistical validation of the results will take place. After carrying out the method proposed according to the invention, a program sequence for evaluating the electropherograms is to be created; furthermore, in order to implement the method proposed according to the invention, a free-flow electrophoresis apparatus (“Octopus” from Dr. Weber GmbH), for example, and, for example, a Mega-BACE sequencer from Amersham or a similar device are required.

Claims

claims

1. Process for the separation and detection of proteins or protein samples of cellular origin, the proteins being contained in a separation buffer solution and the following process steps being carried out:

- The protein samples are processed in a first separation step according to the free

Flow electrophoresis or isoelectric focusing (IEF) or isotachophoresis broken down into individual fractions and linked with a marker,

- In a second separation step, the protein fractions according to the

Capillary electrophoresis occurred in one or more capillaries, at least one marker substance associated with the protein fractions being detected in the one or more capillaries.

2. The method according to claim 1, characterized in that after the first separation step, all proteins in the protein fractions obtained are linked with a reactive fluorescent dye.

3. The method according to claim 2, characterized in that N-hydroxysuccinimide esters (NHS esters) or isothiocyanates of fluorescent dyes are coupled to free amino groups of the proteins.

4. The method according to claim 3, characterized in that the coupling sites are free amino groups such as N-termini or lysines of the proteins.

5. The method according to claim 2, characterized in that iodoacetamido maleimide, [acetylmercaptosuccinoyljamino (= SAMSA), pyridyldithiopropionamide (= PDP) or bromomethyl derivatives of fluorescent dyes are coupled to free sulfhydril groups of the proteins.

6. The method according to claim 2, characterized in that the reactive fluorescent dyes are coupled to carboxylate, thiol or hydroxyl groups of the proteins.

7. The method according to claim 5, characterized in that the coupling site are free sulfhydrile groups of the cysteines.

8. The method according to claim 1, characterized in that after the first separation step of all proteins in the protein fractions obtained are mixed with a fluorescent marker.

9. The method according to claim 8, characterized in that the marking substances are adsorptively bound to the proteins by van der Waals', ionic or hydrophobic interactions.

10. The method according to claim 1, characterized in that in the second separation step the capillaries used contain a polyacrylamide gel.

11. The method according to claim 1, characterized in that in the second separation step the capillaries used contain agarose.

12. The method according to claim 1, characterized in that in the second separation step, the capillaries used contain no gel.

13. The method according to claim 1, characterized in that in the second separation step, the capillaries used contain a synthetic polymer matrix.

14. The method according to claim 1, characterized in that the detection in the second separation step is carried out with laser-induced fluorescence.

15. The method according to claim 1, characterized in that during the capillary electrophoresis sodium dodecyl sulfate is added to the separation buffer containing the proteins.

16. The method according to claim 1, characterized in that the separation of the protein samples in the first separation step is carried out in parallel in preferably 96 different protein fractions, using a microtiter plate, the number of wells of which corresponds to that of the separated protein fractions.

7. The method according to claim 16, characterized in that the number of capillaries in the second separation step corresponds to the number or part of the number of protein fractions applied to the microtiter plate.