This invention relates to a protocol for pre-staining a protein prior to electrophoresis, an electrophoresis method including the protocol, and a kit for carrying out the protocol.
Pyrylium dyes are heterocyclic aromatic compounds with a covalently bonded chromophore, which react with primary amines under mild conditions in buffered solutions and organic solvents, to form stable pyridinium analogues. On conjugation to a primary amine the chromophore undergoes a shift in absorbance maximum, a decrease in molar extinction coefficient and an increase in emission intensity to give a greater quantum yield in comparison to the unconjugated dye.
Pyrylium dyes have the following general structure:
Two dyes in particular are currently commercially available and are sold in kit form with other reagents, consisting of either CE Dye 503 or CE Dye 540 and a relevant buffer (Active Motif Inc.). In the literature which supports these reagents [Craig et al., Electrophoresis 26, 2208-2213], CE Dye 503 is referred to as Py-1 and CE Dye 540 as Py-6.
The structures of some dyes are as follows:
Pyrylium dyes interact with amines on proteins (or amino-modified DNA) to form compound analogues. The dyes specifically interact with lysine residues; an abundant, surface localised amino acid present in almost equal percentages in proteins.
A large group of pyrylium dyes have been investigated. Of these, it has been found that there are a number that do not bind effectively to proteins because they are sterically hindered at the reactive site (the oxygen on the pyrylium ring). The sterically hindered dyes do not readily bind covalently to the protein and therefore have only a week interaction giving an unstable protein-dye conjugate.
A discussion of the use of pyrylium dyes for the determination of picomolar concentrations of proteins by capillary electrophoresis laser-induced fluorescence detection methods can be found in the Craig et al reference supra. This reference discloses protocols for the pre-staining of protein samples with Py-1 or Py-6 before capillary electrophoresis. In reference Wetzl et al., [Angew. Chem. Int. Ed. 2004. 43, 5400-5402], it is disclosed that Py-1, Py-3 and Py-5 can be used as protein labels post gel electrophoresis. It is known from the prior art that varying the basic conditions of incubation such as dye concentration, temperature, time and buffer can influence the effectiveness of the labelling process, and that for a given dye there is a basic set of conditions that work best.
Staining proteins is usually carried out following gel electrophoresis and can be a time consuming procedure. The advantage of these compounds in comparison to other protein stains is that they are small, impart virtually no change in protein size or charge following binding and therefore have a minimal effect on the electrophoretic movement of the protein molecule. It would be advantageous therefore to be able to use them as a pre-stain protocol prior to gel electrophoresis. However, it has been found that the pre-staining techniques described in the prior art do not provide acceptable results, either for prestaining samples to be run on slab gels, or for prestaining samples to be run on small scale automated gel systems. It is an object of the invention to seek to mitigate problems such as this.
According to the invention there is provided a protocol for pre-staining a protein sample prior to electrophoresis, comprising the steps of incubating the protein sample with a pyrylium dye in the presence of a buffer, a detergent and a denaturing agent. It has been found that incubating using this combination of constituents enhances the ability of pyrylium dyes to stain both low and high molecular weight proteins with improved linearity and high intensity.
It is preferred that the pyrylium dye is a non-sterically hindered dye. It is preferred that pyrylium dye when unconjugated has a low quantum yield, and when conjugated, a high quantum yield. It is preferred that the detergent comprises SDS. The denaturing agent may comprise one or more of DTT, tributyl-phosphine (TBP), tris(2-carboxyethyl)phosphine (TCEP).
It is preferred that incubation is carried out at a pH from 9 to 10. Below pH 9 labelling is less efficient, whilst at pH 10.5 sample staining is reduced and protein bands are broader such that resolution is compromised. It is particularly preferred that incubation be carried out at about pH 9.3.
It is further preferred that incubation is carried out at a temperature of from 70 to 95° C. and for from 5 to 60 minutes, preferably at 75° C. for 7 minutes.
It is preferred that the buffer includes a sulphonate group. It has been found that such buffers also contribute to an improvement in staining both low and high molecular weight proteins with respect to linearity and intensity of stain. The buffer may comprise one or more from CAPSO, CHES, TAPS, TES and HEPES.
According to a second aspect of the invention there is provided a gel-electrophoresis method, the method comprising the steps of pre-staining a protein sample using a protocol as set out hereinabove, and electrophoresing the sample on a gel.
It is preferred that the gel is a cross-linked polyacrylamide gel.
According to a third aspect of the invention there is provided a kit for performing a protein pre-stain protocol, the kit comprising a pyrylium dye, a buffer, a detergent and a denaturing agent.
The detergent may comprise SDS. The denaturing agent may comprise one or more of DTT, tributyl-phosphine (TBP), and tris(2-carboxyethyl)phosphine (TCEP).
The buffer is preferably a buffer that includes a sulphonate group. The buffer may comprise one or more from CAPSO, CHES, TAPS, TES and HEPES.
The kit may further comprise an electrophoresis vessel, the vessel including a prepackaged electrophoresis gel. The electrophoresis vessel may preferably be an integrally formed plastics strip or continuous tape, having one or a plurality of electrophoresis volumes formed therein, each volume including a prepackaged electrophoresis gel.
The invention will further be described and illustrated by way of the following experiments and Figures.
A series of experiments was performed to assess the efficiency of known staining protocols utilising pyrylium dyes as pre-stains for protein samples for gel-electrophoresis. The only available pre-stain protocol was that described for use before capillary electrophoresis. A pre-stain protocol was used in Höfelschweiger (PhD dissertation, University of Regensburg). In this work, Py-6, Py-1, Py-4, and Py-2 were dissolved in 100 μl DMF (to give concentrations of around 5 mM). An aliquot of 1 μl dye was added to a protein ladder in 10 μl, in bicarbonate buffer pH9. Dye was present at either 500 μM or 50 μM final concentration. Staining was performed for 30 minutes, although no temperature was given. This is the only published protocol for staining a sample prior to slab gel electrophoresis. A post gel electrophoresis staining protocol is available (Wetzl et al., (2004) Angew. Chem. Int. Ed. 43, 5400-5402).
Gels were made using acrylamide and bis-acrylamide.
A protein ladder was made using six recombinant proteins (electrophoresis grade), obtained from Sigma Aldrich, Poole, UK). Ladders were prepared with each protein present in equal amounts (2 mg/ml). Py-1, Py-2, Py-4, Py-6, and Py-8 were obtained from Active Motif Chromeon, Germany. Py-1, and Py-6 were reconstituted in DMF to give a 2.5 mM stock. Py-4 was reconstituted in DMSO to give a 26 mM stock, and Py-8 a 4 mM stock. The stock concentration of Py-2 was unknown.
The available pre-stain prior art protocol was the Active Motif Chromeon protocol for labelling proteins (see www.activemotif.com). This is referred to as the “manufacturers protocol” herein below. In a 48 μl reaction volume, between 1-20 μl sample was added and made up to 46 μl with either buffer AM1 or AM2. Craig et al. suggest that Buffer AM1 comprises 10 mM sodium hydrogen carbonate and buffer AM2 comprises 2.5 mM sodium tetraborate. 2 μl of dye stock were added, the contents were mixed thoroughly and incubated at room temperature for 30 minutes with AM1 buffer with Py-1, and 50° C. for 60 minutes with AM2 buffer and Py-6. This was directly scaled down to a 10 μl volume, containing 4 μl protein sample ladder, 0.25 μl pyrylium dye from stock, and 4.1 μl AM1 or AM2. The volume of ladder, dye and AM1 or AM2 buffer was always constant, and volumes made up with water when additives were used.
A modified protocol was devised as follows: 4 μl protein ladder mixture, 50 mM CHES buffer (final concentration), in the presence or absence of additives with 0.25 μl of Py-6 which had been pre diluted 1:7.5 in DMF. This gives a final concentration of Py-6 and Py-1 in a protein pre stain reaction of 8.25 μM, as opposed to the manufacturer's protocol using 62.5 μM. Reaction volumes were made to 10 μl with water, and staining was carried out using a PCR machine (TECHNE TC-512) at the required temperature. Py-8 was used at a final concentration of 100 μM.
Following staining, samples were denatured in loading buffer containing 20% glycerol, 0.78M sucrose, 50 mM Tris base pH8, 350 mM mercaptoethanol, and 2% SDS for 5 minutes at 95° C. A volume of 0.4 μl of sample was loaded onto a ScreenTape gel electrophoresis device. Samples were subjected to electrophoresis for 5 minutes, and images captured using the Lab901 Tape Station. Details of these of the ScreenTape® gel electrophoresis device are contained in WO03045557, WO03046542, and details of the Lab901 Tape Station can be found in WO2006085071.
For slab gel analysis of pre stained samples, a full 10 μl reaction volume as described above was denatured with loading buffer and the entire 20 μl volume (with 1.7 μg of protein in each band) was loaded onto a NuPage 4-12% Bis-Tris HCl gel (Invitrogen). Samples were subjected to electrophoresis in the Invitrogen MES-SDS running buffer at 200V for 35 minutes, and gels were imaged using UV. To demonstrate the composition of the ladder sample and to compare with the pre staining protocol, identical gels were used to analyse the sample ladder by post staining the gels with colloidal coomassie. Following electrophoresis under the same conditions as described, gels were fixed in 40% methanol and 10% acetic acid, and post stained with colloidal coomasie blue R-250 (BioRad).
The experiments that make up this example were conducted in order to demonstrate the effects of detergent and denaturing additives.
A pre-stain reaction was performed as set out above according to the manufacturer's protocol using Py-6. Samples were incubated for 60 minutes at 50° C. in the presence of buffer AM2, in accordance with the manufacturer's instructions.
Experiment 1 was repeated, however this time, additives in the form of a denaturing agent and a detergent were included in the incubation mix.
As an extension of this experiment, the temperature of incubation was increased to 95° C. and the time was decreased to 5 minutes. The result is shown in part B, where samples incubated at 95° C. for 5 minutes also show best labelling when both SDS and DTT are present.
This experiment was designed to test the effect of detergent and denaturing additives when used with Py-1. The results are shown in
In part B, the effect of increasing the temperature and reducing the incubation time was tested. AM1 buffer at 95° C. has best results in the presence of both SDS and DTT. Part C shows the electropherogram comparison between room temperature and 95° C. samples in the presence of both SDS and DTT. The increased temperature is shown to be beneficial.
In this experiment, the effects of denaturing and detergent additives on dye Py-4 were tested. The results are shown in
A series of experiments was performed to test the effect of varying the buffer.
The experiments that make up this example were conducted to illustrate the effects of the modified protocol compared to the manufacturer's protocol.
The experiments that make up this example were conducted to demonstrate the applicability of the protocol of the invention to conventional slab gel electrophoresis methods.
This series of experiments was conducted to demonstrate the effects of varying pH and buffer.
The experiments that make up this example demonstrate the effects of varying temperature.
A fluorimetry time course experiment was carried out to further demonstrate the optimum staining temperature and time for protein samples. Experiments were carried out using a fluorimeter (BMG Labtech Fluostar Omega). Samples of prestain solution containing a final concentration of 0.25 mg/ml BSA were added to the plate. Duplicate 65° C., 75° C., 85° C., and 95° C. 4, 6, 8, 10 and 12 minute time course incubations were carried out and analysed alongside a set of negative controls (0 minute incubations) in triplicate from an average reading taken from 30 exposure cycles.
Data presented in
At 65° C. the reaction does not reach completion within 12 minutes; however the data is consistent with that produced during initial feasibility testing and thus lend some credence to the results produced at other temperatures.
At 75° C. a higher more stable signal is produced than at 65° C., with % CV values from the 4-12 minute region within 4%.
At 85° C. the quantum yield obtained is higher than that at either 65° C. or 75° C., however the % CV of the readings in the 4-12 minute window is almost always >4%.
While at 95° C., the overall response is reduced to a level below that seen at 75° C., the reproducibility of that is comparable to that seen at 75° C.
Overall, the data indicate that in balancing response against reproducibility 75° C. gives the largest incubation window which maintains a reproducible signal.
A 7 minute incubation at 75° C. for 7 minutes is preferred, as this lies within a window of robustness as regards temperature and timing of incubations.
Number | Date | Country | Kind |
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0718012.8 | Sep 2007 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2008/003092 | 9/12/2008 | WO | 00 | 3/23/2010 |