KR101191793B1 - Method for measuring protein's concentration in whole cell lysates - Google Patents

Abstract

PURPOSE: A method for measuring protein concentration in whole cell lysate is provided to be applied to all kinds of proteins and to enable protein concentration measurement with high reliability. CONSTITUTION: A method for measuring protein concentration in whole cell lysate comprises: a step (a) of generating a conjugate molecule containing marker-containing standard proteins and biomolecules which are conjugated to subject proteins; a step (b) of mixing the standard proteins with a cell solution containing the subject protein; a step (c) of mixing the cell solution of step (b) and biomolecules conjugated to the subject proteins of step (b) to generate a conjugate molecule containing the biomolecules and a conjugate molecule; and a step (d) of calculating the concentration of the measured subject proteins in the cell solution based on the number of the conjugate molecule generated at step (a) and the number of the conjugate molecule generated at step (c).

Description

Method for Measuring Protein's Concentration in whole cell lysates

The present invention relates to a method for measuring protein concentration in a cytoplasmic stock solution, and more particularly, it can be applied to all kinds of proteins, and is calculated based on data measured at a single molecule level, thereby measuring a high reliability protein concentration. The present invention relates to a method for measuring protein concentration in a cytoplasmic stock solution.

Measuring the concentration of a specific protein desired by an analyst in a human cell is a very useful method for detecting or predicting the conversion to cancer cells according to genetic variation in the cell.

However, prior art methods for measuring concentrations of proteins are merely inexplicable methods that can be applied only to individual proteins, or even in the specific methods of measuring concentrations based on data measured at the single molecule level for a particular protein. There was a problem that the accuracy of the measured concentration could not be trusted because it was not.

Therefore, the object of the present invention is not only applicable to all kinds of proteins, but also calculated on the basis of the data measured at the single molecule level, so that the method of measuring protein concentration in a cell solution which makes it possible to measure high reliability protein concentration. In providing.

Protein concentration measurement method in a cell solution according to the present invention for achieving the above object, (a) a binding molecular sieve is combined with a reference protein having a marker in the protein to be measured and a biomolecular sieve coupled to the protein to be measured Inducing the production of; (b) mixing a reference protein having a marker and a cell solution containing the measurement target protein to the measurement target protein; (c) mixing the mixed cell solution and the biomolecular sieve bound to the protein to be measured to induce the generation of the binding molecular sieve combined with the biomolecular sieve and the reference protein; And (d) based on the number of binding molecular sieves generated in step (a) and the number of binding molecular sieves generated in step (c) of the protein to be measured in the cell solution containing the protein to be measured. Calculating the concentration.

Preferably, the marker is characterized in that the fluorescent protein.

In addition, in the step (d), the number of the binding molecular sieve is characterized by measuring the fluorescent signal of a specific wavelength generated by the fluorescent protein using an optical device for generating a near field.

According to the present invention, there is provided a method for measuring protein concentration in a cell solution that can be applied to all kinds of proteins as well as calculated based on data measured at the single molecule level, thereby making it possible to measure protein concentrations of high reliability. .

1 is a flowchart illustrating a method of measuring protein concentration in a cell solution according to an embodiment of the present invention, and
2 is a view for explaining the principle of the protein concentration measurement method in a cell solution according to an embodiment of the present invention.

Hereinafter, with reference to the drawings will be described the present invention in more detail. It is to be noted that the same elements among the drawings are denoted by the same reference numerals whenever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 is a flowchart illustrating a method for measuring protein concentration in a cell solution according to an embodiment of the present invention. Referring to Figure 1, when explaining a method for measuring protein concentration in a cell solution according to an embodiment of the present invention, first, the analyzer undergoes a genetic engineering process in the cell state, the fluorescent protein is present in the protein to be measured in the cell To be expressed (S110).

Meanwhile, in carrying out the present invention, the fluorescent protein may be attached or linked to the protein to be measured by a physicochemical method. In the present invention, the protein to be measured in which the fluorescent protein is expressed in step S110 is referred to as a reference protein.

In the practice of the present invention, it will be desirable to express the m-Cherry protein in the fluorescent protein in the protein to be measured.

Next, the analyst injects a reference protein having a concentration higher than that of the antibody in a test tube while injecting an antibody that binds the protein to be measured into the test tube (S120).

In the practice of the present invention, the concentration of the antibody and the concentration of the reference protein may be preferably in a ratio of 1: 5 to 1:10. Further, in addition to the antibody, DNA, RNA, and measurement may be used for the antibody binding to the protein to be measured. Biomolecular sieves that bind to proteins such as liposomes with specific components that bind to the protein of interest may be used.

After reacting the antibody and the reference protein in vitro for 20 to 30 minutes, the antibody was supplied to the substrate which is a quartz slide coated with polyethyleneglycol (PEG) coated with the mixed solution in the tube. Attached to the substrate as in (S130).

The analyst then performs surface observation of the substrate using a total reflection microscope, an optical device that generates near-fields, so that the analyst can measure the wavelengths caused by the fluorescent protein (i.e. by measuring the individual monomolecular signals generated from the fluorescent protein). Among the antibodies attached on the substrate, the number of binding antibodies (binding molecular sieves) bound to the reference protein expressing the fluorescent protein is measured (S140).

The analyst records the number of binding antibodies measured in step S140 described above as a reference binding number.

Meanwhile, the analyst repeats the above-described step S110 to manufacture the reference protein again, and mixes the mixed cell solution of the prepared protein and the cell solution of the specific cell containing the target protein to be measured by the analyzer. To prepare a solution (S150).

Herein, the cell solution of a specific cell may be a cytoplasmic solution of a specific cell, a cell stock solution, a diluted cytoplasmic stock solution, or a diluted cell stock solution, and the specific cells used to prepare the mixed cell solution may be used in cancer cell tissues of cancer patients. It could be the extracted cells.

On the other hand, the reference protein introduced in the preparation of the cell solution mixed in step S150 described above should be added at the same concentration as the reference protein introduced into the test tube in step S120 described above.

Next, the analyst puts the mixed cell solution prepared in step S150 into the test tube and mixes the antibody with the same antibody as the antibody in step S120 described above, the antibody binding to the protein to be measured, in the same concentration. (S160).

The reaction process of the antibody and the reference protein in vitro is performed at the same time as before, for 20-30 minutes to induce binding of the antibody and the reference protein or binding of the antibody and the protein to be measured included in the specific cell (S170). ).

In this case, the reference protein in which the fluorescent protein is expressed and the protein to be measured in which the fluorescent protein is not expressed are competitively bound to the antibody of a constant concentration. Therefore, the higher the concentration in the specific cell of the protein to be measured is measured. Interfering with the binding of the reference protein and the antibody of the target protein is increased, the number of antibodies that bind to the reference protein will be reduced.

After reacting in vitro, the analyst supplied the mixed solution in the test tube to the substrate, thereby attaching the antibody to the substrate as in step S130 described above (S180).

The analyst then performs a surface observation of the substrate using a total reflection microscope to determine the number of binding antibodies bound to the reference protein expressing the fluorescent protein among the antibodies attached to the substrate from the wavelength change by the fluorescent protein ( S190).

The analyst records the number of binding antibodies measured in step S190 described above as the number of measurement binding.

That is, the reference protein expressed in the step S140, which is the number of binding of the reference protein expressing the fluorescent protein with no antibody, is measured through the concentration (X ') of the reference protein in step S120 described above. Based on the number of measurement bindings (r), which is the number of binding of an antibody with a reference protein present in a particular cell in competition with the protein of interest, the analyst can calculate the concentration (X) in the specific cell of the protein to be measured. It becomes (S195).

Specifically, in general, since the antibody is provided with two light chains, even if a reference protein is bound to only one of the two light chains, the antibody may be analyzed using a total reflection microscope of the analyzer at step S190. It is calculated as the measurement coupling number r at the time of performing the surface observation of the substrate.

That is, the antibody is measured only when both of the two light chains included in the antibody are bound to the protein to be measured in a specific cell, respectively, in step S190, when the analyst performs surface observation of the substrate using a total reflection microscope. It is not counted as the coupling number r.

Here, the probability value P at which the protein to be measured to be present in each specific cell is bound to both light chains provided in the antibody is expressed as Equation 1 below.

In Equation 1, X 'is the concentration of the reference protein in step S120, X is the concentration in a specific cell of the protein to be measured. X 'can be measured by various methods of measuring the concentration of a protein.

Meanwhile, "r / R", which is the ratio of the reference coupling number R and the measurement coupling number r, may be expressed by Equation 2 below.

When Equation 1 and Equation 2 are combined, Equation 3 below is calculated.

In Equation 3, R is the reference bond number described above, r is the measurement bond number, X 'is the concentration of the reference protein in step S120, X is the concentration in the specific cell of the protein to be measured. R and r are measured by the analyst in steps S140 and S190 described above, respectively.

That is, the concentration (X) in the specific cell of the protein to be measured is calculated by substituting the X 'value, the R value, and the r value in the above formula (1).

Meanwhile, in the practice of the present invention, two light chains may be separated using an enzyme so that the antibody has only one light chain, and in this case, the antibody to be measured in the specific cell is bound to the antibody. The probability value P will be expressed as Equation 4 below.

Since "r / R", which is the ratio of the reference coupling number R and the measurement coupling number r, may be expressed as in Equation 2, Equation 5 and Equation 2 below are calculated. do.

That is, when the light chains are separated from each other and the concentration (X) in a specific cell of the protein to be measured is calculated using an antibody having a single light chain, X ', R, and By substituting the r value, the concentration (X) in the specific cell of the protein to be measured is calculated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

Claims (3)

(a) inducing the generation of a binding molecular sieve in which a reference protein having a marker in a protein to be measured and a biomolecular sieve bound to the protein to be measured are bound;
(b) mixing a reference protein having a marker and a cell solution containing the measurement target protein to the measurement target protein;
(c) mixing the cell solution mixed in the step (b) and the biomolecular sieve combined with the protein to be measured in the step (b) to generate the binding molecular sieve in which the biomolecular sieve and the reference protein are bound. Deriving; And
(d) the concentration of the target protein in the cell solution containing the target protein based on the number of binding molecular sieves generated in step (a) and the number of binding molecular sieves generated in step (c) Step to calculate
Including;
The marker is a fluorescent protein,
In the step (d)
The number of the binding molecular sieve is measuring the protein concentration in the cell solution is to measure the fluorescent signal of a specific wavelength generated by the fluorescent protein using an optical device for generating a near field.

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