KR100828936B1 - - Method for Analysis of Biological Molecule Using Single-Stranded Nucleic Acid Aptamer and Gold Nano-Particle - Google Patents

Abstract

The present invention relates to an analysis method for identifying and quantifying specific biomolecules using single-stranded nucleic acid aptamers that specifically bind to various biomolecules and gold-nanoparticles and salts that form complexes with the single-stranded nucleic acids. . Biomolecule analysis method according to the present invention, by adding a target biomolecule and known single-stranded nucleic acid aptamer excluding the nucleic acid to be analyzed in an aqueous solution to target by specific binding between the target biomolecule and the single-stranded nucleic acid Forming a biomolecule / single-nucleic acid complex; Adding gold-nanoparticles to the aqueous solution to form a single-stranded nucleic acid / gold-nanoparticle complex by reacting the remaining single-stranded nucleic acid with the gold-nanoparticle without forming a complex with the target biomolecule; And analyzing a color change of the aqueous solution based on a dispersion state of the gold-nanoparticles that forms a complex with the single-stranded nucleic acid by adding a salt to the aqueous solution. It comprises: thereby identifying the target biomolecule from the specific binding of the target biomolecule and the single-stranded nucleic acid, and characterized in that for quantifying the target biomolecule from the color change of the reaction solution.

Description

Method for Analysis of Biological Molecule Using Single-Stranded Nucleic Acid Aptamer and Gold Nano-Particle}

1 is a view showing the color change caused by the treatment of 100ng single-stranded nucleic acid aptamer to various numbers of E. coli and the addition of gold-nanoparticles and salts,

Figure 2 shows the color change caused by the treatment of 250ng single-stranded nucleic acid aptamer to various numbers of E. coli and the addition of gold-nanoparticles and salts,

Figure 3 is a graph of the results of scanning spectrometer color change of the solution caused by treatment of 250ng single-stranded nucleic acid aptamer to various amounts of VEGF protein and addition of gold nanoparticles and salts,

4 is a graph showing the discoloration pattern of the solution according to the amount of protein derived from FIG.

(Technology)

The present invention relates to a method for analyzing biomolecules, and more specifically, using a single-stranded nucleic acid aptamer specifically binding to various biomolecules and gold-nanoparticles and salts that form a complex with the single-stranded nucleic acid, It relates to an analysis method for identifying and quantifying specific biomolecules.

(Background)

The method of identifying specific substances and analyzing their quantitative changes is steadily developing with the development of physics and biochemistry, and the demand for the development of more efficient methods in terms of maintenance cost, ease, accuracy, sensitivity, inspection time and automation It is going on.

The method of analyzing a specific substance is not an ultimate goal in itself but a part of the whole process, but it is very useful for microbial and virus identification, cell, protein and organic substance analysis, and is widely used in medicine, veterinary medicine, environmental engineering, food engineering and agriculture. It is applied.

Nucleic acids are linear multimers in which nucleotides are covalently linked. Nucleotides are small organic compounds consisting of phosphoric acid, sugars and purines (adenine or guanine) or pyrimidine (cytosine, thymidine, uracil).

Nucleic acids exist in single- or double-stranded strands, which bind together by hydrogen bonds and interactions between nucleotides under specific physical conditions to form unique conformations, which are determined by the single-stranded nucleotide sequence. .

Generally, nucleic acids such as DNA and RNA are a storage of information for expressing proteins with cell structure and enzyme activity, but since 1982 reports that RNA has a specific structure as well as enzymes, the nucleic acid has been reported as having an enzyme. There are many reports of structural features and their specific function. Nucleic acid is composed of four base repeats to maintain a high diversity to form a large number of three-dimensional structure, these three-dimensional structure is stabilized by interacting with a specific material to form a complex.

Nucleic acid can act as a ligand to a specific substance including a protein, and has a high binding capacity and specificity through a constant screening process and sequencing from a library of single stranded nucleic acids arranged in various nucleotide sequences. Nucleic acids that bind to specific substances are being screened.

The method of screening nucleic acids for binding to a specific substance is called SELEX (Systematic Evolution of Ligand by Exponential enrichment), and the selected nucleic acid is generally called aptamer (Craig et al., 1990, Science, 249, 505-510). Through SELEX, not only proteins that can bind nucleic acids in nature, but also molecules that can bind with various biomolecules, including proteins that do not bind nucleic acids, with very high affinity are selected.

The identification and analysis of specific substances are frequently performed using physical and chemical properties, and the analysis using specificity and affinity between materials is usually performed by methods developed based on immunological methods.

Gold-nanoparticles have different maximum absorption wavelengths in the absorption spectrum, depending on the size of the particles when dispersed in solution. For example, gold-nanoparticles with a diameter of about 13 nm have a maximum absorption wavelength of about 530 nm when they are well dispersed in an aqueous solution, and the solution turns red. However, when the particles gather and become an aggregate (or aggregation), the maximum is reached. The absorption wavelength is shifted to the long wavelength so that the color of the solution becomes purple.

Using this principle, a group of gold-nanoparticles can be induced by attaching single-stranded DNA, which knows the sequence of nucleotide sequences, to the double-stranded nucleic acid by reacting with DNA having a complementary sequence. The color of the solution was reported to be red in the absence of target DNA but purple in the presence of target DNA (J. Am. Chem. Soc., 125, 1643 (2003)).

In addition, when single-stranded nucleic acid and double-stranded nucleic acid are adsorbed to gold-nanoparticles to form a complex, the former single-stranded nucleic acid in a particular salt is dispersed by its electrostatic repulsive force to maintain red color, but the latter double-stranded nucleic acid Silver forms an aggregate and becomes purple.

Colorimetric methods have been developed to analyze hybridization of oligonucleotides using the properties of such nucleic acids, gold-nanoparticles and salts (PNAS., 101, 14036 (2004)). This method does not require the modification of gold-nanoparticles, single-stranded nucleic acids or complementary strands, and the hybridization reaction and the sensing are separated from each other, resulting in a slowing of the hybridization reaction resulting from the steric limitation of fixing the probe to the surface. There is an advantage to overcome the problem.

An object of the present invention is to identify and quantify specific biomolecules using specific binding of single-stranded nucleic acid aptamers and biomolecules and discoloration by salts of complexes of single-stranded nucleic acids and gold-nanoparticles. To provide a way.

According to the present invention, a biomolecule analysis method is provided.

Biomolecule analysis method according to the present invention, by adding a target biomolecule and known single-stranded nucleic acid aptamer excluding the nucleic acid to be analyzed in an aqueous solution to target by specific binding between the target biomolecule and the single-stranded nucleic acid Forming a biomolecule / single-nucleic acid complex; Adding a gold-nanoparticle to the aqueous solution to form a single-stranded nucleic acid / gold-nanoparticle complex by reacting the remaining single-stranded nucleic acid with the gold-nanoparticle without forming a complex with the target biomolecule; And analyzing a color change of the aqueous solution based on a dispersion state of the gold-nanoparticles that forms a complex with the single-stranded nucleic acid by adding a salt to the aqueous solution. It includes, thereby identifying the target biomolecule from the specific binding of the target biomolecule and the single-stranded nucleic acid and quantify the target biomolecule from the color change of the reaction solution.

Preferably, the target biomolecule / single-nucleic acid complex is removed before forming the single-stranded nucleic acid / gold-nanoparticle complex.

The target biomolecule / single-nucleic acid complex formation step may be performed by the specific binding between the target biomolecule and the known single-stranded nucleic acid aptamer specifically binding to the target biomolecule except for the nucleic acid to be analyzed. By forming a complex, the target biomolecule / single-nucleic acid complex, which is the basis for identifying the target biomolecule and the basis for quantifying the target biomolecule, is formed. .

The single-stranded nucleic acid aptamer is present in an equilibrium state with a stable structure that is thermodynamically stable and maintains a constant secondary structure and an unstable structure that are not. In this equilibrium, the ratio of the two structures is determined by the components and temperature of the reaction solution.

When the target biomolecule is added to the aqueous solution of the single-stranded nucleic acid aptamer in the equilibrium state, the target biomolecule reacts with the stable structure of the single-stranded nucleic acid to form the target biomolecule / single-nucleic acid complex. Therefore, the single-stranded nucleic acid remaining without forming a complex with the target biomolecule has relatively many unstable structures that do not form a complex with the target biomolecule. That is, depending on the amount of the target biomolecule, the relative ratio of the stable structure and the unstable structure in the single-stranded nucleic acid remaining without forming a complex is changed.

The single-stranded nucleic acid / gold-nanoparticle complex forming step, the gold-nanoparticles are added to the aqueous solution that passed through the step of forming the target biomolecule / single-stranded nucleic acid complex by the formation of the complex remaining with the target biomolecule Single-stranded nucleic acid is adsorbed to the gold-nano particles to form a complex.

In the color change analysis step, the aqueous solution based on the dispersion state of the gold-nanoparticles forming a complex with the single-stranded nucleic acid by adding a salt to the aqueous solution is completed the formation of the single-stranded nucleic acid / gold-nanoparticle complex The step of determining the amount of the target biomolecule based on the color change of the.

If the amount of the target biomolecule is relatively high, a larger amount of the stable structure of the single-stranded nucleic acid will form a complex with the target biomolecule, so that it remains in solution without forming the target biomolecule / single-nucleic acid complex. In the single-stranded nucleic acid, the proportion of the unstable structure will be relatively high, and in the single-stranded nucleic acid / gold-nanoparticle complex formed by adding the gold-nanoparticle, the unstable structural single-stranded nucleic acid that causes electrostatic repulsion is relatively high. Since it will be included a lot, the gold-nanoparticles will remain dispersed and the color of the salt-added solution becomes red.

On the contrary, when the amount of the target biomolecule is relatively small, the formation of the target biomolecule-single-nucleic acid complex is small, so that the relative ratio of the stable structure among the single-stranded nucleic acid remaining without forming the target biomolecule / single-nucleic acid complex is increased. Since the single-stranded nucleic acid / gold-nanoparticle composite formed by adding the gold-nanoparticles to the complex will contain a relatively large amount of stable structure single-stranded nucleic acid with low electrostatic repulsion, the complex will form an aggregate. The color of this added solution turns purple.

The color change caused by the addition of a salt to the solution after the single-stranded nucleic acid / gold-nanoparticle complex is formed can be measured by various known methods.

The analysis method of the present invention identifies the target biomolecule by specific binding of the target biomolecule and the single-stranded nucleic acid except for nucleic acid, and the color of the solution based on the dispersion state of the single-stranded nucleic acid / gold-nanoparticle complex. The target biomolecule is quantified from the change.

That is, in order to identify and quantify various biomolecules other than nucleic acids including microorganisms, cells and proteins, various single-stranded nucleic acid aptamers that specifically bind to the biomolecules are selected and secured in advance, and various amounts of the After biomolecule-mono-nucleic acid complex formation and single-stranded nucleic acid / gold-nanoparticle complex formation for biomolecules and various amounts of single-stranded nucleic acids, the result of color change by gold-nanoparticles is obtained. Standard data of color change corresponding to various amounts of nucleic acid and non-nucleic acid and gold-nanoparticles can be obtained, and the analysis method of the present invention is applied to such standard data and unknown biomolecules (target biomolecules). By analyzing the data of the applied result, it is possible to identify and quantify the unknown biomolecules except nucleic acids.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. The following examples are merely illustrative of the present invention and are not intended to limit the scope of the present invention.

Example 1 Selection of Single-stranded Nucleic Acid Aptamers Specific to E. Coli

E. coli was selected as an analyte (target biomolecule) of the analysis method according to the present invention, and SELEX standard method was performed to select single-stranded nucleic acids that specifically bind to E. coli (Bock LC et al .; Nature, 355 (6360), pp 564-6, 1992).

After preparing double-stranded DNA through PCR (Polymerase Chain Reaction) using a single-stranded DNA oligonucleotide having a random base sequence as described below, a single-stranded RNA library was prepared through in vitro transcription.

5'- GGG AGA GCG GAA GCG TGC TGG GCC N ₄₀ CAT AAC CCA GAG GTC GAT GGA TCC CCC C- 3 '(where the underlined base sequence is a fixed region of the nucleic acid library and N ₄₀ is A, G at each position) Means that the bases such as, T and C are present in the same concentration.)

The FW primer used for PCR (5'-GGG GGA ATT CTA ATA CGA CTC ACT ATA GGG AGA GCG GAA GCG TGC TGG G-3 ') (SEQ ID NO: 1) and the 5' end of the underlined bases of the above It is capable of base binding and contains a promoter sequence for RNA polymerase of bacteriophage T7. The RE primer of PCR (5'-GGG GGG ATC CAT CGA CCT CTG GGT TAT G-3 ') (SEQ ID NO: 2) can base bond with the 3' end of the underlined base of the above base sequence. And the FW and RE primers contain restriction enzyme cleavage sequences such as Eco RI and Bam HI, respectively, for subsequent cloning.

The nucleic acid library used in the Selex is an RNA molecular library containing 2'-F-substituted pyrimidine, and the DNA nucleic acid library transcript and PCR primers were designed and prepared as described above and prepared by PCR and in vitro transcription methods.

1,000 pmoles single-stranded nucleic acid transcript, 2,500 pmoles of the PCR primer pairs (the FW primers and the RE primers of SEQ ID NO: 1 and SEQ ID NO: 2) were 50 mM KCl, 10 mM Tris-Cl (pH 8.3), 3 mM MgCl ₂ , 0.5 mM dNTP (dATP, dCTP, dGTP, and dTTP), 0.1 U Taq DNA Polymerase (Perkin-Elmer, Foster City Calif.) Followed by QIAquick-spin PCR purification column (QIAGEN Inc., Chatsworth Calif. Purified).

RNA molecule libraries comprising 2′-F-substituted pyrimidines were prepared by synthesis and purification by in vitro transcription. 200 pmoles double stranded DNA transcript, 40 mM Tris-Cl, pH 8.0, 12 mM MgCl ₂ , 5 mM DTT, 1 mM spermidine, 0.002% Triton X-100, 4% PEG 8000, 5 U T7 RNA Polymerase and 1 After reacting mM ATP, GTP and 3 mM 2'F-CTP, 2'F-UTP at 37 ℃ for 6 to 12 hours, purified by Bio-Spin 6 chromatography column (Bio-Rad Laboratories, Hercules Calif.) The amount of purified nucleic acid and its purity were then retrieved using a UV spectrometer.

The single-stranded nucleic acid synthesized in the above was selected at a concentration of 10 ¹⁵ nucleotide sequences / 1 ml, and at a concentration of 200 pmol / 200 μl from the next time (50 mM TrisCl (pH 7.4), 5 mM KCl, 100 mM NaCl, 1 mM MgCl ₂ , 0.1% NaN ₃ ) was heated at 80 ° C. for 10 minutes, and then left on ice for 10 minutes. A reaction solution was prepared by adding 5 times yeast tRNA (yeast tRNA, Life Technologies) and 0.2% BSA (bovine serum albumin, Merck) of the used single-stranded nucleic acid. Single-stranded nucleic acid was added in a selection buffer containing 10 ⁶ Escherichia coli DH-5α (Amershambiosciences) and reacted at 37 ° C. for 30 minutes.

Single-stranded nucleic acid binding to E. coli was centrifuged and separated and washed with a 1 ml selection buffer (containing 0.2% BSA). After the solution I (selection buffer, 10 mM EDTA) was treated with the reaction to separate single-stranded nucleic acid, the single-stranded nucleic acid was completely separated by phenol extraction and ethanol precipitation, and the primers of SEQ ID NO: 1 and SEQ ID NO: 2 listed above were used. Nucleic acid for the next selection process was prepared and purified by amplification.

Repeat the same procedure several times and then react with a lower concentration of the target than the first, or perform several more washing steps to isolate and extract single-stranded nucleic acids that are highly specific and highly affinity with the target E. coli. It was.

After performing the last 18 times, the final isolated single-stranded nucleic acid was subjected to PCR using the FW-primer and the RE-primer to synthesize double-stranded nucleic acid. The PCR product was cloned into a T-vector to determine the nucleotide sequence of E. coli (target biomolecule) and single-stranded nucleic acid aptamer having high binding ability. The nucleotide sequence of N ₄₀ was determined as' UAC ACU GCG UGC. UUN CGA CUU CUG GUC CCA UCA UUC GAA U 'sequence (SEQ ID NO: 3).

Example 2 Analysis of Target Biomolecules (E. Coli) Using Selected Single-stranded Nucleic Acid Aptamers

The single-stranded nucleic acid aptamer transcript and PCR primers were designed and prepared to prepare a single-stranded nucleic acid aptamer of the nucleotide sequence selected in Example 1 containing 2'-F-substituted pyrimidine by PCR and in vitro transcription. .

1,000 pmoles single-stranded nucleic acid transcript, 2,500 pmoles of the PCR primer pairs (the FW primers and the RE primers of SEQ ID NO: 1 and SEQ ID NO: 2) were 50 mM KCl, 10 mM Tris-Cl (pH 8.3), 3 mM MgCl ₂ , 0.5 mM dNTP (dATP, dCTP, dGTP, and dTTP), 0.1 U Taq DNA Polymerase (Perkin-Elmer, Foster City Calif.) Followed by QIAquick-spin PCR purification column (QIAGEN Inc., Chatsworth Calif. Purified). Single-stranded nucleic acid aptamers of RNA molecules comprising 2′-F-substituted pyrimidines were prepared by synthesis and purification by in vitro transcription. 200 pmoles double stranded DNA transcript, 40 mM Tris-Cl, pH 8.0, 12 mM MgCl ₂ , 5 mM DTT, 1 mM spermidine, 0.002% Triton X-100, 4% PEG 8000, 5 U T7 RNA Polymerase and 1 mM ATP, GTP and 3 mM 2'F-CTP, 2'F-UTP were reacted at 37 ° C for 6-12 hours, and then purified by Bio-Spin 6 chromatography column (Bio-Rad Laboratories, Hercules Calif.). .

E. coli (DH-5α), a target biomolecule, was incubated for 12 hours, diluted and prepared, and cfu (colony forming unit) was measured according to standard methods. E. coli (target biomolecule) is prepared by dilution with sterile distilled water to prepare 0, 10 ² , 10 ³ , 10 ⁴ , 10 ⁵ and 10 ^6, and then 100 ~ 400 ng of RNA single-stranded nucleic acid pressure The target biomolecule / single-stranded nucleic acid complex was formed by reacting for 30 minutes by adding a tamper.

And 100 ul ~ 500 ul of 0.01% gold-nanoparticles (Sigma-Aldrich, USA) is added directly to the reaction solution, or the supernatant obtained by removing the target biomolecule / single-stranded nucleic acid complex by the principle separation method or filtration method By adding gold-nanoparticles and reacting for 10 minutes, a single-stranded nucleic acid / gold-nanoparticle complex was formed.

Finally, the color of the solution was observed by adding 100-350 ul of 1N NaCl as a salt, and the results are shown in FIGS.

As can be seen in Figure 1, when 100 ng single-stranded nucleic acid aptamer is added when the target biomolecule (E. coli) is less than 1,000, the solution color was purple, when the target biomolecule (E. coli) is more than 1,000 The solution color was red.

As shown in FIG. 2, when 250 ng single-stranded nucleic acid aptamer was added, the solution color was purple when the E. coli (target biomolecule) was less than 10,000, and the solution color was red when the E. coli was 10,000 or more.

As a result, when a complex of single-stranded nucleic acid aptamer and E. coli, a target biomolecule, is formed, the ratio of the stable / unstable structure of the target biomolecule to the unbound single-stranded nucleic acid is changed according to the amount of the target biomolecule. Since the solution color by the single-stranded nucleic acid / gold-nanoparticle complex is different, it is possible to determine the amount (number) of the target biomolecule (eg, E. coli).

That is, the presence and density of the color change of the solution is determined by the selectivity, specificity, and binding ability between the target biomolecule (E. coli) and the single-stranded nucleic acid aptamer, and from this, the target biomolecule can be identified and its amount can be determined. By analyzing the presence and density, it is possible to confirm the types and quantitative changes of biomolecules that are the subject of analysis.

Example 3: Analysis of target biomolecule (protein) using single-stranded nucleic acid aptamer

In this example, the protein VEGF (Vascular Endothelial Growth Factor) was used as the target biomolecule, and the sequence of the single-stranded nucleic acid ligand having high binding strength was 5'-ACC CUG AUG GUA GAC GCC GGG GUG-3 '(US patent). 5,811,533) (SEQ ID NO: 4). Single-stranded nucleic acid aptamer including 2'-F-substituted pyrimidine was prepared in the same manner as in Example 2.

A VEGF protein (R & D Systems, Minneapolis Minn.) Was prepared using a sterile distilled water standard solution of 1ug / mL concentration to prepare a sample to be used as a dilution method. After reacting with 100 ~ 400 ng RNA single-stranded nucleic acid aptamer produced by the above method for 30 minutes, gold nano to the solution obtained by adding 100 ul ~ 500 ul 0.01% gold nanoparticles (Sigma-Aldrich, USA) Particles were added and reacted for 10 minutes. 100-350 ul of 1N NaCl was added to the reaction solution to observe the color of the solution. The degree of color change was measured by absorbance at two wavelengths of 520 nm and 700 nm on a spectrometer.

As shown in Figure 3, when 250 ng single-stranded nucleic acid aptamer is added, the change in color (ie, the change in absorbance) according to the quantitative change of VEGF protein is the same as in Figures 3a to 3d, It was observed that there is a change in color, that is, a change in absorbance due to specific binding and quantitative change of single-stranded nucleic acid aptamer and target protein.

The signal ratio obtained from the above results (signal ratio: 520 nm absorbance / 700 nm absorbance) is 0.15 for VEGF protein of 1 ng / mL, 0.20 for 20 ng / mL, and 30 ng / mL for 0.4, and 50 ng / mL is 1.2, 100 ng / mL is 2.1, and 500 ng / mL is 3.2, and the graph is shown in Figure 4.

That is, as in Example 2 using E. coli as the target biomolecule, even when the protein is used as the target biomolecule, a complex of single-stranded nucleic acid aptamer and VEGF protein is formed to change the ratio of the structure of the unbound aptamer. There will be changes in color and absorbance, and these changes will correlate with the amount of VEGF protein, thus identifying and quantifying proteins (eg VEGF) from specific binding and absorbance changes (discoloration) between single-stranded nucleic acid aptamers and proteins. You can do it.

According to the biomolecule analysis method according to the present invention described above, the formation of the target biomolecule / single-nucleic acid complex by specific binding between the target biomolecule and the single-stranded nucleic acid aptamer to be analyzed, the target biomolecule and Formation of a single-stranded nucleic acid / gold-nanoparticle complex by reaction of the single-stranded nucleic acid with the gold-nanoparticle remaining without forming a complex of the; and the gold-nanoparticle complexed with the single-stranded nucleic acid The color change analysis of the reaction aqueous solution by the salt based on the dispersed state of the target biomolecules can be quickly and safely identified and quantified.

In addition, according to the analytical method according to the present invention, single-stranded nucleic acid aptamers that specifically bind to various biomolecules, including microorganisms, cells, and proteins, which are commonly identified and quantified, are secured, By analyzing the standard data of the color change corresponding to various amounts of these single-stranded nucleic acid aptamers, biomolecules and gold-nanoparticles through analytical methods, the analysis method of the present invention for unknown biomolecules (target biomolecules) By analyzing the results against the standard data, it is possible to identify and quantify various unknown biomolecules, and the analytical method of the present invention may be prepared by analytical kits and distributed. It is expected to be widely applied to the identification and quantification of biomolecules widely used in engineering, food engineering and agriculture.

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Claims (2)

By adding a target biomolecule and a known single-stranded nucleic acid aptamer except the nucleic acid to be analyzed to an aqueous solution to form a target biomolecule / single-nucleic acid complex by specific binding between the target biomolecule and the single-stranded nucleic acid. step; Adding gold-nanoparticles to the aqueous solution to form a single-stranded nucleic acid / gold-nanoparticle complex by reacting the remaining single-stranded nucleic acid with the gold-nanoparticle without forming a complex with the target biomolecule; And Analyzing a color change of the aqueous solution based on a dispersion state of the gold-nanoparticles forming a complex with the single-stranded nucleic acid by adding a salt to the aqueous solution; Including: Thus, the target biomolecule is identified from the specific binding of the target biomolecule and the single-stranded nucleic acid, and the target biomolecule is quantified from the color change of the reaction solution. Biomolecule analysis method using particles. The single-stranded nucleic acid aptamer and gold-nano according to claim 1, wherein the target biomolecule / single-nucleic acid complex formed prior to forming the single-stranded nucleic acid / gold-nanoparticle complex is removed. Biomolecule analysis method using particles.

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