WO2019237406A1 - Dye encoding method based on fluorescently-labeled amino acid - Google Patents

Abstract

Provided is a dye encoding method based on a fluorescently-labeled amino acid and the method employs a tag sequence. An amino acid sequence is used as a tag sequence and is divided into at least two fluorescent regions along an extension direction of the amino acid sequence. An amino acid in each fluorescent region is at least linked to one fluorescent dye or quantum dot, and two adjacent fluorescent regions are spaced by at least 3 amino acids. The present invention greatly expands the numbering range of the tag sequence. By using fluorescent dyes or quantum dots having different colors, spectral overlap can be effectively avoided. Also provided is a liquid phase chip capable of qualitatively and quantitatively detecting a nucleic acid or protein, thereby realizing high-throughput detection.

Description

Dye coding method based on fluorescently labeled amino acids Technical field

The invention belongs to the field of gene detection, and particularly relates to a dye coding method based on fluorescently labeled amino acids and uses thereof.

Background technique

Liquid chips, also known as suspension arrays, the core of this technology is to encode polystyrene microspheres with fluorescent staining, and then covalently cross-link microspheres of each color (or fluorescently coded microspheres) to target Probes for specific nucleic acids. In application, the detection sample is subjected to a hybridization reaction with a plurality of microspheres with specific nucleic acid probes at the same time. After the reaction is completed, the instrument recognizes the encoded microspheres by two laser beams and detects the fluorescence intensity of the reporter molecule on the microspheres, so Target nucleic acid is quantitatively detected. Because the entire reaction is completed in the liquid phase, the reaction speed is fast, the hybridization efficiency is high, and up to hundreds of target sequences can be detected simultaneously in one micro reaction system. However, research results in recent years show that the liquid chip technology still has shortcomings such as low sensitivity and poor reproducibility. The main reason is that the emission spectra of different fluorescent labels overlap widely in the liquid phase, leading to a large number of false positive results, which limits the Further promotion and application of liquid chip technology. Therefore, finding a fluorescent label that can separately label probes with different colors, has high luminous intensity, is not easy to quench, and has little overlap between spectra is the key to improving the sensitivity and repeatability of liquid chip detection.

Summary of the Invention

Therefore, the technical problem to be solved by the present invention is to provide a dye-coding method for fluorescently labeled amino acids and a liquid phase chip, which respectively label probes with different colors, have high luminous intensity, are not easily quenched, and have little overlap between spectra.

To this end, the present invention provides a method for dye coding based on fluorescently labeled amino acids. Using the amino acid sequence as a tag sequence, the tag sequence is divided into at least two fluorescent regions along the extension direction of the amino acid sequence. The amino acids in the region are connected to at least one fluorescent dye or quantum dot, and two adjacent fluorescent regions are separated by at least 3 amino acids.

Preferably, the tag sequence is divided into at least four fluorescent regions, and the length of the amino acid sequence in the fluorescent region is 10-15 amino acids.

Preferably, the fluorescent dyes or quantum dots in any two of the fluorescent regions are different.

Preferably, only one amino acid is connected to the fluorescent dye or the quantum dot in each of the fluorescent regions, and the fluorescent dye or the quantum dot is the same in the same fluorescent region.

Preferably, the fluorescent dye includes BODIPY, FITC, rhodamine, coumarin, xanthene, anthocyanin, osmium or phthalocyanine; the quantum dot is selected from MgS, MgSe, MgTe, CaS, CaSe, CaTe, ZnO , ZnS, ZnSe, ZnTe, SrS, SrSe, SeTe, CdS, CdSe, CdTe, BaS, BaSe, BaTe, HgS, HgSe, HgTe, PbSe, CaAs, InP, InAs, InCaAs, ZnS / CdS, ZnS / CdS / ZnS , ZnS / HgS / ZnS / CdS, CdS / ZnS, CdS / Ag2S, CdS / HgS, CdS / HgS / CdS, CdS / PbS, CdS / Cd (OH) 2, CdSe / CuSe, CdSe / ZnS, CdSe / ZnSe , CdSe / CdS, CdSe / HgSe, CdSe / HgSe / CdSe, CdSe / HgTe, CdTe / HgS, CdTe / HgTe, InAs / ZnSe, InAs / CdSe, InAs / InP, ZnS: Mn, ZnS: Cu, CdS: Mn And any one of CdS: Cu, and a core-shell type quantum dot with any of the above as a core and silica as a shell;

The present invention provides a tag sequence encoded by the dye-coding method based on a fluorescently labeled amino acid.

The invention provides a liquid phase chip, including:

The tag sequence;

A probe molecule P1 linked to the tag sequence;

Magnetic microsphere

A probe molecule P2 connected to the magnetic microsphere, the probe molecule P1 and the probe molecule P2 are not bound to each other.

Preferably, the probe molecule P1 comprises a nucleotide sequence, an antigen or an antibody, and the probe molecule P2 comprises a nucleotide sequence, an antigen or an antibody.

Preferably, biotin or a fluorescent dye is connected to the probe molecule P2, and the fluorescent dye connected to the probe molecule P2 is different from the fluorescent dye in the tag sequence.

The invention provides a method for preparing the liquid phase chip, which includes the following steps:

S1. Connecting the tag sequence to a probe molecule P1;

S2. Link biotin or fluorescent dye to probe molecule P2

S3. Attach the magnetic microsphere to the probe molecule P2.

The invention provides a use of the liquid-phase chip in the field of nucleic acid or protein detection.

Compared with the prior art, the present invention has the following advantages:

1. A dye-coding method based on a fluorescently labeled amino acid provided by the present invention, which uses an amino acid sequence as a tag sequence and divides the tag sequence into at least two fluorescent regions along the extending direction of the amino acid sequence, The amino acid is connected to at least one fluorescent dye or quantum dot, and the adjacent two fluorescent regions are separated by at least 3 amino acids, so that the fluorescence emitted between the two regions does not interfere with each other.

2. The dye coding method based on fluorescently labeled amino acids provided by the present invention, each fluorescent region is connected with a fluorescent dye or quantum dot, and the labeling sequence can be achieved by arranging and combining the fluorescent dye or quantum dot connected with each fluorescent region. The purpose of numbering. The tag sequence is divided into four fluorescent regions. By combining 4 different fluorescent dyes or quantum dots, 24 different combinations can be obtained. If different fluorescent regions can use the same fluorescent dye or quantum dot, 4 Fluorescent areas can be obtained in 256 different combinations. By analogy, the more fluorescent regions are divided into the tag sequence, the more combinations can be obtained, and more numbered tag sequences can be realized, which greatly expands the number range of the tag sequence. In addition, by using different colors of fluorescent dyes or quantum dots, it is possible to effectively avoid overlap between the spectra.

3. The dye-coding method based on fluorescently labeled amino acids provided by the present invention, the number of fluorescent dyes or quantum dots connected in each fluorescent region of the tag sequence is different, so that the luminous intensity of each fluorescent region is different. Permutation and combination of the luminous intensity can achieve the purpose of numbering the tag sequence; for example, the tag sequence is divided into 4 fluorescent regions, each fluorescent region can be connected to 10 quantum dots, and a fluorescence intensity level is set for each two quantum dots. 5 is a fluorescence intensity level, four different fluorescence regions can be obtained in the arrangement ^54, and so on, provided N fluorescent tag sequence regions, provided M fluorescent fluorescence intensity levels within each region can be M ^N kinds of Different arrangement methods greatly expand the number range of the tag sequence.

4. The liquid-phase chip provided by the present invention comprises a tag sequence, a probe molecule P1 connected to the tag sequence, and a magnetic microsphere-labeled probe molecule P2, and detects the fluorescence emitted by the fluorescent dye of each fluorescent region of the tag sequence to obtain a tag. The sequence number is used to know whether the target nucleic acid sequence exists in the test sequence, and the target nucleic acid sequence can be qualitatively detected.

5. The liquid-phase chip provided by the present invention can utilize the fluorescence intensity of the fluorescent dye or biotin on the probe molecule P2 to be proportional to the concentration of the target nucleic acid sequence, so that the target nucleic acid sequence can be quantitatively detected.

6. The liquid-phase chip provided by the present invention can detect a plurality of different target sequences at one time, and realize high-throughput detection.

7. In the liquid-phase chip provided by the present invention, the probe molecule P1 includes a nucleotide sequence, a protein, or a saccharide, and the probe molecule P2 includes a nucleotide sequence, a protein, or a saccharide. Class for detection.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a coding schematic diagram of a dye coding method for fluorescently labeled amino acids in an embodiment of the present invention; FIG.

2 is a schematic diagram of detection of a liquid phase chip in an embodiment of the present invention;

FIG. 3 is a liquid crystal chip detection result of ALK, APC, BRAF and EGFR genes in an experimental example of the present invention.

detailed description

The following describes the embodiments of the present invention through specific examples. Unless otherwise stated, the experimental methods disclosed in the present invention adopt conventional techniques in the technical field.

Example 1

This embodiment provides a dye coding method based on fluorescently labeled amino acids. The amino acid sequence is a tag sequence and the length is 70 amino acids. As shown in FIG. 1, the tag sequence is divided into four fluorescent regions, which are respectively a fluorescent region I and a fluorescent region. Region II, fluorescence region III and fluorescence region IV are all 15 amino acids in length, with at least 3 amino acids spaced between two adjacent fluorescent regions, and in this embodiment 3 amino acids spaced between two adjacent fluorescent regions ; Wherein leucine in fluorescent region I is connected to rhodamine, cysteine in fluorescent region II is connected to anthocyanin, lysine in fluorescent region III is connected to coumarin, and valine in fluorescent region IV is connected Phthalocyanine.

According to the above-mentioned dye-coding method based on fluorescently labeled amino acids, arrange and combine the fluorescent dyes connected to each fluorescent region. Each fluorescent region uses different fluorescent dyes to obtain 24 different arrangements, and number each arrangement. As the numbering of the tag sequence, numbering of the tag sequence is realized.

The encoding method divides the tag sequence into a plurality of fluorescent regions, and two adjacent fluorescent regions are separated by at least 3 amino acids, so that the fluorescence emitted between the two regions does not interfere with each other. A fluorescent dye is connected to each fluorescent region, and the number of tag sequences can be achieved by arranging and combining the fluorescent dyes connected to each fluorescent region. For example, as shown in Table 1, an example of the combination method of arrangement is given. By combining 4 different fluorescent dyes, 24 different combinations can be obtained. If different fluorescent regions can use the same fluorescent dye, 4 There are 256 different combinations of fluorescence regions.

Table 1

ID	Fluorescent region I	Fluorescent Region II	Fluorescent Region III	Fluorescent Region IV
1	Rodin	anthocyanin	Coumarin	Phthalocyanine
2	Rodin	anthocyanin	Phthalocyanine	Coumarin
3	Rodin	Coumarin	Phthalocyanine	anthocyanin
4	Rodin	Coumarin	anthocyanin	Phthalocyanine
5	Rodin	Phthalocyanine	anthocyanin	Coumarin
6	Rodin	Phthalocyanine	Coumarin	anthocyanin
7	anthocyanin	Rodin	Coumarin	Phthalocyanine
8	anthocyanin	Rodin	Phthalocyanine	Coumarin
9	anthocyanin	Coumarin	Rodin		Phthalocyanine
10	anthocyanin	Coumarin	Phthalocyanine	Rodin

11	anthocyanin	Phthalocyanine	Rodin	Coumarin
12	anthocyanin	Phthalocyanine	Coumarin	Rodin
13	Coumarin	Rodin	anthocyanin	Phthalocyanine
14	Coumarin	Rodin	Phthalocyanine	anthocyanin
15	Coumarin	anthocyanin	Rodin	Phthalocyanine
16	Coumarin	anthocyanin	Phthalocyanine	Rodin
17	Coumarin	Phthalocyanine	Rodin	anthocyanin
18	Coumarin	Phthalocyanine	anthocyanin	Rodin
19	Phthalocyanine	Rodin	anthocyanin	Coumarin
20	Phthalocyanine	Rodin	Coumarin	anthocyanin
twenty one	Phthalocyanine	anthocyanin	Rodin	Coumarin
twenty two	Phthalocyanine	anthocyanin	Coumarin	Rodin
twenty three	Phthalocyanine	Coumarin	anthocyanin	Rodin
twenty four	Phthalocyanine	Coumarin	Rodin	anthocyanin

Dividing the tag sequence into 5 fluorescent regions can get 625 different combinations, and so on. The more the tag sequence is divided into more fluorescent regions, the more combinations can be obtained, and more numbered tag sequences can be achieved, greatly expanding. The number range of the tag sequence. In addition, by using fluorescent dyes of different colors, it is possible to effectively avoid overlap between the spectra.

Example 2

This embodiment provides a method for coding a dye based on a fluorescently labeled amino acid. Using the amino acid sequence as a tag sequence and a length of 80 amino acids, the tag sequence is divided into four fluorescent regions, namely, fluorescent region I, fluorescent region II, and fluorescence. Region III and fluorescence region IV are both 15 amino acids in length, with at least 3 amino acids spaced between two adjacent fluorescent regions, and in this embodiment, 5 amino acids spaced between two adjacent fluorescent regions; Leucine in I is linked to pyrene, cysteine in fluorescent region II is connected to BODIPY, lysine in fluorescent region III is connected to FITC, and valine in fluorescent region IV is connected to rhodamine.

According to the above-mentioned dye-coding method based on fluorescently labeled amino acids, arrange and combine the fluorescent dyes connected to each fluorescent region. Each fluorescent region uses different fluorescent dyes to obtain 24 different arrangements, and number each arrangement. As the numbering of the tag sequence, numbering of the tag sequence is realized.

Example 3

This embodiment provides a method for encoding a dye based on a fluorescently labeled amino acid. Using the amino acid sequence as a tag sequence and a length of 100 amino acids, the tag sequence is divided into five fluorescent regions, namely, fluorescent region I, fluorescent region II, and fluorescence. Region III, fluorescence region IV, and fluorescence region V are all 15 amino acids in length, with at least 3 amino acids spaced between two adjacent fluorescent regions, and in this embodiment 5 amino acids spaced between two adjacent fluorescent regions ; Where leucine in fluorescent region I is linked to xanthene, cysteine in fluorescent region II is linked to anthocyanin, lysine in fluorescent region III is linked to pyrene, and valine in fluorescent region IV is linked to BODIPY, Serine in the fluorescent region V is connected to rhodamine.

According to the above-mentioned fluorescently-labeled amino acid-based dye coding method, the five fluorescent dyes (xanthene, anthocyanin, hydrazone, BODIPY, and rhodamine) are selected and combined to mark the five fluorescent regions, thereby realizing 625 tag sequence numbers.

Example 4

This embodiment provides a method for dye coding based on fluorescently labeled amino acids. The amino acid sequence is a tag sequence with a length of 30 amino acids, and the tag sequence is divided into two fluorescent regions, which are fluorescent region I, fluorescent region II, and length. Both are 10 amino acids, with at least 3 amino acids spaced between two adjacent fluorescent regions, and in this embodiment, 10 amino acids spaced between two adjacent fluorescent regions; where the cysteine in the fluorescent region I is linked Phthalocyanine, a serine-linked anthocyanin in fluorescent region II.

According to the above-mentioned method for coding dyes based on fluorescently labeled amino acids, arrange and combine the fluorescent dyes connected to each fluorescent region. Use different fluorescent dyes for each fluorescent region to obtain 2 different arrangements, and number each arrangement. As the numbering of the tag sequence, numbering of the tag sequence is realized.

As an alternative embodiment, the tag sequence can be divided into two, three, four, five or more fluorescent regions, as long as there are at least 3 amino acids spaced between two adjacent fluorescent regions, there is only one of each fluorescent region An amino acid is linked to a fluorescent dye.

As an alternative embodiment, the fluorescent dye may be BODIPY, FITC, rhodamine, coumarin, xanthene, anthocyanins, osmium, and phthalocyanine.

Example 5

This embodiment provides a method for encoding a dye based on a fluorescently labeled amino acid. Using the amino acid sequence as a tag sequence and a length of 95 amino acids, the tag sequence is divided into four fluorescent regions, namely, fluorescent region I, fluorescent region II, and fluorescence. Region III and fluorescence region IV are both 15 amino acids in length, with at least 3 amino acids spaced between two adjacent fluorescent regions, and in this example, 3 amino acids spaced between two adjacent fluorescent regions; Cysteine in I is connected to CdTe, valine in fluorescent region II is connected to CaS, serine in fluorescent region III is connected to CdS, and leucine in fluorescent region IV is connected to CdSe.

The encoding method divides the tag sequence into a plurality of fluorescent regions, and two adjacent fluorescent regions are separated by at least 3 amino acids, so that the fluorescence emitted between the two regions does not interfere with each other. A quantum dot is connected to each fluorescent region, and the number of tag sequences can be achieved by arranging and combining the quantum dots connected to each fluorescent region. For example, as shown in Table 2, an example of the combination method of permutations is given. By combining 4 different quantum dots, 24 different combinations can be obtained. If different fluorescent regions can use the same quantum dot, 4 There are 256 different combinations of fluorescence regions.

Table 2

ID	Fluorescent region I	Fluorescent Region II	Fluorescent Region III	Fluorescent Region IV
1	CdTe	CaS	CdS	CdSe
2	CdTe	CaS	CdSe	CdS
3	CdTe	CdS	CdSe	CaS
4	CdTe	CdS	CaS	CdSe
5	CdTe	CdSe	CaS	CdS
6	CdTe	CdSe	CdS	CaS
7	CaS	CdTe	CdS	CdSe
8	CaS	CdTe	CdSe	CdS
9	CaS	CdS	CdTe	CdSe

10	CaS	CdS	CdSe	CdTe
11	CaS	CdSe	CdTe	CdS
12	CaS	CdSe	CdS	CdTe
13	CdS	CdTe	CaS	CdSe
14	CdS	CdTe	CdSe	CaS
15	CdS	CaS	CdTe	CdSe
16	CdS	CaS	CdSe	CdTe
17	CdS	CdSe	CdTe	CaS
18	CdS	CdSe	CaS	CdTe
19	CdSe	CdTe	CaS	CdS
20	CdSe	CdTe	CdS	CaS
twenty one	CdSe	CaS	CdTe	CdS
twenty two	CdSe	CaS	CdS	CdTe
twenty three	CdSe	CdS	CaS	CdTe
twenty four	CdSe	CdS	CdTe	CaS

Dividing the tag sequence into 5 fluorescent regions can get 625 different combinations, and so on. The more the tag sequence is divided into more fluorescent regions, the more combinations can be obtained, and more numbered tag sequences can be achieved, greatly expanding. The number range of the tag sequence. In addition, by using quantum dots of different colors, the overlap between the spectra can be effectively avoided.

Example 6

This embodiment provides a method for encoding a dye based on a fluorescently labeled amino acid. Using the amino acid sequence as a tag sequence and a length of 95 amino acids, the tag sequence is divided into four fluorescent regions, namely, fluorescent region I, fluorescent region II, and fluorescence. Region III and fluorescence region IV are both 15 amino acids in length, with at least 3 amino acids spaced between two adjacent fluorescent regions, and in this embodiment, 5 amino acids spaced between two adjacent fluorescent regions; The amino acids in I are linked to CdTe, the amino acids in fluorescent region II are linked to CaS, the amino acids in fluorescent region III are linked to CdS, and the amino acids in fluorescent region IV are linked to CdSe. For each fluorescent region, two quantum dots are connected to one fluorescence intensity level. For example, two amino acids in fluorescent region I are connected to CdTe, then the fluorescence intensity level of fluorescent region I is CdTe intensity I, and four amino acids are in fluorescent region II. When CaS is connected, the fluorescence intensity level of fluorescent region II is CaS intensity II. Six amino acids in fluorescent region III are connected to CdS. The fluorescence intensity level of fluorescent region III is CdS intensity III. Eight amino acids in fluorescent region IV are connected to CdSe. , The fluorescence intensity level of the fluorescent region IV is the CdSe intensity IV. In this embodiment, each fluorescent region is divided into five fluorescent intensity levels: intensity I, intensity II, intensity III, intensity IV, and intensity V. By arranging and combining the fluorescence intensity levels of the quantum dots connected to each fluorescent region, it can be achieved The purpose of numbering the tag sequence. For example, as shown in Table 3, are arranged in combination is exemplified by 4 different intensity levels of fluorescence quantum dots composition can be obtained ⁵⁴ different combinations, that is numbered ^54.

table 3

ID	Fluorescent region I	Fluorescent Region II	Fluorescent Region III	Fluorescent Region IV
1	CdTe intensity I	CaS intensity II	CdS intensity III	CdS intensity IV

2	CdT intensity III	CaS intensity I	CdS intensity IV	CdS intensity V
3	CdT intensity III	CdS intensity IV	CdSe intensity I	CaS intensity V
4	CdT intensity IV	CdS intensity III	CaS intensity II	CdSe intensity I

Example 7

This embodiment provides a method for encoding a dye based on a fluorescently labeled amino acid, which uses an amino acid sequence as a tag sequence and a length of 125 amino acids, and divides the tag sequence into five fluorescent regions, namely, fluorescent region I, fluorescent region II, and fluorescence. Region III, fluorescence region IV, and fluorescence region V are 15 amino acids in length, with at least 3 amino acids spaced between two adjacent fluorescent regions, and in this embodiment 5 amino acids spaced between two adjacent fluorescent regions. Where the amino acid in the fluorescent region I is connected to CdTe, the amino acid in the fluorescent region II is connected to CaS, the amino acid in the fluorescent region III is connected to CdS, the amino acid in the fluorescent region IV is connected to CdSe, and the amino acid in the fluorescent region V is connected to HgS. For each fluorescent region, two quantum dots are connected to one fluorescence intensity level. For example, two amino acids in fluorescent region I are connected to CdTe, then the fluorescence intensity level of fluorescent region I is CdTe intensity I, and four amino acids are in fluorescent region II. When CaS is connected, the fluorescence intensity level of fluorescent region II is CaS intensity II. Six amino acids in fluorescent region III are connected to CdS. The fluorescence intensity level of fluorescent region III is CdS intensity III. Eight amino acids in fluorescent region IV are connected to CdSe. , The fluorescence intensity level of the fluorescent region IV is CdSe intensity IV; ten amino acids in the fluorescent region V are connected to HgS, and the fluorescence intensity level of the fluorescent region V is HgS intensity V. In this embodiment, each fluorescent region is divided into 6 Fluorescence intensity levels: Intensity I, Intensity II, Intensity III, Intensity IV, Intensity V, and Intensity VI. Permutation and combination of the fluorescence intensity levels of the quantum dots connected to each fluorescent region can achieve the purpose of numbering tag sequences. 5 different quantum dots, 6 fluorescence intensity levels are combined can be obtained ⁶⁵ different combinations, that is numbered ^65.

As an alternative embodiment, the tag sequence can be divided into two, three, four, five or more fluorescent regions, as long as the interval between adjacent two fluorescent regions is at least 5bp, and an amino acid is connected to a quantum in each fluorescent region. point.

As an alternative embodiment, the quantum dots may be MgS, MgSe, MgTe, CaS, CaSe, CaTe, ZnO, ZnS, ZnSe, ZnTe, SrS, SrSe, SeTe, CdS, CdSe, CdTe, BaS, BaSe, BaTe, HgS , HgSe, HgTe, PbSe, CaAs, InP, InAs, InCaAs, ZnS / CdS, ZnS / CdS / ZnS, ZnS / HgS / ZnS / CdS, CdS / ZnS, CdS / Ag2S, CdS / HgS, CdS / HgS / CdS , CdS / PbS, CdS / Cd (OH) 2, CdSe / CuSe, CdSe / ZnS, CdSe / ZnSe, CdSe / CdS, CdSe / HgSe, CdSe / HgSe / CdSe, CdSe / HgTe, CdTe / HgS, CdTe / HgTe , InAs / ZnSe, InAs / CdSe, InAs / InP, ZnS: Mn, ZnS: Cu, CdS: Mn, and CdS: Cu, and a core with any of the above as the core and silica as the shell Shell-type quantum dots.

The tag sequence is divided into N fluorescent regions with at least 3 amino acids spaced between two adjacent fluorescent regions. Each fluorescent region is connected to a quantum dot. Each fluorescent region is divided into M fluorescence intensity levels. N different quantum dots and M fluorescence intensity levels can be combined to obtain M ^N different combinations, that is, M ^N numbers, and each arrangement number is used as the number of the tag sequence to realize the tag sequence. Numbering.

Example 8

A liquid phase chip provided in this embodiment includes a tag sequence encoded by the dye coding method based on a fluorescently labeled amino acid in Embodiment 1;

According to the target nucleic acid sequence, a probe molecule P1 and a probe molecule P2 are designed. The probe molecule P1 can hybridize and bind to the 5 'end of the target nucleic acid sequence, and the probe molecule P2 can hybridize and bind to the 3' end of the target nucleic acid sequence. The probe molecule P1 and probe molecule P2 are not complementary, and a fluorescent dye FITC is connected to the probe molecule P2. As shown in FIG. 2, the probe molecule P1 is connected to a tag sequence, and the probe molecule P2 is connected to a magnetic microsphere; the tag sequence to which the probe molecule P1 is connected and the magnetism to which the probe molecule P2 is connected. Microsphere mix.

Use universal primers to perform PCR amplification on the sample to be tested, and then add the PCR amplification product to the liquid-phase chip. The PCR amplification product simultaneously performs hybridization reaction with the tag sequence and magnetic microspheres. If the sample to be tested contains the target nucleic acid Sequence, the probe molecule P1 on the tag sequence and the probe molecule P2 on the magnetic microsphere can specifically bind to the target nucleic acid sequence through base complementation. The resulting complex can be magnetically separated from the reaction system using magnetic microspheres. The target nucleic acid sequence is quantitatively detected according to the fluorescence intensity of the fluorescent dye on the probe molecule P2 and the concentration of the target nucleic acid sequence. If the target nucleic acid sequence is not contained in the test sample, the probe molecule P1 for the target nucleic acid cannot be bound to the magnetic microsphere-labeled probe molecule P2 through the target nucleic acid sequence, and is not magnetic, so it can be taken out during magnetic separation.

Example 9

This embodiment provides a liquid phase chip, which includes a tag sequence encoded by the dye-encoding method based on a fluorescently labeled amino acid in Example 6, that is, the tag sequence is an amino acid sequence with a length of 95 amino acids, and the tag sequence is divided into four fluorescences. Regions, which are fluorescent region I, fluorescent region II, fluorescent region III, and fluorescent region IV, each having a length of 15 amino acids, with at least 3 amino acids spaced between two adjacent fluorescent regions; CdTe, CaS, CdS, and CdSe, respectively Linked to an amino acid in four fluorescent regions, where leucine in fluorescent region I is connected to CdTe, serine in fluorescent region II is connected to CaS, valine in fluorescent region III is connected to CdS, and in fluorescent region IV Cysteine is connected to CdSe, and every two quantum dots in each fluorescent region is a fluorescence intensity level. For example, two amino acids in fluorescent region I are connected to CdTe, then the fluorescence intensity level of fluorescent region I is CdTe intensity I, and the fluorescence There are four amino acids connected to CaS in region II, then the fluorescence intensity level of fluorescent region II is CaS intensity II, and six amino acids in fluorescent region III are connected to Cd S, the fluorescence intensity level of the fluorescence region III is CdS intensity III, and eight amino acids in the fluorescence region IV are connected to CdSe, and the fluorescence intensity level of the fluorescence region IV is CdSe intensity IV. In this embodiment, each fluorescent region is divided into five fluorescent intensity levels: intensity I, intensity II, intensity III, intensity IV, and intensity V. The combination and arrangement of the fluorescence intensity levels of the quantum dots connected to each fluorescent region can achieve The label sequence is numbered for the purpose. By combining four different quantum dot fluorescence intensity levels, 625 different combinations can be obtained, and each arrangement is numbered as the number of the tag sequence.

According to 625 different target nucleic acid sequences, different probe molecules P1 and P2 are designed. The probe molecule P1 can hybridize and bind to the 5 'end of the target nucleic acid sequence, and the probe molecule P2 can hybridize and bind to the 3' end of the target nucleic acid sequence. The probe molecule P1 and the probe molecule P2 are not complementary, and a fluorescent dye FITC is connected to the probe molecule P2. The probe molecule P1 is connected to a tag sequence, and the probe molecule P2 is connected to a magnetic microsphere; the tag sequence to which the probe molecule P1 is connected and the magnetic microsphere to which the probe molecule P2 is connected are mixed.

Use universal primers to perform PCR amplification on the sample to be tested, and then add the PCR amplification product to the liquid-phase chip. The PCR amplification product performs hybridization reaction with the tag sequence and magnetic microspheres at the same time. Target nucleic acid sequence, the probe molecule P1 on the tag sequence and the probe molecule P2 on the magnetic microsphere can specifically bind to the target nucleic acid sequence through base complementation, and the resulting complex can be magnetically separated from the magnetic microsphere It is separated from the reaction system, and the fluorescence emitted by the fluorescent dye in each fluorescent region of the tag sequence is detected to obtain the number of the tag sequence. It can be known whether the target nucleic acid sequence exists in the test sequence, and the target nucleic acid sequence can be qualitatively detected. The fluorescence intensity of the fluorescent dye FITC on the needle molecule P2 is directly proportional to the concentration of the target nucleic acid sequence, and the target nucleic acid sequence is quantitatively detected.

Experimental example 1

This experimental example uses the liquid-phase chip in Example 9 to detect four tumor-targeting drug-related genes, including ALK, APC, BRAF, and EGFR. The tag sequence is shown in SEQ NO.1, the probe molecule P1 of the ALK gene is shown in SEQ NO.2, the probe molecule P2 is shown in SEQ NO.3, and the probe molecule P1 of the APC gene is shown in SEQ NO.4 The probe molecule P2 is shown in SEQ NO.5; the probe molecule P1 of the BRAF gene is shown in SEQ NO.6, the probe molecule P2 is shown in SEQ NO.7; the probe molecule P1 of the EGFR gene is shown in SEQ. The probe molecule P2 is shown in SEQ. NO.9.

FIG. 3 is a standard curve for detecting a gene-mixed sample related to tumor-targeting drug administration using a flow cytometer using the liquid-phase chip of the present invention, and a regression equation of each standard curve is obtained by a least square method. R2 is higher than 0.99, indicating fluorescence The fluorescence intensity of the dye FITC is directly proportional to the concentration of the target nucleic acid sequence, and the target nucleic acid sequence can be quantitatively detected based on this.

The above-mentioned embodiment is merely an example for clear description, and is not a limitation on the implementation. For those of ordinary skill in the art, on the basis of the above description, other different forms of changes or changes can also be made, and the obvious changes or changes derived therefrom are still within the protection scope of the present invention.

Claims (11)

1. A dye coding method based on fluorescently labeled amino acids, characterized in that:

   An amino acid sequence is used as a tag sequence, and the tag sequence is divided into at least two fluorescent regions along the extension direction of the amino acid sequence, and the amino acids in each fluorescent region are connected to at least one fluorescent dye or quantum dot, and two adjacent Fluorescent regions are separated by at least 3 amino acids.
2. The method according to claim 1, wherein the tag sequence is divided into at least four fluorescent regions, and the length of the amino acid sequence in the fluorescent region is 10-15 amino acids.
3. The method according to claim 1 or 2, wherein the fluorescent dyes or quantum dots in any two of the fluorescent regions are different.
4. The method for encoding a dye based on a fluorescently labeled amino acid according to any one of claims 1 to 3, wherein only one amino acid in each of the fluorescent regions is connected to a fluorescent dye or a quantum dot, and the fluorescence in the same fluorescent region is The dye or quantum dot is the same.
5. The method for encoding a dye based on a fluorescently labeled amino acid according to any one of claims 1 to 4, wherein the fluorescent dye comprises BODIPY, FITC, rhodamine, coumarin, xanthene, anthocyanin, osmium, or phthalocyanine The quantum dot is selected from MgS, MgSe, MgTe, CaS, CaSe, CaTe, ZnO, ZnS, ZnSe, ZnTe, SrS, SrSe, SeTe, CdS, CdSe, CdTe, BaS, BaSe, BaTe, HgS, HgSe, HgTe , PbSe, CaAs, InP, InAs, InCaAs, ZnS / CdS, ZnS / CdS / ZnS, ZnS / HgS / ZnS / CdS, CdS / ZnS, CdS / Ag2S, CdS / HgS, CdS / HgS / CdS, CdS / PbS , CdS / Cd (OH) 2, CdSe / CuSe, CdSe / ZnS, CdSe / ZnSe, CdSe / CdS, CdSe / HgSe, CdSe / HgSe / CdSe, CdSe / HgTe, CdTe / HgS, CdTe / HgTe, InAs / ZnSe , InAs / CdSe, InAs / InP, ZnS: Mn, ZnS: Cu, CdS: Mn, and CdS: Cu, and core-shell type quantum dots with any of the above as the core and silica as the shell .
6. A tag sequence encoded by the dye-coding method based on a fluorescently labeled amino acid according to any one of claims 1-5.
7. A liquid-phase chip, comprising:

   The tag sequence of claim 6;

   A probe molecule P1 linked to the tag sequence;

   Magnetic microsphere

   A probe molecule P2 connected to the magnetic microsphere, the probe molecule P1 and the probe molecule P2 are not bound to each other.
8. The liquid-phase chip according to claim 7, wherein the probe molecule P1 comprises a nucleotide sequence, an antigen or an antibody, and the probe molecule P2 comprises a nucleotide sequence, an antigen or an antibody.
9. The liquid-phase chip according to claim 8, wherein biotin or a fluorescent dye is connected to the probe molecule P2, and the fluorescent dye connected to the probe molecule P2 is not the same as the fluorescent dye in the tag sequence. the same.
10. A method for preparing a liquid-phase chip according to claim 7-9, comprising the following steps:

    S1. Linking the tag sequence of claim 6 to a probe molecule P1;

    S2. Link biotin or fluorescent dye to probe molecule P2

    S3. Attach the magnetic microsphere to the probe molecule P2.
11. The use of the liquid-phase chip according to claims 7-9 in the field of nucleic acid or protein detection.

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