WO2016037394A1 - 一种核酸单链环状文库的构建方法和试剂 - Google Patents
一种核酸单链环状文库的构建方法和试剂 Download PDFInfo
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Definitions
- the invention relates to the technical field of molecular biology, and in particular to a method and a reagent for constructing a nucleic acid single-chain circular library.
- Exon sequencing also known as target exome capture refers to a genomic analysis method that uses sequence region capture technology to capture and enrich the whole genome exon region DNA for high-throughput sequencing. It is an efficient strategy for selecting the coding sequence of the genome. Exon sequencing has lower cost than genomic resequencing, and has great advantages for studying single nucleotide polymorphisms and insertion deletions of known genes.
- the more commonly used exon library is a double-stranded DNA library based on Illumina platform or Proton platform. The experimental procedure is as follows: genomic DNA is randomly broken into fragments of 180-280 bp by physical crusher, and the ends are repaired and added. After A tail, a DNA library was prepared by ligating the adaptors at both ends of the fragment.
- the library is subjected to liquid phase hybridization with a biotin-labeled probe, and the exon is captured using a magnetic bead with streptomycin, and then the enriched DNA fragment is eluted from the magnetic beads and hybridized for a second rich Set the reaction. After linear amplification by PCR, the library quality inspection can be carried out after sequencing.
- the transposase disruption kit led by Epigentra's Nextera kit (acquired by Illumina), uses DNA transposase to simultaneously complete DNA fragmentation and linker addition, reducing sample processing time. This method can be used for library construction.
- transposase realizes transposition Rely on a specific 19 bp Me sequence.
- a transposase can have a different linker sequence at the 5' and 3' ends of the target sequence by embedding two completely different linker sequences, the linker needs to contain Mete.
- the sequence is such that one effect is that the ends of the fragment produced by the disruption are symmetrically each have a Me sequence, and due to the special action of the transposase, the sequence of interest (or the disrupted fragment) is separated from the Me sequence.
- the Me sequence which is completely consistent with the two ends of the target sequence, will affect some downstream applications.
- the Me sequences on both sides of the same chain are complementary sequences, which easily cause single chain. Annealing occurs inside the molecule and is not conducive to anchoring the primer.
- the invention provides a method and a reagent for constructing a nucleic acid single-stranded circular library, which has a simple process, saves time and is not affected by the common transposase recognition sequence at both ends.
- the present invention provides a method for constructing a nucleic acid single-stranded circular library, comprising the steps of:
- the nucleic acid is randomly disrupted using a transposase-embedded complex comprising a transposase and a first linker comprising a transposase recognition sequence, the disrupted nucleic acid being ligated to the first linker at both ends and Forming a gap;
- the first PCR reaction is carried out using primers respectively targeting the first linker and the second linker to obtain a product having different linker sequences ligated to each end, wherein one primer has a first affinity tag at the 5' end;
- Single strands are cyclized using a single-stranded circular "bridge” sequence in which a single-stranded circular "bridge” sequence is capable of simultaneously binding to both ends of a single strand.
- a second PCR reaction is carried out using primers respectively targeting the first linker and the second linker to obtain a product in which different linker sequences are ligated to each end.
- one of the primer pairs used in the second PCR reaction has a sample tag sequence at the 5' end.
- the exon sequence probe is used to capture a single strand containing the exon sequence in the product of the second PCR reaction, wherein the exon
- the sequence probe has a first affinity tag capable of forming an affinity binding with a second affinity tag on a solid support, and isolating a single strand containing the exon sequence for use in performing the first PCR reaction.
- the primers are used to block the primers at both ends of the product obtained by the second PCR reaction. sequence.
- the first affinity tag is a biotin tag
- the second affinity tag is a streptavidin tag
- the transposase in the removal system is carried out by magnetic bead purification, column purification or chemical reagent treatment.
- the solid support is a magnetic bead.
- the method comprises the following steps:
- the nucleic acid is randomly disrupted using a transposase-embedded complex comprising a transposase and a first linker comprising a transposase recognition sequence, the disrupted nucleic acid being ligated to the first linker at both ends and Forming a gap;
- a second PCR reaction is performed using primers respectively targeting the first linker and the second linker to obtain a product having different linker sequences linked at both ends, wherein one primer has a sample tag sequence at the 5' end;
- the exon sequence probe is used to capture a single strand containing the exon sequence in the product of the second PCR reaction, wherein the exon sequence probe has a biotin label and can form a streptavidin label with the solid phase carrier. Affinity binding, and separating a single strand containing an exon sequence;
- the first PCR reaction is carried out using primers for both ends of the single strand containing the exon sequence, and a product having different linker sequences ligated to each end is obtained, wherein one primer has a biotin label at the 5' end;
- a construction reagent for a nucleic acid single-stranded circular library comprising the following components:
- transposase and a first linker comprising a transposase recognition sequence for forming a transposase-embedded complex to randomly interrupt the nucleic acid, connecting the first linker at both ends of the interrupted nucleic acid and forming a gap;
- a primer for the first PCR reaction wherein one primer has a first affinity tag at the 5' end, and the primers are respectively targeted to bind the first linker and the second linker;
- a single-stranded circular "bridge" sequence capable of simultaneously binding both ends of a single strand for cyclization of a single strand.
- the reagent further comprises a primer for the second PCR reaction for separately targeting the first linker and the second linker;
- one of the primers used in the second PCR reaction has a sample tag sequence at the 5' end.
- the reagent further comprises an exon sequence probe for capturing a single strand containing an exon sequence in the product of the second PCR reaction, the exon sequence probe having the first affinity tag, capable of Forming an affinity bond with the second affinity tag on the solid support, and separating the single strand containing the exon sequence;
- the reagent further comprises a primer blocking sequence for blocking the primer sequences at both ends of the single strand of the product obtained by the second PCR reaction.
- the first affinity tag is a biotin tag
- the second affinity tag is a streptavidin tag
- the solid support is a magnetic bead.
- the method for constructing a nucleic acid single-stranded circular library of the present invention comprises using a transposase to interrupt a nucleic acid and further adding a second linker to realize a different linker sequence at both ends, thereby separating the single strand and performing cyclization.
- Single-stranded circular library Compared to the prior art, the method of the present invention is simple in flow, time-saving and is not limited to having a common transposase recognition sequence at both ends.
- FIG. 1 is a schematic flow chart of a method for constructing a CG original single-joint library based on the prior art
- FIG. 2 is a schematic flow chart showing the construction of a transposase-binding single-linker exon library according to an embodiment of the present invention
- FIG. 3 is a schematic flow chart showing the construction of a transposase-binding single-linker exon library according to an embodiment of the present invention
- lane 1 represents the single-chain cyclized product obtained in the present embodiment
- M1 and M2 represent single-chain cyclized DNA Marker
- Figure 5 is a diagram showing the distribution of single base cumulative coverage depth obtained by sequencing a single-stranded circularized library according to an embodiment of the present invention.
- the terms used in the present invention are as follows:
- the first joint is referred to as a first joint in a specific embodiment;
- the second joint is referred to as a second joint in a specific embodiment.
- a method for constructing a nucleic acid single-stranded circular library comprises the steps of: randomly interrupting a nucleic acid using a transposase-embedded complex, wherein the transposase-embedded complex comprises a transposase and a transposome a first linker of the enzyme recognition sequence, the interrupted nucleic acid is ligated to the first linker at both ends and forms a gap; the transposase in the system is removed, and then the second linker is ligated at the gap using a ligase, and the sequence of the second linker is different In the first linker; performing a first PCR reaction using primers respectively targeting the first linker and the second linker to obtain a product having different linker sequences linked at both ends, wherein one primer has a first affinity tag at the 5' end Contacting the product of the first PCR reaction with a solid phase support having a second affinity tag to form an affinity binding of the first affinity tag to the second affinity
- the above method enables the construction of a basic nucleic acid single-stranded circular library without distinguishing between exon and intron sequences. It is known that for a bacterial genome that does not have an intron, a single-stranded circular library can be realized by the above method. Constructed and can be further used for downstream sequencing and other operations.
- the above method uses a transposase-embedded complex to interrupt nucleic acid and synchronize the addition of the linker, eliminating the need to The traditional end-repair, add-on and intermediate purification steps simplify the process and save time.
- the first linker comprises a transposase recognition sequence, typically a well-known 19 bp Me sequence, and the first linker is present in a double-stranded form, wherein one of the strands may have a dideoxy modification at the 3' end, ie, a dideoxynucleoside Acid to prevent self-connection or interconnection between the joints.
- “Self-joining” refers to the connection between different molecules of the same linker, such as the connection between different molecules of the first linker or the connection between different molecules of the second linker; the so-called “interconnect” refers to a different type of linker
- the linkage between molecules such as the linkage between the molecule of the first linker and the molecule of the second linker.
- the sequence of the second linker is not limited and may be any sequence as long as it differs from the sequence of the first linker. Because the second linker is used in the present invention primarily to avoid the effects of a common transposase recognition sequence at both ends. The second linker is ligated to the gap, and then a PCR reaction is carried out by separately targeting the primers that bind the first linker and the second linker to obtain a product in which different linker sequences are respectively ligated to both ends.
- one of the primer pairs used in the first PCR reaction has a first affinity tag at the 5' end, wherein the first affinity tag may be a component of a biologically commonly used biological binding reaction, such as an antigen. Or an antibody, a strand of a short strand of double-stranded DNA, biotin or streptavidin, and the like.
- the second affinity tag selects an antibody that binds to the antigen, and vice versa; in the case where the first affinity tag uses a strand of a double-stranded DNA short segment, The second affinity tag selects another strand that is complementary to the strand, and vice versa; in the case where biotin is selected for the first affinity tag, the second affinity tag selects streptavidin bound to biotin. ,vice versa.
- the first affinity tag is a biotin tag and the second affinity tag is a streptavidin tag, both of which have a strong binding capacity.
- a single-stranded circular "bridge” sequence is a sequence in which a sequence is capable of simultaneously binding to both ends of a single strand, and cyclization of a single strand is achieved by complementary binding to both ends of a single strand. It is called the "bridge” sequence because it bridges the ends of a single chain like a bridge.
- a second PCR reaction is performed using primers that respectively bind to the first linker and the second linker to obtain a product having different linker sequences joined at both ends.
- One of the purposes of this second PCR reaction is to connect a large number of amplified ends A disrupted nucleic acid fragment of the first linker and the second linker.
- the primer pair used in the second PCR reaction can be identical in sequence to the primer pair used in the first PCR reaction, the only difference being that there is no first affinity label in the primer pair used in the second PCR reaction;
- the primer pair used in the first PCR reaction is not exactly the same, such as the outer side (5' end) of the primer pair used in the second PCR reaction, and some base sequences, a typical but non-limiting example is the second One of the primer pairs used in the PCR reaction has a sample tag sequence at the 5' end, and the sample tag sequence may be a random sequence for labeling different samples to simultaneously interrupt, build, and subsequently mix multiple samples.
- the sequences of the different samples can be distinguished because each sample has a specific sample tag sequence at both ends of the interrupted nucleic acid fragment. This greatly improves sequencing efficiency in high-throughput sequencing.
- the second purpose of the second PCR reaction is to add a sample tag sequence to both ends of the interrupted nucleic acid fragment.
- the exon sequence probe is used to capture a single strand of the product of the second PCR reaction containing the exon sequence after the second PCR reaction and prior to the first PCR reaction.
- This embodiment introduces an exon capture technique, which is a well-known technique for obtaining exon sequences in the art, because there are some identical sequences between exons and/or exons and introns (Consensus). Sequence), these consensus sequences are conserved, and by designing exon sequence probes capable of binding these sequences to these sequences, various single strands containing exon sequences can be interrupted from numerous genomic DNAs. The fragments were isolated for exon sequencing. In a specific implementation, it is necessary to perform affinity labeling on the exon sequence probe, such as biotin labeling, and then bind the streptavidin-labeled solid phase vector to separate the fragment containing the exon.
- the single strand of the product obtained by the second PCR reaction is blocked using a primer blocking sequence before the exon sequence probe is used to capture the single strand of the exon sequence in the product of the second PCR reaction.
- primer blocking sequence is capable of specifically binding to the primer sequence at both ends of the product of the second PCR reaction, so that the exon sequence probe can no longer bind to the partial sequence, thereby avoiding the occurrence of false positive results.
- a solid phase carrier for capturing an exon fragment from the product of the second PCR reaction and a solid phase carrier for binding to the product of the first PCR reaction may be a chip or a magnetic bead or the like.
- a second affinity tag is labeled on the chip or magnetic bead and the second affinity tag is capable of binding to the first affinity tag.
- streptavidin-labeled magnetic beads are employed.
- the transposase interrupts the nucleic acid
- magnetic bead purification and column purification are conventional purification methods well known in the art, such as magnetic bead purification using Ampure XP beads, and column purification using a QIAGEN PCR purification column. Needless to say, any similar magnetic bead purification or column purification product can be used in the present invention.
- the advantage of the purification treatment is that the transposase can be completely removed from the system, but the corresponding operations and costs are added in the specific operation.
- transposase to be denatured or digested to dissociate from the target sequence. Since the transposase is chemically a protein, it can be dissociated from the target sequence using the corresponding denaturation or digestion methods. Although the transposase thus treated may still remain in the system, it has been lost. Its biological activity will not adversely affect subsequent reactions.
- the chemical reagent treatment may firstly use a protease solution, a sodium dodecyl sulfate (SDS) solution, and an NT buffer solution (NT buffer buffer matched in the Sup series of the Sup series), etc., to break the target of the transposase and the nucleic acid. Adsorption of the sequence; then the solution containing Triton-X100 is used to attenuate the effect of the above reagents on subsequent enzymatic reactions.
- This method replaces the traditional complex and costly magnetic bead purification or column purification steps, as well as ensuring smooth downstream PCR amplification.
- the denaturation treatment of the PCR product bound to the solid phase support may be carried out by means of thermal denaturation or alkali denaturation, preferably an alkali denaturation mode, such as sodium or potassium hydroxide denaturation, etc., an embodiment of the present invention Denatured with sodium hydroxide.
- a simplified flow of the construction of a nucleic acid single-stranded circular library includes: disrupting genomic DNA using a transposase; amplifying the fragment after PCR and capturing by exon capture technology The exon fragment is further amplified by PCR and isolated to obtain single-stranded DNA; the single strand is cyclized to obtain a nucleic acid single-stranded circular library.
- a detailed flow of the construction of the nucleic acid single-stranded circular library of one embodiment of the present invention includes: using a transposase-embedded complex to interrupt genomic DNA, and the ends of the interrupted DNA are connected to the first linker, and Forming a 9 nt gap; removing the transposase; ligating the second linker; using a primer with a tag sequence (one of the primers) for PCR amplification to obtain an amplified product with a tag sequence; using an exon sequence probe (biotin tag) Capture exon fragments; use biotin-labeled primers (one of which is labeled with one primer) for PCR amplification to obtain a biotin-labeled amplification product in one strand; use streptavidin-labeled magnetic beads to separate the organism with The product of the labeling; denaturation treatment results in a label-free single strand; single-chain cyclization is achieved using a single-stranded circular "
- ligase T4DNA Ligase
- transposase including PCR enzyme
- exonuclease I Exonuclease I
- Exonuclease III was purchased from NEB.
- the technology is developed by using a transposase kit, which comprises two kinds of genomic DNA and 50 ng of genomic DNA.
- the present embodiment uses 50 ng of genome to test.
- Linker sequence A GCTTCGACTGGAGACAGATGTGTATAAGAGACAG (SEQ ID NO: 1);
- Linker sequence B CTGTCTCTTATACACATC ddT (SEQ ID NO: 2).
- the two annealed joints were mixed in equal volume for embedding the transposase complex.
- Method 1 Add SDS at a final concentration of 0.04%-0.1%, mix and then purify with 1.3 times Ampure XP beads; Method 2: Add 1 volume of PBI (Qiagen PCR purification) Kit), after mixing, purified with 1.3 times Ampure XP beads; Method 3 (no purification method): Add SDS at a final concentration of 0.04%-0.1%, and add 0.1% Triton-X100 to the next enzyme reaction.
- the purified product was ligated to the No. 2 linker according to the following system (Table 4), and ligated at 25 ° C for 60 minutes to complete the joint connection.
- Component content water 8 ⁇ L 3 ⁇ connection buffer 20 ⁇ L Connector 2 (5 ⁇ M) 10 ⁇ L Ligase 2 ⁇ L DNA 20 ⁇ L total 30 ⁇ L
- Linker sequence A AGTCGGAGGCCAAGCGGTCGTC (SEQ ID NO: 3);
- Linker sequence B TTGGCCTCCGAC ddT (SEQ ID NO: 4, dd indicates 3'-end dideoxy modification).
- Method 1 purification: 1.3 times Ampure XP beads purification; Method 2 (not purified): The next PCR reaction complements 1% Triton-X100.
- PCR amplification was carried out according to the following system (Table 5) and reaction conditions (Table 6), and 0.1% to 2% of Triton-X100 was added, and this example was preferably 1%.
- Primers 1 with different labels were designed to achieve post-PCR mixing and purification and subsequent region capture. There are 8 different labels in this case.
- tag primers 1-8 are as follows, and the underline sequence is the tag sequence (random sequence):
- Primer 2 (SEQ ID NO: 13): TCCTAAGACCGCTTGGCCTCCGACT
- Blocking sequence #1 and blocking sequence #2 are oligonucleotide sequences (Oligo) in Agilent's kit for blocking some tandem repeat regions in the human genome, and the like.
- Biotin hybridization probes i.e., exon sequence probes referred to elsewhere in the present invention, are used to capture exon single-stranded fragments.
- reaction system was kept at 65 ° C, and 13 ⁇ L of the reaction system 2 was added to the reaction system 1. After mixing, the whole was transferred to the reaction system 3, and the membrane was sealed and hybridized for 24 hours.
- connection buffer 3.7 ⁇ L 20U/ ⁇ L exonuclease I 11.1 ⁇ L 100U/ ⁇ L exonuclease III 5.2 ⁇ L total 20 ⁇ L
- the single base cumulative coverage depth distribution is shown in Figure 5.
- the above results indicate that the nucleic acid single-stranded circular library constructed by the above embodiments of the present invention can be successfully used for sequencing, and the desired results are obtained.
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Abstract
Description
组分 | 含量 |
转座酶 | 85μL |
一号接头 | 30μL |
偶联缓冲液 | 85μL |
合计 | 200μL |
组分 | 含量 |
水 | 5μL |
5×打断缓冲液 | 2μL |
gDNA(50ng/μL) | 1μL |
打断酶复合体 | 2μL |
合计 | 10μL |
组分 | 含量 |
水 | 8μL |
3×连接buffer | 20μL |
二号接头(5μM) | 10μL |
连接酶 | 2μL |
DNA | 20μL |
合计 | 30μL |
组分 | 含量 |
DNA | 30μL |
5×PCR缓冲液 | 10μL |
10mM dNTPs | 1μL |
标签引物1-8 | 2μL |
引物2 | 2μL |
PCR酶 | 1μL |
纯水 | 4μL |
合计 | 50μL |
组分 | 含量 |
DNA | 120μL |
5×PCR缓冲液 | 40μL |
10mM dNTPs | 4μL |
通用引物1 | 8μL |
生物素引物2 | 8μL |
PCR酶 | 4μL |
纯水 | 16μL |
合计 | 200μL |
组分 | 含量 |
“桥”序列 | 20μL |
纯水 | 178.3μL |
10×连接缓冲液 | 35μL |
100mM ATP | 3.5μL |
连接酶 | 1.2μL |
上一步回收的单链DNA | 112μL |
合计 | 350μL |
组分 | 含量 |
10×连接缓冲液 | 3.7μL |
20U/μL外切酶I | 11.1μL |
100U/μL外切酶III | 5.2μL |
合计 | 20μL |
参数 | 数值 |
浓度 | 1.62ng/μL |
体积 | 40μL |
总量 | 64.8ng |
摩尔数 | 0.65pmol |
参数 | 数值 |
覆盖度 | 98.6% |
SNP数目 | 42000 |
dbSNP数据一致性 | 98.65% |
基因分型一致性 | 99.97% |
Claims (14)
- 一种核酸单链环状文库的构建方法,包括如下步骤:使用转座酶包埋复合体对核酸进行随机打断,其中所述转座酶包埋复合体包含转座酶和含转座酶识别序列的第一接头,打断的核酸两端连接所述第一接头并且形成缺口;去除体系中的转座酶,然后使用连接酶在所述缺口处连接上第二接头,所述第二接头的序列不同于所述第一接头;使用分别靶向结合所述第一接头和所述第二接头的引物进行第一PCR反应,得到两端分别连接有不同接头序列的产物,其中一条引物在5’端具有第一亲和标记;将所述第一PCR反应的产物与具有第二亲和标记的固相载体接触,使所述第一亲和标记与所述第二亲和标记形成亲和结合;对结合到所述固相载体上的PCR产物进行变性处理,分离出无亲和标记的单链;使用单链环化“桥”序列对所述单链进行环化,其中所述单链环化“桥”序列能够同时结合所述单链的两端。
- 根据权利要求1所述的方法,其特征在于,在所述第一PCR反应之前,使用分别靶向结合所述第一接头和所述第二接头的引物进行第二PCR反应,得到两端分别连接有不同接头序列的产物。
- 根据权利要求2所述的方法,其特征在于,所述第二PCR反应使用的引物对中有一条引物在5’端具有样本标签序列。
- 根据权利要求2或3所述的方法,其特征在于,在所述第二PCR反应之后且在所述第一PCR反应之前,使用外显子序列探针捕获所述第二PCR反应的产物中含有外显子序列的单链,其中所述外显子序列探针具有所述第一亲和标记,能够与所述固相载体上的第二亲和标记形成亲和结合,而将所述含有外显子序列的单链分离出来,以用于进行第一PCR反应。
- 根据权利要求4所述的方法,其特征在于,在使用外显子序列探针捕获所述第二PCR反应的产物中含有外显子序列的单链之前,使用引物封闭序列封闭所述第二PCR反应得到的产物单链两端的引物序列。
- 根据权利要求1所述的方法,其特征在于,所述第一亲和标记为生物素标记;所述第二亲和标记为链霉亲和素标记。
- 根据权利要求1所述的方法,其特征在于,所述去除体系中的转座酶采用磁珠纯化、过柱纯化或化学试剂处理的方式进行。
- 根据权利要求1所述的方法,其特征在于,所述固相载体为磁珠。
- 根据权利要求1所述的方法,其特征在于,所述方法包括如下步骤:使用转座酶包埋复合体对核酸进行随机打断,其中所述转座酶包埋复合体包含转座酶和含转座酶识别序列的第一接头,打断的核酸两端连接所述第一接头并且形成缺口;去除体系中的转座酶,然后使用连接酶在所述缺口处连接上第二接头,所述第二接头的序列不同于所述第一接头;使用分别靶向结合所述第一接头和所述第二接头的引物进行第二PCR反应,得到两端分别连接有不同接头序列的产物,其中一条引物在5’端具有样本标签序列;使用引物封闭序列封闭所述第二PCR反应得到的产物单链两端的引物序列;使用外显子序列探针捕获所述第二PCR反应的产物中含有外显子序列的单链,其中所述外显子序列探针具有生物素标记,能够与固相载体上的链霉亲和素标记形成亲和结合,而将所述含有外显子序列的单链分离出来;使用针对所述含有外显子序列的单链两端的引物进行第一PCR反应,得到两端分别连接有不同接头序列的产物,其中一条引物在5’端具有生物素标记;将所述第一PCR反应的产物与具有链霉亲和素标记的固相载体接触,使所述生物素标记与所述链霉亲和素标记形成亲和结合;对结合到所述固相载体上的PCR产物进行变性处理,分离出无亲和标记的单链;使用单链环化“桥”序列对所述单链进行环化,其中所述单链环化“桥”序列能够同时结合所述无亲和标记的单链的两端。
- 一种核酸单链环状文库的构建试剂,包括如下组成部分:转座酶和含转座酶识别序列的第一接头,用于形成转座酶包埋复合体以对核酸进行随机打断,在打断的核酸两端连接所述第一接头并且形成缺口;第二接头和连接酶组分,用于在所述缺口处连接上第二接头;用于第一PCR反应的引物,其中一条引物在5’端具有第一亲和标记,所述 引物分别靶向结合所述第一接头和所述第二接头;固相载体,具有第二亲和标记,用于与所述第一亲和标记形成亲和结合;变性溶液,用于对结合到所述固相载体上的PCR产物进行变性处理,以分离出无亲和标记的单链;单链环化“桥”序列,能够同时结合所述单链的两端,用于对所述单链进行环化。
- 根据权利要求10所述的试剂,其特征在于,所述试剂还包括用于第二PCR反应的引物,用于分别靶向结合所述第一接头和所述第二接头;优选地,所述用于第二PCR反应的引物中有一条引物在5’端具有样本标签序列。
- 根据权利要求10或11所述的试剂,其特征在于,所述试剂还包括外显子序列探针,用于捕获所述第二PCR反应的产物中含有外显子序列的单链,所述外显子序列探针具有所述第一亲和标记,能够与所述固相载体上的第二亲和标记形成亲和结合,而将所述含有外显子序列的单链分离出来;优选地,所述试剂还包括引物封闭序列,用于封闭所述第二PCR反应得到的产物单链两端的引物序列。
- 根据权利要求10所述的试剂,其特征在于,所述第一亲和标记为生物素标记;所述第二亲和标记为链霉亲和素标记。
- 根据权利要求10所述的试剂,其特征在于,所述固相载体为磁珠。
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