CN112322637B - Internal reference gene TIP41 of glehnia littoralis and screening method and application thereof - Google Patents

Internal reference gene TIP41 of glehnia littoralis and screening method and application thereof Download PDF

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CN112322637B
CN112322637B CN202011351913.XA CN202011351913A CN112322637B CN 112322637 B CN112322637 B CN 112322637B CN 202011351913 A CN202011351913 A CN 202011351913A CN 112322637 B CN112322637 B CN 112322637B
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李莉
周义峰
李乃伟
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Abstract

The invention discloses an internal reference gene of glehnia littoralis and a screening method and application thereof, belonging to the technical field of plant genetic engineering. In particular to an internal reference gene of glehnia littoralis and a primer thereof, wherein the internal reference gene is TIP41-like; and provides a real-time fluorescent quantitative PCR screening method of internal reference genes of glehnia littoralis, and fills the blank that the research field of the glehnia littoralis lacks suitable and universal internal reference genes.

Description

Internal reference gene TIP41 of glehnia littoralis and screening method and application thereof
The application is a divisional application;
filing date of original application: 2019-07-22;
application No.: CN201910659220.8;
the invention creates the name: internal reference gene of glehnia littoralis and screening method and application thereof;
Technical Field
The invention belongs to the technical field of plant genetic engineering, and particularly relates to an internal reference gene of glehnia littoralis, a screening method and application thereof.
Background
Glehnia littoralis, an umbelliferae perennial, is a basic source plant of the traditional Chinese medicinal material radix glehniae in China. Radix glehniae, ginseng, radix scrophulariae, salvia miltiorrhiza and codonopsis pilosula are called as Wushen which has the effects of nourishing yin to clear away the lung-heat, tonifying the stomach and promoting the production of body fluid and is mainly used for treating diseases such as lung heat, yin deficiency, dry cough, stomach dryness, throat dryness, thirst and the like, are commonly used in clinical and health care, and tender leaves on the overground part can be eaten as vegetables, so that the economic value is high.
The glehnia littoralis grows naturally in coastal sandy beach zones, is a genuine medicinal material production area of glehnia littoralis in coastal provinces of China, such as Liaoning, jiangsu, shandong, zhejiang, fujian, guangdong and Hainan, and is an important source area of glehnia littoralis commercial medicinal materials. However, due to the reasons of coastal development and the like, the range of the coastal-road production area of the glehnia littoralis is gradually reduced and even disappears; in recent years, with the development and utilization of new coastal reclamation lands in China, space and opportunity are provided for the scale recovery of coastal-way production areas of corals, however, the salt tolerance is insufficient due to long-term inland cultivation and artificial seed selection of the existing main planting of corals, and the difficulty in the recovery planting of coastal saline-alkali lands is great, so that the research on salt tolerance mechanisms of corals is urgently needed.
In addition, the mechanism of the authentic formation of the glehnia littoralis medicinal material is not clear, and the specific coastal high-salt living environment is probably an important reason for influencing the accumulation of the effective components of the glehnia littoralis and the authentic formation of the medicinal material, so that the specific influence mechanism has great research significance. In order to solve the above two problems, research on various aspects of salt tolerance mechanism, breeding, anabolism mechanism of active ingredients and the like of glehnia littoralis is inevitable, and research on the field of plant molecular biology of the glehnia littoralis is required.
Gene expression analysis is one of important means in the research of plant molecular biology field, and is important in the aspects of searching plant related genes and regulation and control mechanisms, revealing plant elegance and the like. In the study of gene expression level, reference genes are required to be used as references, such as a real-time fluorescent Quantitative PCR (qRT-PCR) technology, and in order to obtain more accurate and reliable results, the reference genes are required to carry out standardized measurement on the expression level of target genes.
When the relative quantitative expression of genes is analyzed through qRT-PCR, in order to eliminate the influence of the difference of initial templates and the difference of reverse transcription efficiency of different samples, a stable reference gene needs to be introduced to correct the expression result. The internal reference genes are various housekeeping genes, and are stably expressed in the intracellular composition and help to maintain the functions of the cells. The ideal reference gene should satisfy the following conditions: 1) The absence of pseudogenes (pseudogenes) to avoid non-specific amplification of gene DNA; 2) High or moderate expression, excluding low expression; 3) Stably expresses in different types of cells and tissues (such as normal cells and cancer cells), and the expression quantity is approximate without significant difference; 4) The expression level is independent of the cell cycle and whether the cells are activated; 5) The stable expression level is similar to that of the target gene; 6) Is not affected by any endogenous or exogenous factors, such as any experimental treatment measures. As reference genes, 18S rRNA, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), actin (Actin), etc., are commonly used in plants. However, perfect reference genes almost do not exist, most reference genes are not constantly expressed in different environmental conditions, different developmental stages and tissues and organs, and can only be relatively stable within a certain test range, and meanwhile, different plants have the most suitable reference genes, and the stability of the reference genes of different tissues of the same plant is different. Therefore, the selection of a suitable reference gene for normalization under a particular test condition and sample type is critical to obtain accurate gene expression results, since blindly using a gene as a reference gene in any test condition directly affects the reliability of the results of the study and even results with errors.
Meanwhile, when analyzing gene expression, more and more researchers tend to choose a research method of jointly correcting a plurality of reference genes, for example, two or more stable reference genes are arranged, the obtained results are homogenized, and the target gene is corrected, so that experimental errors can be reduced, and the reliability of the research results is increased. For example, in the study of expression of BAHD acyltransferase in rice, the investigator evaluated five reference genes and finally determined that the two most stable reference genes Ubq5 and Cc55 were used together for the fluorescent quantitative PCR results correction (Bartley LE et al. Overexpression of a BAHD acyltransferase, osAt10, altera cell wall hydrolytic acid content and amplification. Plant physiology.2013, 161: 1615-1633). Similarly, in the expression analysis of the HKTS family of potassium channel genes, researchers have applied two internal reference genes UBQ5 and 18sRNA simultaneously to correct for increased stability of results (Wang R, sting W, xiao L, jin Y, shen L, zhang W. The rice high-affinity site transporter1;1is included in the dissolved and regulated by an MYB-type transport vector. Plant physiology. 2015,168 (3): 1076-90). Therefore, after screening reference genes according to specific experimental conditions and samples and evaluating stability, the reference genes with stability in the prostate are evaluated, and the method has important use value in multi-reference correction. At present, no research report on the development, screening and stability verification of the internal reference genes of glehnia littoralis exists, and for the reasons, the development of the stable internal reference genes and primers of the internal reference genes of the glehnia littoralis has important practical application value in the molecular biology research of the glehnia littoralis and the research of the Umbelliferae plants.
Disclosure of Invention
1. Problems to be solved
Aiming at the lack of an effective means for carrying out related gene expression analysis on glehnia littoralis in the prior art, the invention provides an internal reference gene of the glehnia littoralis, a screening method and application thereof; through a glehnia littoralis transcriptome sequencing database, internal reference gene development is carried out, four different experimental treatment conditions are selected for stability screening and verification, and the method is suitable for stable internal reference genes and primers thereof under the treatment research of salt stress, drought stress, abscisic acid (ABA) and methyl jasmonate (MeJA) of glehnia littoralis.
2. Technical scheme
In order to solve the problems, the technical scheme adopted by the invention is as follows:
internal reference genes of glehnia littoralis, wherein the internal reference genes are TIP41-like; the nucleotide sequence of the TIP41-like is SEQ ID NO.11.
PCR primers for amplifying the above-mentioned reference genes.
Preferably, the amplified fragment size of the primer is 100-250 bp.
Preferably, the primer pair sequence for amplifying TIP41-like is SEQ ID NO.35/SEQ ID NO.36.
The real-time fluorescent quantitative PCR screening method of the internal reference gene of the glehnia littoralis comprises the following steps:
(1) Selecting root tissue samples of 4 template glehnia littoralis treated by salt stress, drought stress, abscisic acid and methyl jasmonate respectively;
(2) Screening out internal reference genes of the glehnia littoralis by using transcriptome sequencing data of the glehnia littoralis;
(3) Designing a reference gene primer of real-time fluorescent quantitative PCR by taking the selected reference gene sequence as a template;
(4) Carrying out real-time fluorescence quantitative PCR; and performing statistical analysis on the obtained real-time fluorescent quantitative PCR data through four statistical software of delta Ct, geNorm, normFinder and BestKeeper to respectively screen out the optimal reference gene and reference gene combination, and performing comprehensive ranking analysis through comprehensive analysis software RankAggreg R. It should be noted that, the step (1) may be located after the step (2) or after the step (3); however, step (1) must precede step (4).
Preferably, before the real-time fluorescent quantitative PCR in the step (4) is performed, the specificity of the primers of the internal reference gene is identified by ordinary PCR (using DNA polymerase: green Taq Mix; identification conditions: 95 ℃ 3min,95 ℃ 15s,56 ℃ 15s,72 ℃ 60s/kb,30 cycles; 72 ℃ 5min, supplied by Nanjing Homopsin Biotech, ltd.).
Preferably, in the step (4), the real-time fluorescent quantitative PCR amplification procedure is: pre-denaturation at 95 ℃ for 5min; denaturation at 95 ℃ for 15s, annealing at 60 ℃ for 15s, extension at 72 ℃ for 25s, and 40 cycles were run.
Preferably, in the step (4), the obtained real-time fluorescent quantitative PCR data is subjected to statistical analysis through four statistical software, namely delta Ct, geNorm, normFinder and BestKeeper, so as to respectively screen out the optimal reference genes and reference gene combinations, and then comprehensive ranking analysis is performed through comprehensive analysis software RankAggreg R.
Preferably, the real-time fluorescent quantitative PCR screening method of the internal reference gene of the glehnia littoralis comprises the following specific steps:
1) The material and the processing method are as follows: selecting sandculture glehnia littoralis with consistent growth vigor, and respectively carrying out salt stress, drought stress, abscisic acid and methyl jasmonate treatment on different glehnia littoralis by utilizing a NaCl solution with the concentration of 200mM, a PEG (polyethylene glycol) 6000 solution with the mass concentration of 20%, an ABA (abscisic acid) solution with the mass concentration of 100 mu M and a methyl jasmonate solution with the mass concentration of 100 mu M to obtain a template glehnia littoralis; sampling the root of each template glehnia littoralis at three time points of which the processing time is 0h, 6h and 24h, and performing three biological repeated samplings on the glehnia littoralis at each time point;
2) RNA extraction and detection: washing all root tissue samples of the glehnia littoralis by using deionized water, drying by using absorbent paper, and quickly freezing by using liquid nitrogen; extracting RNA of the root tissue sample of the glehnia littoralis by using a Trizol Reagent (Takara) kit (the extraction mode is consistent with the content in the kit specification); detecting the integrity of the extracted RNA by electrophoresis, carrying out electrophoresis on the RNA for 10min by using 1% agarose gel and TAE buffer solution under the voltage of 170V, and observing and analyzing by using a gel imaging system; performing purity detection (OD 260/280 of pure RNA is between 1.8 and 2.2) and concentration quantification on the extracted RNA by using NanoDrop ND-2000;
3) RNA reverse transcription to synthesize cDNA: collecting 0.5-1 μ g RNA sample of Eucheuma Gelatinosum with reverse transcription kit PrimeScript TM The RT reagent Kit carries out reverse transcription reaction on RNA with g DNA Eraser (Perfect Real Time);
4) Screening candidate reference genes: screening candidate internal reference genes of the coralline vegetable for stability analysis by using coralline vegetable transcriptome sequencing data and referring to gene homology of a model plant Arabidopsis thaliana;
5) Designing and detecting a specific primer: designing an internal reference gene Primer for real-time fluorescence quantitative PCR by using the screened candidate internal reference gene sequence as a template and using a site Primer 3web (http:// Primer3.Ut. Ee /);
the specificity of the primer is preliminarily identified by common PCR by taking cDNA obtained by reverse transcription of a template glehnia littoralis as a template.
6) Establishing a reference gene primer standard curve: establishing a standard curve of each internal reference gene primer: diluting cDNA obtained by reverse transcription into 6 concentration gradients (1, 1/5, 1/25, 1/125, 1/625 and 1/3125) as templates for establishing a standard curve; carrying out real-time fluorescent quantitative PCR by taking the primer as a guide;
7) Fluorescent quantitative PCR amplification: carrying out real-time fluorescence quantitative PCR amplification on the internal reference gene by taking cDNA obtained by reverse transcription as a template to obtain a corresponding Ct value; the amplification procedure was: pre-denaturation at 95 ℃ for 5min; denaturation at 95 ℃ for 15s, annealing at 60 ℃ for 15s, extension at 72 ℃ for 25s, and running for 40 cycles; drawing a standard curve by using the obtained fluorescent quantitative PCR result to obtain the amplification efficiency and the slope of each candidate gene, wherein the primer amplification efficiency of the candidate reference gene is 88-108%;
8) Analyzing the stability of the reference gene by using four statistical analysis methods of delta Ct, geNorm, normFinder and BestKeeper;
9) Carrying out comprehensive statistical ranking on the candidate internal reference gene stability ranking obtained by the four statistical analysis methods by utilizing a RankAggreg R program package to obtain a comprehensive result;
10 Utilize 2 -ΔΔCt The method comprises analyzing and verifying target gene expression amount of reference gene, wherein the expression amount of the reference gene is delta Ct = Ct (target gene) -Ct (reference gene), the expression amount of the reference gene is delta Ct = delta Ct (treatment) -delta Ct (control), and the expression amount of the reference gene is 2 -ΔΔCt = relative expression amount.
The application of the internal reference gene of the glehnia littoralis in researching the expression level of the target gene of the glehnia littoralis.
3. Advantageous effects
Compared with the prior art, the invention has the beneficial effects that:
(1) In the face of the current situation that the salt tolerance mechanism, breeding, anabolism mechanism of active ingredients and other aspects of the glehnia littoralis are urgently needed to be researched in the existing glehnia littoralis industry, and the gene expression of different parts, different tissues and different conditions of the glehnia littoralis is analyzed by utilizing PCR (polymerase chain reaction), an inventor screens a plurality of candidate internal reference genes from glehnia littoralis species and discloses an internal reference gene sequence; fills the blank that the coral vegetable research field lacks suitable and universal reference genes;
(2) According to the invention, a plurality of internal reference genes are screened from the glehnia littoralis species, and the real-time fluorescent quantitative PCR primer is designed according to the screening, so that the verified primer has high amplification efficiency and strong specificity (see table 1 and figure 1 for details), the blank that a proper and universal internal reference gene is lacked in the research field of the glehnia littoralis is filled, the blank that a proper fluorescent quantitative PCR primer is lacked in the research field of the glehnia littoralis is also filled, and an effective internal reference gene correction tool is provided for the analysis, screening and verification work of the gene expression of the glehnia littoralis in the future.
(3) Aiming at the research blank of the stable reference gene of the coral vegetable species, the invention screens the reference gene on the basis of transcriptome data, and analyzes and comprehensively compares the stability of the reference gene by utilizing various statistical methods; different treatment conditions are set, such as salt stress, drought stress and hormone stress, so that the requirements of most physiological researches can be met; the material is the medicinal active part, so that the research is more targeted; under the conditions of salt stress, drought stress and abscisic acid treatment, the TIP41-like stability is thirty percent of the first percent of the sequence of the selected genes, belongs to the reference genes with good stability (see the attached figure 4 in detail), meets the requirements of real-time fluorescence quantitative detection of the expression level of the glehnia littoralis genes under the conditions of the salt stress, the drought stress and the abscisic acid treatment, has good correction capability, can be independently used as the reference genes by researchers in the stress treatment research, can also be combined with other reference genes with better stability to jointly correct the expression quantity of target genes, can be selectively used by the researchers according to actual requirements to obtain stable and reliable results, improves the working efficiency of scientific research, reduces the cost and can further ensure the stability, the reliability and the repeatability of the research results.
(4) The reference gene provided by the invention can also provide reference value for the research of other plants in the Umbelliferae.
Drawings
FIG. 1is a sequence electrophoresis diagram obtained by using Eucheuma Gelatinosum cDNA as template for amplification of multiple primers provided by the present invention; m: the DNA Marker comprises 2000bp, 1000bp, 750bp, 500bp, 250bp and 100bp in sequence from top to bottom; the genes represented by the numbers from 1 to 13 are respectively PP2A, UBQ10, ACT, EF 1-alpha, GAPDH, alpha-TUB, beta-TUB, PTBP1, EXP2, TIP41-like, SAND family and CYP2;
FIG. 2 is a Ct value distribution diagram of fluorescent quantitative PCR of a plurality of reference genes;
FIG. 3 is a graph of the ranking of the expression stability values (M) of a plurality of candidate reference genes using GeNorm software, the lower the M value, the more stable the gene; wherein FIG. 3A shows NaCl treatment conditions; FIG. 3B shows PEG treatment conditions; FIG. 3C depicts ABA treatment conditions; FIG. 3D shows MeJA processing conditions;
FIG. 4 is a graph of the rankings obtained by the four statistical analysis methods using the RankAggreg R package to obtain a composite ranking; FIG. 4A shows NaCl treatment conditions; FIG. 4B shows PEG treatment conditions; FIG. 4C depicts ABA treatment conditions; FIG. 4D shows MeJA processing conditions;
FIG. 5 shows the effect of the candidate reference gene of the present invention in application, which is verified by analyzing the change in the expression level of the target PYL gene of Eucheuma Gelatinosum under four stress treatments; FIG. 5A shows NaCl treatment conditions; FIG. 5B shows PEG treatment conditions; FIG. 5C depicts ABA treatment conditions; fig. 5D shows MeJA processing conditions.
Detailed Description
Herein, the following: the coral vegetable transcriptome sequencing data are as follows: reference Li L, li M, qi X, tang X, zhou y.de novo transcription sequencing and analysis of genes related to stress response in glehnial littoralis. Peerj.2018, 6;
Δ Ct references described herein: silver N, best S, jiang J, the in SL.selection of household eating genes for gene expression study of real-time PCR.BMC Mol biol.2006;7, 33;
GeNorm reference: vandesoplex J, de Preter K, pattyn F, poppe B, van Roy N, paepe A, et al, accurate normalization of real-time quantitative RT-PCR data by geometrical averaging of multiple internal control genes, genome biol.2002;3, and (3);
NormFinder reference: andersen CL, jensen JL,
Figure BDA0002801541580000041
TF.Normalization of real-time quantitative reverse transcription-PCR data:a model-based variance estimation approach to identify genes suited for normalization, applied to bladder and colon cancer data sets.Cancer Res.2004;64:5245–5250;
BestKeeper reference: pfaffl MW, tiChopad A, prgomet C, neuvians TP. Determination of stable housekeeping genes, differentiated regulated target genes and sample integration BestKeeper-Excel-based tool using pair-wise corerrelations Biotechnol Lett.2004; 26;
see rank agreg R package: pihur V, dattaS, datta s.rank aggregate, an R package for weighted rank aggregation, BMC Bioinformatics 2009, 10;
biological replicates described herein: each individual coral vegetable is repeated;
the invention is further described with reference to specific examples.
Example 1
This example shows the internal reference gene of Eucheuma Gelatinosum of the present invention. Provides a plurality of internal reference genes of glehnia littoralis as follows: PP2A (protein phosphatase 2), UBQ10 (ubiquitin 10), ACT (actin), EF1- α (elongation factor), GAPDH (glyceraldehyde-3-phosphate dehydrogenase), α -TUB (α -tubulin), β -TUB (β -tubulin), PTBP1 (polypyrimidine sequence binding protein), EXP1 (expansin 1), EXP2 (expansin 2), TIP41-like (TIP 41-like protein), SAND family protein, CYP2 (cyclophilin); the nucleotide sequence of the PP2A is SEQ ID NO.1; the nucleotide sequence of UBQ10 is SEQ ID NO.2; the nucleotide sequence of the ACT is SEQ ID NO.3; the nucleotide sequence of the EF 1-alpha is SEQ ID NO.4; the nucleotide sequence of the GAPDH is SEQ ID NO.5; the nucleotide sequence of the alpha-TUB is SEQ ID NO.6; the nucleotide sequence of the beta-TUB is SEQ ID NO.7; the nucleotide sequence of the PTBP 1is SEQ ID NO.8; the nucleotide sequence of the EXP 1is SEQ ID NO.9; the nucleotide sequence of the EXP2 is SEQ ID NO.10; the nucleotide sequence of the TIP41-like is SEQ ID NO.11; the nucleotide sequence of the SAND family is SEQ ID NO.12; the nucleotide sequence of the CYP2 is SEQ ID NO.13.
Example 2
In this example, fluorescent quantitative PCR primers for amplifying the reference gene of example 1 were provided,
the amplified fragment size of the primer is 100-250 bp.
The sequence of a primer pair for amplifying the PP2A is SEQ ID NO.15/SEQ ID NO.16; the sequence of a primer pair for amplifying UBQ10 is SEQ ID NO.17/SEQ ID NO.18; the sequence of a primer pair for amplifying the ACT is SEQ ID NO.19/SEQ ID NO.20; the sequence of a primer pair for amplifying EF 1-alpha is SEQ ID NO.21/SEQ ID NO.22; the sequences of the primer pairs for amplifying GAPDH are SEQ ID NO.23/SEQ ID NO.24; the sequence of a primer pair for amplifying alpha-TUB is SEQ ID NO.25/SEQ ID NO.26; the sequence of a primer pair for amplifying the beta-TUB is SEQ ID NO.27/SEQ ID NO.28; the sequence of a primer pair for amplifying the PTBP 1is SEQ ID NO.29/SEQ ID NO.30; the sequences of the primer pairs for amplifying the EXP1 are SEQ ID NO.31/SEQ ID NO.32; the sequences of the primer pair for amplifying the EXP2 are SEQ ID NO.33/SEQ ID NO.34; the sequence of a primer pair for amplifying TIP41-like is SEQ ID NO.35/SEQ ID NO.36; the sequence of a primer pair for amplifying the SAND family is SEQ ID NO.37/SEQ ID NO.38; the sequences of the primer pair for amplifying CYP2 are SEQ ID NO.39/SEQ ID NO.40.
Example 3
The embodiment provides a real-time fluorescent quantitative PCR method for screening the internal reference gene of the glehnia littoralis, which comprises the following steps: (1) Selecting root tissue samples of the glehnia littoralis which are respectively subjected to salt stress, drought stress, abscisic acid and methyl jasmonate treatment;
(2) Screening out candidate internal reference genes of the glehnia littoralis by using transcriptome sequencing data of the glehnia littoralis;
(3) Selecting candidate internal reference genes as templates (namely PP2A, UBQ10, ACT, EF 1-alpha, GAPDH, alpha-TUB, beta-TUB, PTBP1, EXP2, TIP41-like, SAND family and CYP2; the specific sequences can be seen in sequence tables SEQ ID NO. 1-SEQ ID NO. 13), and designing and obtaining primers of real-time fluorescence quantitative PCR of each internal reference gene (see the embodiment 2 for details);
(4) And (3) performing real-time fluorescent quantitative PCR, performing statistical analysis on the obtained real-time fluorescent quantitative PCR data (Ct value), and screening out the optimal reference gene.
Example 4
This example differs from example 3 only in that: the step (1) is positioned after the step (2).
Example 5
This example differs from example 3 only in that: the step (1) is positioned after the step (3).
Example 6
This example differs from example 3 only in that: the step (1) is a material and processing method: selecting sand-cultured glehnia littoralis with consistent growth vigor, and respectively treating different glehnia littoralis with a NaCl solution with the concentration of 200mM, a PEG 6000 solution with the mass concentration of 20%, an ABA solution with the mass concentration of 100 mu M and a methyl jasmonate solution with the mass concentration of 100 mu M to obtain a template glehnia littoralis; the root of each template glehnia littoralis was sampled at three time points at treatment times of 0h, 6h, and 24h, and three biological replicates were sampled at each time point.
Example 7
The real-time fluorescent quantitative PCR screening method of the internal reference gene of the glehnia littoralis provided in the embodiment comprises the following steps: (1) Selecting root tissue samples of the glehnia littoralis which are respectively treated by salt stress, drought stress, abscisic acid and methyl jasmonate;
(2) Screening out internal reference genes of the glehnia littoralis by using transcriptome sequencing data of the glehnia littoralis;
(3) The method comprises the following steps of (1) designing and obtaining a primer of real-time fluorescence quantitative PCR of each reference gene by taking the selected reference gene as a template (namely PP2A, UBQ10, ACT, EF 1-alpha, GAPDH, alpha-TUB, beta-TUB, PTBP1, EXP2, TIP41-like, SAND family and CYP2; the specific sequence can be shown in a sequence table SEQ ID NO. 1-SEQ ID NO. 13) (see an example 2 for details);
(4) Preliminarily identifying the specificity of the reference gene primer by common PCR;
using a DNA polymerase provided by tokyo kezan biotechnology limited: green Taq Mix; identification conditions: 95 ℃ 3min,95 ℃ 15s,56 ℃ 15s,72 ℃ 60s/kb, for 30 cycles; 5min at 72 ℃;
(5) And (3) performing real-time fluorescent quantitative PCR, performing statistical analysis on the obtained real-time fluorescent quantitative PCR data (Ct value), and screening out the optimal reference gene.
Example 8
This example differs from example 1 in that: the step (4) is as follows: carrying out real-time fluorescence quantitative PCR; carrying out quantitative analysis on the obtained real-time fluorescence quantitative PCR data through a standard curve, and screening out an optimal reference gene and an optimal reference gene combination;
wherein, the real-time fluorescent quantitative PCR amplification procedure comprises the following steps: pre-denaturation at 95 ℃ for 5min; denaturation at 95 ℃ for 15s, annealing at 60 ℃ for 15s, and extension at 72 ℃ for 25s, and 40 cycles were run.
Example 9
The embodiment provides a method for screening the stability of an internal reference gene of glehnia littoralis, which comprises the following specific steps:
1) The material and the processing method are as follows: selecting sand-cultured glehnia littoralis with consistent growth vigor, and respectively treating different glehnia littoralis with a NaCl solution with the concentration of 200mM, a PEG 6000 solution with the mass concentration of 20%, an ABA solution with the mass concentration of 100 mu M and a methyl jasmonate solution with the mass concentration of 100 mu M to obtain a template glehnia littoralis;
the roots of each template glehnia littoralis were sampled at three time points at treatment times of 0h, 6h, and 24h, and three biological replicates (one replicate per individual) were sampled at each time point.
2) RNA extraction and detection: washing the extracted root (medicinal part) tissue sample of the glehnia littoralis with deionized water, drying with absorbent paper, and quick freezing with liquid nitrogen; extracting RNA of a root tissue sample of the glehnia littoralis by using a Trizol Reagent (Takara) kit (the extraction mode is consistent with the content in the kit instruction);
detecting the integrity of the extracted RNA by electrophoresis, carrying out electrophoresis for 10min on 1% agarose gel and TAE buffer solution under the voltage of 170V, observing by using a gel imaging system, and analyzing; performing purity detection (OD 260/280 of pure RNA is between 1.8 and 2.2) and concentration quantification on the extracted RNA by using NanoDrop ND-2000;
3) Synthesizing cDNA by RNA reverse transcription: 0.5-1. Mu.g of RNA sample was sampled using reverse transcription kit PrimeScript TM The RT reagent Kit carries out reverse transcription on RNA with g DNA Eraser (Perfect Real Time) to obtain cDNA.
4) Screening candidate reference genes: screening candidate internal reference genes of the glehnia littoralis for stability analysis by using sequencing data of a glehnia littoralis transcriptome and referring to gene homology of a model plant arabidopsis thaliana;
5) Designing and detecting a specific primer: designing an internal reference gene Primer for real-time fluorescence quantitative PCR by using the screened internal reference gene as a template and using a site Primer3 (http:// Primer3.Ut. Ee /);
the primer specificity was identified by ordinary PCR using cDNA obtained by reverse transcription as a template, and a DNA polymerase provided by Biotech Ltd of Nanjing Novozam was used: green Taq Mix; identification conditions: 95 ℃ 3min,95 ℃ 15s,56 ℃ 15s,72 ℃ 60s/kb, for 30 cycles; 5min at 72 ℃.
6) Establishing a reference gene primer standard curve: establishing a standard curve of each reference gene primer: diluting cDNA obtained by reverse transcription into 6 concentration gradients (1, 1/5, 1/25, 1/125, 1/625 and 1/3125) as templates for establishing a standard curve; performing real-time fluorescent quantitative PCR by taking the primer as a guide, and drawing a standard curve;
7) And (3) PCR amplification: carrying out real-time fluorescent quantitative PCR amplification on the internal reference gene by taking cDNA obtained by reverse transcription as a template to obtain a corresponding Ct value;
the amplification procedure was: pre-denaturation at 95 ℃ for 5min; denaturation at 95 ℃ for 15s, annealing at 60 ℃ for 15s, extension at 72 ℃ for 25s, and running for 40 cycles; and (3) obtaining the amplification efficiency and the slope of each candidate gene by using the obtained data result, wherein the amplification efficiency of the primers is between 88 and 108 percent.
8) Analyzing the stability of the reference gene by using four statistical analysis methods of delta Ct, geNorm, normFinder and BestKeeper;
9) Carrying out comprehensive statistical ranking on the candidate internal reference gene stability ranking obtained by the four statistical analysis methods by utilizing a RankAggreg R program package to obtain a comprehensive result;
10 Utilize 2 -ΔΔCt The method comprises analyzing and verifying target gene expression amount of reference gene, wherein the expression amount of the reference gene is delta Ct = Ct (target gene) -Ct (reference gene), the expression amount of the reference gene is delta Ct = delta Ct (treatment) -delta Ct (control), and the expression amount of the reference gene is 2 -ΔΔCt = relative expression amount.
Example 10
This example shows the development and screening process of the candidate internal reference genes of glehnia littoralis and the stability evaluation of the candidate internal reference genes under different stress treatments. The germplasm resource of the template glehnia littoralis in the embodiment is from Fujian plain pond coastal, and is cultivated in a germplasm resource garden of the plant institute of Chinese academy of sciences of Jiangsu province, namely Nanjing Zhongshan;
(1) The material and the processing method are as follows:
early-stage treatment: collecting coral vegetable seedlings (the underground part is about 3-6cm in length) in a nursery, transplanting the coral vegetable seedlings into a flowerpot cleaned with river sand, irrigating a Hoagland nutrient solution, culturing in a light incubator at the temperature of 26 ℃ and 22 ℃ respectively, for 14h/10h, for day and night circulation and at the relative humidity of 75%, and culturing for three months;
sampling: selecting sand-cultured glehnia littoralis with consistent growth vigor, and respectively treating different glehnia littoralis with a NaCl solution with the concentration of 200mM, a PEG 6000 solution with the mass concentration of 20%, an ABA solution with the mass concentration of 100 mu M and a methyl jasmonate solution with the mass concentration of 100 mu M to obtain a template glehnia littoralis;
sampling the root of each template glehnia littoralis at three time points of 0h, 6h and 24h of processing time, performing three times of biological repeated sampling (one is repeated for each single plant) on the glehnia littoralis at each time point, washing the collected root tissue sample of the template glehnia littoralis by using deionized water, drying the sample by using absorbent paper, quickly freezing the sample by using liquid nitrogen, and placing the sample in a refrigerator at the temperature of-80 ℃ for extracting RNA;
(2) RNA extraction and cDNA synthesis: extracting RNA of root tissue samples of 4 different templates of glehnia littoralis by using a Trizol Reagent (Takara) kit (the extraction mode is consistent with the content in the kit specification);
detecting the integrity of the extracted RNA by electrophoresis, carrying out electrophoresis on the RNA for 10min by using 1% agarose gel and TAE buffer solution under the voltage of 170V, observing by using a gel imaging system, and analyzing; performing purity detection (OD 260/280 of pure RNA is between 1.8 and 2.2) and concentration quantification on the extracted RNA by using NanoDrop ND-2000;
(3) Mu.g of RNA sample was sampled using reverse transcription kit PrimeScript TM The RT reagent Kit with gDNA Eraser (Perfect Real Time) performs reverse transcription to obtain cDNA (the reverse transcription mode is consistent with the content in the Kit instruction).
(4) Internal reference gene screening and specific primer design: according to the obtained coralline transcriptome sequencing database information of the research team, the gene homology of a model plant Arabidopsis is referred, and the homologous gene in the coralline is screened out to be used as a candidate reference gene (shown as a sequence table SEQ ID NO. 1-SEQ ID NO. 13); using the screened candidate reference gene as a template, designing a Primer by using Primer 3web (http:// Primer3.Ut. Ee /) according to a gene sequence, and amplifying the fragment with the size of 100-250bp (see table 1 for details);
using cDNA obtained by reverse transcription of a template glehnia littoralis as a template, identifying the specificity of a primer through common PCR, observing a band of a PCR product under a gel imaging system after electrophoresis, selecting the primer with correct size of the band, single band and no primer dimer as shown in figure 1, and recovering and sequencing the PCR product to further determine whether the target candidate gene amplification product is correct.
(6) Establishing a reference gene primer standard curve: and (3) preparing respective standard curves for the primers of each pair of reference genes, and calculating the amplification efficiency of the corresponding primers. Diluting cDNA reverse transcribed by template glehnia littoralis by 5 times into 6 gradients (1, 1/5, 1/25, 1/125, 1/625 and 1/3125) as a template for establishing a standard curve; qRT-PCR is carried out by using a qTOWER2.2 Real-Time PCR System instrument, the amplification efficiency and the slope of each candidate gene are obtained by using the obtained data result, and the amplification efficiency of the primer is between 88 and 108 percent (see table 1 for details);
TABLE 1 candidate internal reference genes of Gynura corallina and corresponding primers
Figure BDA0002801541580000071
(7) qRT-PCR: carrying out real-time fluorescence quantitative PCR amplification on the internal reference gene by taking cDNA obtained by reverse transcription as a template to obtain a corresponding Ct value; SYBR Premix ExTaqTM II (TliRNaseH Plus) (Takara) fluorescent quantitation kit, amplification program: pre-denaturation at 95 ℃ for 5min; denaturation at 95 ℃ for 15s, annealing at 60 ℃ for 15s, extension at 72 ℃ for 25s, and running for 40 cycles; and collecting a melting curve signal, wherein the generated melting curve is a single peak, which indicates that the specificity of the primer is good, the Ct value data is automatically read by a real-time fluorescent quantitative PCR instrument, and the distribution range of the Ct value is shown in figure 2. The Ct value is inversely proportional to the expression quantity of the gene, the larger the Ct value is, the lower the expression quantity of the gene is, and conversely, the smaller the Ct value is, the higher the expression quantity of the representative gene is;
(8) Analysis of stability of internal reference gene: analyzing the stability of the reference gene by using four statistical analysis methods of delta Ct, geNorm, normFinder and BestKeeper;
(9) The RankAggreg R program package is used for comprehensive analysis of the stability of the reference genes. Δ Ct is ranked according to the dispersion of Ct value data, and the smaller the mSD (Mean StdDev), the higher the gene stability. Table 2 is a case of ranking the stability of multiple candidate reference genes under four different stress treatments using the Δ Ct method. FIG. 3 shows GeNorm is a measure of gene stability based on the average variation M, with smaller M values giving better stability. Table 3 shows that NormFinder is based on analysis of variance, and the stability of the internal reference gene is directly evaluated. Table 4 shows that BestKeeper judges the stability of the reference gene by the standard coefficient of variation (SD), and the smaller the SD, the more stable the gene. As shown in fig. 4, finally, according to the stability ranking obtained by the four methods, a RankAggreg R program package is used for making a comprehensive ranking, and under four treatment conditions of coral vegetable salt stress, drought stress, ABA and MeJA, the CYP2 gene comprehensive stability ranking is the first and the stability is the best;
(10) Relative expression of genesMethod of calculating quantity application 2 -ΔΔCt The method comprises the following specific steps: Δ Ct = Ct (target gene) -Ct (reference gene), Δ Δ Ct = Δ Ct (treatment) - Δ Ct (control), 2 -ΔΔCt = relative expression amount.
TABLE 2 stability analysis of multiple candidate reference genes by Delta Ct method
Figure BDA0002801541580000081
TABLE 3 stability analysis of multiple candidate reference genes under four stresses by the NormFinder method
Figure BDA0002801541580000082
TABLE 4 stability analysis of multiple candidate reference genes under four stresses by BestKeeper method
Figure BDA0002801541580000083
Figure BDA0002801541580000091
Example 11
This example is to verify the effect of the application of the candidate reference gene provided by the present invention. PYL (abscisic acid receptor-like protein) is selected as a target gene, and is a key component in an ABA signal transduction pathway, and the expression level of the PYL is generally increased after the PYL is stressed. According to the research of NaCl differential transcriptome sequencing of glehnia littoralis, the expression level of the glehnia littoralis PYL gene is definitely up-regulated under the salt treatment. Therefore, in the embodiment, the reference genes with better and poorer stability (shown in figure 4) provided by the invention are respectively selected, and the expression quantities of the glehnia littoralis PYL gene under salt treatment, drought treatment, ABA treatment and MeJA treatment are verified and compared in application effects by utilizing a qRT-PCR method. The method comprises the following specific steps:
(1) Experimental materials and treatment methods: the germplasm resource of the template glehnia littoralis comes from Fujian Tan coast, and is cultivated in a germplasm resource garden of the plant institute of Chinese academy of sciences of Jiangsu province and Nanjing Zhongshan;
the stress treatment method comprises the following steps: collecting seedling of Eucheuma Gelatinosum (the underground part is about 3-6cm in length) in nursery garden, transplanting into flowerpot cleaned with river sand, irrigating Hoagland nutrient solution, culturing in illumination incubator at 26 deg.C and 22 deg.C, 14h/10h day and night circulation, relative humidity of 75%, culturing for three months, selecting healthy plant with similar growth vigor, performing stress treatment, soaking the flowerpot in 200mM NaCl, 20 mM PEG 6000, 100 μ M ABA, and 100 μ M MMeJA solution, collecting root (medicinal part) tissue sample of Eucheuma Gelatinosum at 0, 6, and 24 hr, washing with deionized water, absorbing water, draining, quick freezing with liquid nitrogen, and refrigerating at-80 deg.C for RNA extraction, wherein each sampling has three biological repetitions (one repetition per plant);
(2) RNA extraction and cDNA synthesis: extracting RNA of root tissue samples of 4 different templates of glehnia littoralis by using a Trizol Reagent (Takara) kit (the extraction mode is consistent with the content in the kit specification);
detecting the integrity of the extracted RNA by electrophoresis, carrying out electrophoresis for 10min by using 1% agarose gel and TAE buffer solution under the voltage of 170, observing by using a gel imaging system, and analyzing; performing purity detection (OD 260/280 of pure RNA is between 1.8 and 2.2) and concentration quantification on the extracted RNA by using NanoDrop ND-2000;
(3) Mu.g of RNA sample was sampled using reverse transcription kit PrimeScript TM Carrying out reverse transcription by an RT reagent Kit with gDNA Eraser (Perfect Real Time) to obtain cDNA (the reverse transcription mode is consistent with the content in the Kit instruction);
(4) And (3) a target gene PYL sequence for verifying the application effect of the reference gene and a specific primer design: according to the information of a corallina transcriptome sequencing database obtained by the research team, a PYL nucleic acid sequence (shown as a sequence table SEQ ID NO. 14) is obtained by referring to a PYL gene AT5G05440 of a model plant Arabidopsis thaliana, a Primer is designed by using a Primer 3web (http:// Primer3.Ut. Ee /) according to the gene sequence, a PYL fluorescence quantitative upstream Primer sequence is shown as a sequence table SEQ ID NO.41, a downstream Primer sequence is shown as a sequence table SEQ ID NO.42, and a target fragment is 137bp;
(5) Establishing a standard curve of a target gene PYL primer: diluting cDNA reverse transcription of template glehnia littoralis into 6 gradients (1, 1/5, 1/25, 1/125, 1/625 and 1/3125) by taking 5 as a multiple, and taking the gradients as a template for establishing a standard curve;
qRT-PCR is carried out by using a qTOWER2.2 Real-Time PCR System instrument, the amplification efficiency and the slope of the gene are calculated by using the obtained data result, the amplification efficiency of the PYL primer is 92.22 percent, and the slope is 0.9974;
(6) qRT-PCR: taking cDNA obtained by reverse transcription as a template, and simultaneously carrying out real-time fluorescent quantitative PCR amplification on the selected and verified reference gene and the target gene to obtain a corresponding Ct value;
SYBR Premix ExTaqTM II (TliRNaseH Plus) (Takara) fluorescent quantitation kit, amplification program: pre-denaturation at 95 ℃ for 5min; denaturation at 95 ℃ for 15s, annealing at 60 ℃ for 15s, extension at 72 ℃ for 25s, and running for 40 cycles; and collecting a melting curve signal, wherein the generated melting curve is a single peak, which indicates that the specificity of the primer is good, and the Ct value data is automatically read by a real-time fluorescence quantitative PCR instrument. The Ct value is inversely proportional to the expression quantity of the gene, the larger the Ct value is, the lower the expression quantity of the gene is, and conversely, the smaller the Ct value is, the higher the expression quantity of the representative gene is; method for calculating relative expression amount of gene and application 2 -ΔΔCt The method comprises the following specific steps: Δ Ct = Ct (target gene) -Ct (reference gene), Δ Δ Ct = Δ Ct (treatment) - Δ Ct (control), 2 -ΔΔCt = relative expression amount.
(7) Different reference genes are selected to carry out qRT-PCR verification to verify the application effect of the reference genes provided by the invention:
as shown in fig. 4, the results of the comprehensive stability evaluation of the reference genes, under the NaCl treatment condition, four reference genes were applied, wherein CYP2 and EXP1 were reference genes with relatively good proven stability, and GAPDH and UBQ10 were reference genes with relatively poor stability; as can be seen from the qRT-PCR result, the expression level of PYL is changed to a larger extent when the PYL is treated for 24h by NaCl through the correction of GAPDH and UBQ10 compared with the control, and the result is relatively stable through the correction of CYP2 and EXP1 with good stability, so that the possibility of false positive result can be reduced to a certain extent through the use of the reference gene with good stability (see FIG. 5A).
Under the PEG treatment condition, four reference genes are respectively applied, wherein CYP2 and ACT are the reference genes with better relative stability, and beta-TUB and UBQ10 have poorer stability; as can be seen from the results of qRT-PCR, the PYL expression levels varied greatly at 24h in PEG treatment using the relatively unstable β -TUB and UBQ10 genes, and the use of UBQ10 even showed a trend opposite to that of other reference genes, while the use of CYP2 and ACT, which had better stability, showed a consistent trend and good reproducibility (see FIG. 5B).
Under the ABA treatment condition, four reference genes are respectively applied, wherein CYP2 and ACT are reference genes with relatively good stability, and beta-TUB and UBQ10 are poor in stability; as seen in the qRT-PCR result, the PYL expression amount after ABA treatment is inconsistent and is in an opposite trend at 24h by using unstable beta-TUB and UBQ10 genes, while the PYL expression trend is consistent and the result is more reliable by using CYP2 and ACT with better stability (see figure 5C).
Under MeJA treatment conditions, four internal reference genes are respectively applied, wherein CYP2 and EXP2 are internal reference genes with better evaluation relative stability, and beta-TUB and EF 1-alpha have poorer relative stability; the qRT-PCR result shows that PYL expression trends obtained by applying the four genes are almost consistent, which shows that the repeatability of each internal reference gene is good and the result is reliable under MeJA treatment (see figure 5D).
According to the embodiment, the internal reference gene with good stability developed by the invention has better effect on the analysis of target gene expression, clearly shows the expression change trend of the target gene PYL after various stresses are treated for 6h and 24h, and if CYP2 is used alone, the test operation is simple and convenient, the cost is reduced, and meanwhile, the internal reference gene has reliability, and can be combined with other internal reference genes for correction.
Sequence listing
<110> plant institute of Chinese academy of sciences of Jiangsu province
<120> internal reference gene of glehnia littoralis and screening method and application thereof
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gatttaaatg actattttgt tcctctagtg aagaggttgg cagcaggtga atggtttact 420
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agacatactg gtgttatggt cgggatgggg cagaaggatg cctatgttgg tgatgaagcc 180
caatcgaaga gaggtattct taccttgaaa tatccgattg agcacggtat tgtgagtaat 240
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gaggagcacc cagttctttt gactgaagcg cctctcaatc ccaaggccaa cagggagaaa 360
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atgttcacca ccactgctga gcgggaaatt gttcgtgaca tgaaggagaa acttgcctat 660
gttgctcttg actacgagca agagcttgaa acctcaaaga gtagctcttc tgtggaaaag 720
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gaagtcctgt tccagccgtc tctgatcggg atggaagctg ctggaatcca tgaaaccact 840
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aggttcgaga aggaagctgc tgagatgaac aaacgttcat tcaagtacgc atgggttctt 180
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aagcctggta tggttgtgac ttttggtcct tcagggttga ccactgaagt caagtctgtt 840
gagatgcatc atgaggctct ccaggaggct cttcctggtg acaatgttgg attcaatgtt 900
aagaatgttg ctgttaagga tctcaagcgt ggatatgttg cctccaactc caaggatgat 960
cccgccaaag aggctgccaa tttcactgct caagttatca tcatgaacca ccctggtcag 1020
atctcaaatg gttatgctcc agtgcttgat tgccatacct gtcacattgc tgttaagttt 1080
gctgaaatcc aaaccaagat tgatcgtcga tctggtaagg agatcgagaa ggagcccaag 1140
tttttgaaga atggtgatgc tggatttgtt aagatgattc caaccaagcc catggtggtc 1200
gagaccttta tgacctaccc tcctcttgga aggtttgctg taagggacat gaggcagact 1260
gttgctgtgg gagtcatcaa gagtgtggag aagaaggaac ctaccggagc caaggtcaca 1320
aaggcggcaa tcaagaagaa a 1341
<210> 5
<211> 1010
<212> DNA
<213> GAPDH
<400> 5
atggcaccaa tcaagatcgg aatcaacggt ttcggaagaa ttggacgatt ggttgctaga 60
gttgttctgc aaagagatga tgttgagctt gttgctgtta acgatccatt tatctcaact 120
gattacatga catacatgtt caagtatgac agtgttcacg gtgcatggaa gcatcatgaa 180
ctcaaggtta aggatgagaa gactcttctc ttcggtgcga agcctgttgc tgtctttggt 240
tgcaggaacc cagaggagat cccatgggct agcactggtg cagagtatat tgttgaatcc 300
actggtgtct tcactgacaa ggaaaaggct gctgcacatt tgaagggagg tgcaaagaag 360
gtcatcatat ctgccccaag caaagatgct ccaatgtttg tcgttggtgt caatgagaag 420
gaatacaagt ctgacctcca cattgtttcc aatgctagtt gcacaacaaa ttgccttgct 480
cccctagcta aggtgatcaa tgataggttt ggcattgttg aggggcttat gacaactgtt 540
cattcaatca ctgccacaca aaaaactgtt gacggacctt ctgcgaagga ctggagaggt 600
ggaagagctg cttcattcaa catcattcct agcagcactg gagctgccaa ggctgttgga 660
aaagtgctac cttctctgaa tgggaagttg accggaatgt cattccgagt tcctactgtg 720
gatgtctcag ttgttgatct cactgtcagg ctggaaaaga aggctactta tgaacaaatt 780
aaagctgcca ttaaggagga gtctgaggga aagcttaagg gaatcttggg ttacactgaa 840
gatgatgtgg tttccacaga ctttgtgggt gacagcaggt caagcatctt tgatgccaaa 900
gctggaattg ctctaaatga caactttgtc aagcttgttt cgtggtatga caacgaatgg 960
ggatacagca cccgagtggt tgacttgatc gttcatatgg catctgttca 1010
<210> 6
<211> 1356
<212> DNA
<213> α-TUB
<400> 6
atgagggagt gcatttcagt tcacatcggt caggccggta ttcagatcgg taacgcttgc 60
tgggaacttt actgcctcga gcacggcatt cagcctgatg gccaaatgcc aagtgacaaa 120
actgtcggtg gaggtgatga tgctttcaac actttcttta gtgaaactgg tgctggaaag 180
catgtgcctc gagcaatctt tgtggatctt gagcccactg tcattgatga agtgaggact 240
ggaacatatc gtcagctctt tcatcctgaa cagctgatta gcggaaaaga agatgcagct 300
aacaactttg ctcgtggaca ctataccatt ggaaaggaga ttgttgatct ttgcctggat 360
cgtatcagga agcttgctga caattgcact ggtctccagg gtttccttgt ttttaatgct 420
gttggaggag gcactggttc tggtttgggt tcccttcttc tggaacgtct ctccgtggac 480
tatggcaaaa agtcaaaact tggattcact gtttatcctt caccacagat ctctacctct 540
gttgttgagc cttacaacag tgtgctttcg acccactcac ttttggagca caccgatgtt 600
tctgtgctgc tggataatga ggctatatat gatatttgca agcgttccct tgacattgag 660
cgacccacct ataccaacct taatcgattg gtttctcagg tcatttcctc tttgaccgct 720
tccttgaggt ttgatggagc cttgaatgtt gatgtgactg agttccagac taatctggtg 780
ccatacccaa ggatccactt catgctttct tcttatgccc ctgttatctc cgctgagaag 840
gcctaccatg aacagctatc tgttgcagag atcaccaaca gtgcatttga gccctcttct 900
atgatggcca agtgtgatcc tcgccatgga aagtacatgg cttgctgtct gatgtaccga 960
ggtgatgtgg tgcccaaaga tgtgaatgca gctgttggta ccattaagac caagcgcacc 1020
atccagtttg ttgattggtg cccaactggt tttaagtgcg gtatcaacta tcaggcccca 1080
actgttgttc caggtggtga tcttgccaaa gtgcagagag ctgtatgcat gatctcaaat 1140
tcgaccagtg ttgcagaggt tttctcacgc atagacacta aatttgacct aatgtactca 1200
aagagggctt tcgttcactg gtatgttggc gagggtatgg aagaaggtga attctctgaa 1260
gcacgtgagg atcttgctgc ccttgagaag gactatgagg aggttggtgc agagtctgct 1320
gagggggatg atgaggacga gggagaagat tactga 1356
<210> 7
<211> 1344
<212> DNA
<213> β-TUB
<400> 7
atgagagaaa ttcttcacat tcagggcggt caatgtggaa accagatcgg agcaaagttc 60
tgggaagtga tctgcgccga gcacgggatc gattcgacag ggcgttacca gggagacact 120
gaaattcaat tggagcgaat caatgtgtat tacaatgaag ccagttctca gaggtatgtt 180
cccagggctg tgcttatgga tctggagcct ggtactatgg atagtctccg atctggaccc 240
tacggtcaga tcttcaggcc tgataacttt gtgtttggtc aatctggtgc tggtaataat 300
tgggccaaag gtcactatac tgaaggtgct gagttaatcg actcggtgct tgatgttgtg 360
aggaaggaag ctgagaattg tgactgtctt caagggtttc aggtgtgtca ttcactcggt 420
ggtggaaccg gatctggaat gggtacactt ctgatttcaa aaatcagaga ggagtatcct 480
gaccgtatga tgcttacttt ctcagttttc ccatcaccca aggtgtctga tactgtggtt 540
gagccttata atgccactct ttctgttcat caacttgttg aaaatgctga tgagtgcatg 600
gttttggaca atgaggctct ttatgacatt tgcttccgca ccttgaagct taccacacct 660
agctttggtg atctaaacca cttgatttcg gccactatgt ctggtgttac atgctgcttg 720
cgtttccctg gtcagttgaa ctccgatctc aggaagttgg ctgtaaatct cattcccttc 780
cccaggttgc acttctttat ggttggattt gcacctctta cctcccgtgg ttcccagcaa 840
taccgtgcat tgagtgtacc tgagcttacc cagcagatgt gggattcaaa gaacatgatg 900
tgcgcagctg atccccgcca tggtagatac ttgacagctt ctgctgtgtt cagaggaaag 960
atgagcacta aagaggttga tgagcagatg atcaacgtcc agaacaagaa ctcttcctac 1020
tttgttgaat ggatcccaaa caatgtgaag tcaactgttt gtgacatccc accaactggt 1080
ctgaagatgg cttcaacctt cattgggaat tcaacttcaa ttcaagagat gtttaggcgt 1140
gtgagtgagc agttcacagc tatgttcagg aggaaagctt tcttgcattg gtataccggt 1200
gagggcatgg acgagatgga gttcactgag gctgagagca acatgaatga tcttgtttcg 1260
gagtaccagc agtaccagga tgccactgct gacgaggagg gtgactattt cgaagaagaa 1320
gaagaggatg gccaagacat gtaa 1344
<210> 8
<211> 1163
<212> DNA
<213> PTBP1
<400> 8
atgtcgaatt caaatcagcc tcaatttcga tacacacaga ctccttctaa agtgcttcac 60
ttgcgtaact tgccttggga gtgtattgaa gaagagctcg tcgagctttg caggcctttt 120
ggtaagatcg ttaacaccaa gtgcaatgtc ggcgctaatc gcaatcaagc cttcgttgaa 180
tttgtggatc ttaatcaggc cattaatatg gtttcatatt atgcttcatc atcagaacct 240
gcatctgttc ggggtaaaca tgtttatata cagtattcaa acagacatga aattgtcaac 300
aacaagggtc caggtgatgt tccgggaaat gtcttgctgg taaccattga gggtgtagaa 360
gccggtgatg taagcattga tgtgattcac ttggtcttct cggcttttgg atttgtgcac 420
aagattgcta cttttgagaa ggcagcaggt tttcaggcac taatccagtt tactgatgct 480
gagactgctc tttcagcaag ggaagcttta gatggcagaa gtattccaag gtacttgctt 540
ccagaacatg ttggttcttg caatctgcgc atctcatatt cagctcacac agatctaaac 600
atcaagttcc aatcacaccg tagccgggac tatacaaatc catatcttcc tgttaatgca 660
actgcaattg agggatttgt ccagcctgtt gtaggtcctg acggaaagaa aaaagaaccg 720
gagagtaatg tacttcttgc ctcaattgaa aataggatct atgatgtcac tgtagatgtt 780
cttaacacgg tattctctgc atttggcacg gttcagaaaa ttgctatatt cgagaagaac 840
gcgacaactc aggctctaat tcagtatcct gatgtcaaca ctgccgccgt agctaaagat 900
gctctagagg gacactgcat atatgatggt ggctactgta agcttcatat atcatactct 960
cgtcatactg atctcaatgt aaaggccttc agcgataaaa gtagggatta tacagtacca 1020
gagtccggtt ttgctgctgg tctgcctgct ggagcaacag tctggcagaa tcctcatgct 1080
gctgctccgg tctttattgg gagcgaattt gctagtatca attatgggca gcctcaaggc 1140
tctcccggtc aaggacctcc tgg 1163
<210> 9
<211> 1179
<212> DNA
<213> EXP1
<400> 9
atgtcgaaaa ctgaagacga agaggagcgc cggagaaagt acgaggaagc tctcgaagtc 60
aaatctctcc gccgtatcat cagcgcctat ctcaattacc cagaggctgc agaggaggac 120
ttgaaaagat atgaaagatc ttatagaagg cttccaccaa cccataaggg tctcctgtct 180
caccttcctg taaaatatcg aagactgcga aggtgtatat ctaagaattc atattttata 240
tttgaaatgc taaaggcatt tgaacctccc cttgatctga gccaagacct tgacatatgt 300
gaacaagatc cgcagaatat cttagacgat accaaagaaa ccaattattt ttcttgtggg 360
tctgcatcaa ccagtaaaac aggatgtcat ccagggtgca atgaagctgt cagtggagag 420
gaggggagcg tgttattagg atctcccaag gaggagaaac ttgggctttt tattgattcg 480
gacaccggga gccgtcatat tttggaatgt gatgccacag cagataaagc tggtaacaac 540
ggtgttaaga ttaaaaaaac ttcacactct aatgcagact ccaataataa tgagaaactt 600
gggcttttca ttgagtctga cactgggaac cgtcatgttt tggaatgtga taccaaagca 660
gatgaggctg gtaacaacgg tgttaggata caggaaactt cgtactctaa tgcagactcc 720
aattataatg tgtcttcatc tcctgattgg ttggatccat cactgcagtc gcatgttcct 780
ctagttgatg tagataaggt tcgatgtatt ataagaaata ttgtaagaga ttgggctgca 840
gagggacaac aagaacgtga tcagtgctat acgcctattc ttgaagagct taaatcacaa 900
tttcctaatc gaagtaaagg gagccctcct gcatgtttag ttccgggtgc tggacttggt 960
agactggctt tggaaatttc atgtcttggt tttgcaagcc aaggaaatga attttcatac 1020
tatatgatga tctgctcgag ttttattctt aaccaagcgg aaagggctaa tgaatggact 1080
atccatcctt ggattcatag caattgcaat tcactttctg acagtgacca gcttcgtcct 1140
atttcaatac cagatattca tcctgccagg aataactga 1179
<210> 10
<211> 981
<212> DNA
<213> EXP2
<400> 10
atggcaagag gagagtgggg gtactataat ggaagaacga aatggtgttc ttatagaaga 60
accactttga ttatttgttc aattaacatt ggtgttgctc tttatgttct tcacactctt 120
tataactctc tttacaccta cccttttaat gatcctcaaa aagctgctag gtacactcct 180
gatcagatta ggaaaatgga agaatcaaat gatattagaa aagcctcaca acccactgaa 240
cttattaaat tggtgaatga aataaggaag gattttttac aagaagagaa gagggttgat 300
ttgccatcaa atttgaaaca ccaggtaatt gatgagattg tggaattatt gaggagcttg 360
aagtcctcca atgcgactgt tcaaaatgaa gcagttgaaa gatggcgcaa gcaaaaaata 420
agagaagcta gaggggtggc tcggggagat attctgaatc caaacattct gccaaaggaa 480
gcaaaaattc ttgcaagaac gttgaagtct cgctgggatg agtttagaga agaaatcggt 540
ctctggatac ctgttgcaat cgttaacaag gaacatgatg acaagcctga gggtgaagaa 600
gagtttgaca gcgaaatatt agccggcaga cagcttcctc ccgagtgcca tactgaactt 660
catacagatt atggtggggc agctgttcgc tggggcctta cccaccataa agagagcgct 720
tatgattgtt gtcaagcttg tctggatcaa gccaaaaatg caagagaagg cgaaaagcgc 780
tgcaatatat gggtgtactg cccttcagag ggtggatgtt actcaccaga tatatatgaa 840
cacaaacagc aagaatgctg gctgaaatat gacgagaaac cccaagtaag ctttaaggac 900
aaatactccg aatcattcag aaactcgcat ccaaatgttc cactggttgt tccatgggta 960
gctgggattg taagtgtata a 981
<210> 11
<211> 684
<212> DNA
<213> TIP41-like
<400> 11
atggtttttg gggaaagttc attggttctc aagcacttga agagcgatgt aaagattcat 60
ttcaacgcat ttgattctct agttggttgg aagcaggaaa aattaccacc agttgaggtc 120
cctgcagcag caaaatggaa atttagaagc aaacctttcc agcaggtgat attagattat 180
gactacacat ttacaacacc atattgtgga agtgaaactg ttgagaaaaa ctcagagagg 240
gatacaatct ctgatgaagg cagttgcaag cttcgttggg aggactgcga ggaacgaatt 300
aatttgactg cacttgcatc aaaagagcct attctcttct atgatgaggt gatcttctat 360
gaagatgaat tggctgatag tggagtgtcg cttttaacag taaaagtgag agtgatgcca 420
agctgttggt ttcttctctt gcgtttttgg cttagagttg atggtgtgct tatgcgttta 480
agggacacac gcatccattg catttttggt gagggtaaaa caccagttat tctgagagaa 540
tgttgctgga gagaggccac atttcaagca ctagcttcta aaggatatcc ttctgattgt 600
gctgcgtata ttgatccaag cagcatcggc caaagacttc ctatcatttt gcataagacc 660
caaaagctta taattcctga ttaa 684
<210> 12
<211> 2007
<212> DNA
<213> SAND family
<400> 12
atgttaccag aagatgatgc caactcctca tcagaaaccg actcaattga ccaaaaccct 60
aaccctacca cttcaattga ccaatctctc gacgctattg aaggtcaatt aacctctatt 120
tcactcaatc accaccactc aaaaccccca tttcaccctc ctcttcccca aaatatcgat 180
acattgcctt cccattcgca ttcgcaactc caacaaccac cagcaccagc tgaaaatctc 240
caaaatatcg atacattacc ttcccattca cattcgaaac tccaacaagt agcagtagct 300
gaaaatatcg gttcattacc ttcggattca cattcgcggg ccggacaagt agttgaaaat 360
tctggacaag tggatatatt aggttcggat tcctatacga aagtagagaa ggaagtagtt 420
ggaaattcga gaggcgaagg agtgttgtgg aggaataatt cggatgtgga agttgaggtg 480
gaagggcaag ggagtccgag tagtagtgga tatgctggag gaaaggggac tagtagtagt 540
ggtagtagtg gtataagtgg ttcaggtatc gaggagatta gtggcggcga tgacgaggtg 600
gttaacagga gtggttcttt tggtggtagt gtggattccg agtgggtccc tgggaaacgg 660
catgttaatg aagatgatgc ttctgtttca tggaggaaaa ggaagaagca tttttttatc 720
ttaagccatt ccggaaaacc aatatattca agatatggag atgaacacag actagcagga 780
ttttcagcaa ctttgcaagc catcatttcc ttcgtggaga atgggggaga tcgcgtgaag 840
ttggttaggg cgggaaaaca ccaggtggtt tttcttgtta aaggaccaat atatctagtt 900
tgcataagct gtacagaaga gcctcatgaa tccctcagtg aacaactgga acttctttat 960
ggccagatga tacttattct gacaaagtct ataaatagat gctttgagaa gaatccgaaa 1020
tttgatatga cacctttgct tgggggaaca gatgctgtgt tctcttctct catccactcg 1080
tttagttgga accctgccac ttttcttcat gcctactctt gtcttcccct tgcttatcca 1140
acaaggcaag ccgccggtgc catattgcag gatgttgctg agtcaggtgt cctcttcgcg 1200
atattaatgt gtaaacacaa ggtcatcagt ctggttggtg cacaaaaagc gtctcttcat 1260
cccgatgata tgctcttgct tgccaacttt gtgatgtcat ctgaatcatt caggacatct 1320
gaatctttct ctccaatctg tcttccgaga tacaatccaa tggcattttt atatacttat 1380
gtgtattatc ttgatgctga tacttatttg atgttgctta ctgctaatcc tgatgcattt 1440
catcgtctaa aagattggag gatccgtatc gaaatggtcc ttctgaagtc aaatgttctt 1500
aatgaagctc aaaggtcgat gttggatggt ggcatgcgtg tcgaagatgt gcctgttaat 1560
ccatctcctc gctcgggatc tttgtcatct catttaggtc agcctagacc tccaccggac 1620
tctgcagatg ggtgtaaggc actgttaggt ggtcctgctg ggctttggca cttcgtttac 1680
cgcagtatat atctagatca atatgtatct tctgagttct catcaccgat caacacccct 1740
aaacaacaga aaagattata tagagcatat cagaagctgt atacttctat gcatgatata 1800
gaacttggtc ctcacaaaac ccagtttaga agggacgaga actatgttct actctgctgg 1860
gttactcagg attttgaact ttatgcagca tttgatcctc tagcagacaa ggcactggct 1920
ataaagacat gcaaccgagt atgccaatgg gttaaagatg tggaaaatga agtttttttg 1980
ttgggagcaa gccccttttc atggtga 2007
<210> 13
<211> 1491
<212> DNA
<213> CYP2
<400> 13
atgtcatcta tctacgtatc ggagcctccg accaaaggca aagtttcgct caagacaaca 60
tacggtccat tggacataga gctatggccg aaagaggctc ctaaagctgt gcgcaacttc 120
gttcagctct gtctcgaagg ttattatgat gacacaattt ttcatcgtat aattaagtca 180
tttatggtcc aaggtggtga tcctactggc actggcaaag gtggtgaaag tatatatgga 240
ggtacatttt ctgatgagtt ccattcccgc cttaggttca accacagggg cttggttgca 300
tgtgcgaatg ctggatcacc aaattcaaat gggagtcagt tttttataac cttggatcgt 360
tgtgattggc ttgatcgtaa acataccatt ttcggaaagg taactggaga ttcactatac 420
aatctcttaa acttttccga ggttgaaact gataaggatg atcgaccagt agaatctccc 480
cctaaattga tttcagttga ggtgatatgg aacccttttg atgatattgt tccaagggca 540
gcccctgcta aagctttggt ctcctcaaat gatagtggca acagagatac aaaaaggaaa 600
gcgtcaaaaa agctaaactt gctttcattt ggagaagaag ctgaagaaga ggaaaaagaa 660
ttggcagctg tgaagatgaa aattagaagt agtcacgatg tattagatga tcctcgtttg 720
ctgaaggaag acggttcaac cagcaaaccg agtgaatcag aagccaaagc tatgaaagat 780
atgcagttaa gtgttagaga agctctaagt tcaaagaagg atgaatcatg gaaagagacg 840
cacagtaaat tttcagagac ccttcctgat agcgatgacg atgaggccaa ctttgataac 900
aggatgcgat tacaaatact taagaaaaga aaggagcttg gagatcattc aactaagcaa 960
aagtcacaca atgcgagttc aagtccaaga aaccgtgaac gctcctattc tcctcccagg 1020
tcaaatgcca aaaattccga tgatcaacca aaagtggaga agttggcttt gaagaaggga 1080
ataggatcag aagccagggc cgagcgtttg gccaatgcgg atgtggactt gcaactgttg 1140
ggagaagctg aacgagaaag gcagttacaa aagcagaaga agcgccgatg tcatgggcac 1200
gaagaggatg tgctagcaaa gcttgagaag ttcaaggcca ccatgtcctc caaatctgtt 1260
ggagctgatg gtgaatctgg aggacacaag gaagaggact tgtctgactg gacaaaagtt 1320
aagctgaagt ttgaacctca atccgggaag gataatatga ctcgcaccga gaatgtgaat 1380
gactatgtat ttcatgatcc tcttctggag aagggaaaag agaagttcaa caaaatgcaa 1440
gcaaagcaaa agcgacgaga acgagaatgg gctggaaagt cacttacata a 1491
<210> 14
<211> 603
<212> DNA
<213> PYL
<400> 14
atgccttcat ctcttcgacg tcaaagaatc tacaacaccg attacaacta ccaaaaaaaa 60
tcacataata atgtgcatac aattattcca ccacctctag ggcttccgga aaatatcaaa 120
caccaccaca cacacatgat tagctataac caaagcagct ccgccgtggt ccaaaccatc 180
tccgcaccta tatccaccgt gtggtccatt attcgaaact tcgaaaagcc acaaatttac 240
aagcacttta tcaaaagctg ccatgtcatc cacggggatg gatccgtagg tagtctccgg 300
gaagtccacg tcatctctgg cctgcccgcg gtgtcgagca tcgagaggct agatattctt 360
gatgaagagt gtcacattat tagttttagt gtagtaggag gtgatcatcg gttgaacaat 420
tatcggtcag tgacgacgct acacaagacg gagaccggaa atggtacggt ggtggtggag 480
tcatatgtcg tggatgtgcc ggaggggaat actaaagagg agacttgtgg atttgcaaat 540
acaattgtga catgtaattt acattctttg gcaaagattg ctgaaaactt gagtaataag 600
taa 603
<210> 15
<211> 20
<212> DNA
<213> Artificial sequence
<400> 15
gcaaccattg aacctgctca 20
<210> 16
<211> 20
<212> DNA
<213> Artificial sequence
<400> 16
gaacacgcca cgacttatcc 20
<210> 17
<211> 20
<212> DNA
<213> Artificial sequence
<400> 17
tgaggggtgg aatgcagatt 20
<210> 18
<211> 20
<212> DNA
<213> Artificial sequence
<400> 18
tgcaagtgta cgaccatcct 20
<210> 19
<211> 20
<212> DNA
<213> Artificial sequence
<400> 19
accatcacca gaatccagca 20
<210> 20
<211> 20
<212> DNA
<213> Artificial sequence
<400> 20
cttcgagttg ctcctgagga 20
<210> 21
<211> 20
<212> DNA
<213> Artificial sequence
<400> 21
aaggatgggc aaactcgtga 20
<210> 22
<211> 20
<212> DNA
<213> Artificial sequence
<400> 22
agcaattttg tcggggttgt 20
<210> 23
<211> 20
<212> DNA
<213> Artificial sequence
<400> 23
accttctttg cacctccctt 20
<210> 24
<211> 20
<212> DNA
<213> Artificial sequence
<400> 24
gctgtctttg gttgcaggaa 20
<210> 25
<211> 20
<212> DNA
<213> Artificial sequence
<400> 25
acaactttgc tcgtggacac 20
<210> 26
<211> 20
<212> DNA
<213> Artificial sequence
<400> 26
tgcctcctcc aacagcatta 20
<210> 27
<211> 20
<212> DNA
<213> Artificial sequence
<400> 27
caggtacact caatgcacgg 20
<210> 28
<211> 20
<212> DNA
<213> Artificial sequence
<400> 28
cgcaccttga agcttaccac 20
<210> 29
<211> 20
<212> DNA
<213> Artificial sequence
<400> 29
ggctacggtg tgattggaac 20
<210> 30
<211> 20
<212> DNA
<213> Artificial sequence
<400> 30
tcggcttttg gatttgtgca 20
<210> 31
<211> 20
<212> DNA
<213> Artificial sequence
<400> 31
agccctcctg catgtttagt 20
<210> 32
<211> 20
<212> DNA
<213> Artificial sequence
<400> 32
acgaagctgg tcactgtcag 20
<210> 33
<211> 20
<212> DNA
<213> Artificial sequence
<400> 33
acacccatat attgcagcgc 20
<210> 34
<211> 20
<212> DNA
<213> Artificial sequence
<400> 34
catgatgaca agcctgaggg 20
<210> 35
<211> 20
<212> DNA
<213> Artificial sequence
<400> 35
agagtgatgc caagctgttg 20
<210> 36
<211> 20
<212> DNA
<213> Artificial sequence
<400> 36
gcctctctcc agcaacattc 20
<210> 37
<211> 21
<212> DNA
<213> Artificial sequence
<400> 37
ggaccatttc gatacggatc c 21
<210> 38
<211> 20
<212> DNA
<213> Artificial sequence
<400> 38
aagcgtctct tcatcccgat 20
<210> 39
<211> 22
<212> DNA
<213> Artificial sequence
<400> 39
gccactatca tttgaggaga cc 22
<210> 40
<211> 20
<212> DNA
<213> Artificial sequence
<400> 40
cgttgtgatt ggcttgatcg 20
<210> 41
<211> 20
<212> DNA
<213> Artificial sequence
<400> 41
tgccttcatc tcttcgacgt 20
<210> 42
<211> 20
<212> DNA
<213> Artificial sequence
<400> 42
catgtgtgtg tggtggtgtt 20

Claims (2)

1. Internal reference gene of glehnia littoralisTIP41-likeThe application of the coralline vegetable target gene expression level research is characterized in that:
the describedTIP41-likeThe nucleotide sequence of (A) is SEQ ID NO.11.
2. The internal reference gene of Eucheuma Gelatinosum according to claim 1TIP41-likeThe application of the coralline vegetable target gene expression level research is characterized in that:
internal reference gene for amplifying the glehnia littoralisTIP41-likeThe sequence of the primer pair is SEQ ID NO.35/SEQ ID NO.36.
CN202011351913.XA 2019-07-22 2019-07-22 Internal reference gene TIP41 of glehnia littoralis and screening method and application thereof Expired - Fee Related CN112322637B (en)

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