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GLADS: A gel-less approach for detection of STMS markers in wheat and rice


Authors: Gautam Vishwakarma aff001;  Ravi Prakash Sanyal aff002;  Ajay Saini aff002;  Parmeshwar Kumar Sahu aff004;  Ravi Raj Singh Patel aff004;  Deepak Sharma aff004;  Ratan Tiwari aff005;  Bikram Kishore Das aff001
Authors place of work: Nuclear Agriculture and Biotechnology Division, Bhabha Atomic Research Centre, Trombay, Mumbai, Maharashtra, India aff001;  Homi Bhabha National Institute, Anushaktinagar, Trombay, Mumbai, Maharashtra, India aff002;  Molecular Biology Division, Bhabha Atomic Research Centre, Trombay, Mumbai, Maharashtra, India aff003;  Department of Genetics and Plant Breeding, Indira Gandhi Krishi Vishwavidyalaya, Raipur, Chhattisgarh, India aff004;  ICAR - Indian Institute of Wheat and Barley Research, Karnal, Haryana, India aff005
Published in the journal: PLoS ONE 14(11)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0224572

Summary

Sequence tagged microsatellite site (STMS) are useful PCR based DNA markers. Wide genome coverage, high polymorphic index and co-dominant nature make STMS a preferred choice for marker assisted selection (MAS), genetic diversity analysis, linkage mapping, seed genetic purity analysis etc. Routine STMS analysis involving low-throughput, laborious and time-consuming polyacrylamide/agarose gels often limit their full utility in crop breeding experiments that involve large populations. Therefore, convenient, gel-less marker detection methods are highly desirable for STMS markers. The present study demonstrated the utility of SYBR Green dye based melt-profiling as a simple and convenient gel-less approach for detection of STMS markers (referred to as GLADS) in bread wheat and rice. The method involves use of SYBR Green dye during PCR amplification (or post-PCR) of STMS markers followed by generation of a melt-profile using controlled temperature ramp rate. The STMS amplicons yielded characteristic melt-profiles with differences in melting temperature (Tm) and profile shape. These characteristic features enabled melt-profile based detection and differentiation of STMS markers/alleles in a gel-less manner. The melt-profile approach allowed assessment of the specificity of the PCR assay unlike the end-point signal detection assays. The method also allowed multiplexing of two STMS markers with non-overlapping melt-profiles. In principle, the approach can be effectively used in any crop for STMS marker analysis. This SYBR Green melt-profiling based GLADS approach offers a convenient, low-cost (20–51%) and time-saving alternative for STMS marker detection that can reduce dependence on gel-based detection, and exposure to toxic chemicals.

Keywords:

Wheat – Rice – Polymerase chain reaction – Crops – India – Gel electrophoresis – Plant breeding – Crop genetics

Introduction

Conventional breeding utilizes various approaches for improvement of desired traits in crop plants [1,2], which involve laborious and time-consuming manual screening of large experimental populations. In addition, these are not straight forward methods for introgression of complex traits/phenotypes governed by multiple genes [3]. DNA markers ascertains linked traits (at any stage of plant) saves screening time, and hence are highly desirable for crop breeding applications such as, marker assisted selection (MAS) or marker assisted backcross breeding (MABB) [4]. Polymerase chain reaction (PCR) has revolutionized the development and use of a variety of DNA markers viz. Sequence Tagged Microsatellite Site (STMS), Sequence-Tagged Site (STS), Sequence Characterized Amplified Region (SCAR), Randomly Amplified Polymorphic DNA (RAPD), Arbitrary Primed-PCR (AP-PCR), Inter Simple Sequence Repeat (ISSR), Amplified Fragment Length Polymorphism (AFLP), Retroposon-Microsatellite Amplified Polymorphism (RE-MAP) [5]. Recent advances in genome sequencing has resulted in development of SNP markers for diverse applications including genome wide association studies (GWAS), marker development, genomic selection, germplasm characterization [6,7].

STMS markers due to their co-dominant nature, high polymorphism, high abundance, and dispersed genomic distribution [8] are highly popular, and have been extensively used for high density maps, tagging genes, map based cloning, gene pyramiding, species identification [910] etc. For applications like MAS of a trait or MABB, STMS marker are more preferred owing to their convenience in use and cost effectiveness [9,1012]. Furthermore, STMS also exhibit ‘transferability’, a useful attribute that allow the markers developed in one species to be utilized in related species [13,14]. For example, STMS markers from barley exhibit considerable transferability in wheat (~78%), rye (~75%) and rice (~42%) [15,16]. Despite advantages, STMS markers have not been utilized to their full potential, partly due to the non-availability of sequence of flanking regions (for locus specific primer designing) in several non-sequenced genomes, and to a certain extent due to the complexities associated with gel-based detection methods [1719]. Availability of next generation sequencing (NGS) approaches have resulted in development of large number of STMS or SSR markers (genomic/EST derived) in several non-model crops having limited genomic information. These markers are important genetic resources for linkage mapping, genetic diversity, MAS, DNA fingerprinting, and other applications for these crops [13,20,21].

PCR amplified amplicons (single- and multi-locus markers) are routinely scored on agarose or polyacrylamide gels [1719]. The gel-based methods are low-throughput, laborious, and add additional cost, thereby limiting the utility of even single-band markers to their full potential, as needed in applications such as MAS [22]. Scoring STMS markers on long-format polyacrylamide/high-resolution agarose gels is cumbersome, time-consuming and not suitable for high-throughput analysis [23]. Several gel-less approaches have been reported for DNA marker detection [19 and references therein], however majority of them are technically intensive. Hernández and co-workers reported a simplified assay involving addition of ethidium bromide to detect amplified products directly in the PCR tubes [24]. Advent of real-time PCR and sensitive fluorescent dyes [25] resulted in development of a diverse array of DNA detection methods based on hybridization probes, molecular beacons, TaqMan probes, scorpion probes, SYBR Green and High-resolution melting or HRM [26]. Capillary electrophoresis and use of fluorescently labelled primers were shown to automate the STMS marker scoring to a certain extent [2729]. Although, technical feasibility and utility of these approaches in STMS analysis have been demonstrated [3033] these are technologically intensive, expensive, require specialized instrumentation, and not suitable for analysis of large breeding populations [31,34,35]. In view of the above-mentioned concerns of different methods, simple, convenient and low cost gel-less detection methods are desirable for STMS scoring. These will be important for effective utilization of STMS in MAS programs that handles large experimental populations.

SYBR Green, a low-cost DNA binding dye, is an ideal candidate for large scale analysis [36]. Previously, we showed the utility of SYBR Green based melt-profiling as an effective method for SCAR marker detection in a gel-less manner, [19]. The approach is based on existing primers and is cost-effective than other methods [19]. The present study explores the utility of SYBR Green dye based melt-profiling as a gel-less approach for detection of STMS markers (referred to as GLADS). This approach involves generation of specific melt-profiles of wheat and rice STMS markers for their detection. The STMS markers/alleles were differentiated based on the melting temperature (Tm) and profile characteristics. The approach also demonstrated the feasibility of multiplexing that can further reduce the cost and time of analysis. Overall, SYBR green melt-profiling based GLADS can serve as a convenient gel-less method for detection of STMS markers linked to desirable traits. It is technologically less intensive, saves time, cost-effective, and therefore suitable for rapid analysis of large number of experimental samples as in MAS based crop breeding experiments.

Materials and methods

Plant material

A total of twelve bread wheat (Triticum aestivum L.) and twelve rice (Oryza sativa L.) genotypes were used in the present study. Seeds of the genotypes were obtained from the following Institutes: 1) Indian Agricultural Research Institute (IARI), New Delhi, India, 2) ICAR-IARI Regional Station, Wellington, Tamil Nadu, India, 3) Punjab Agricultural University (PAU), Ludhiana, India, 4) ICAR-Indian Institute of Wheat & Barley Research (IIWBR) Regional Station, Flowerdale, Shimla, Himachal Pradesh, India, and 5) Indira Gandhi Krishi Vishwavidyalaya (IGKV), Raipur, Chhattisgarh, India (Table 1). The wheat and rice plants were grown at experimental field at Bhabha Atomic Research Centre (BARC), Mumbai, Maharashtra.

Tab. 1. List of wheat (W1 –W12) and rice (R1 –R21) genotypes used for analysis.
List of wheat (W1 –W12) and rice (R1 –R21) genotypes used for analysis.

DNA isolation and quantification

Total genomic DNA was isolated from one-month old seedlings grown in experimental field at BARC as per protocol detailed in Eswaran and co workers [37], with minor modifications. Briefly, 200 mg leaf tissue was homogenized in 2.0 ml DNA extraction buffer (100 mM Tris, 20 mM EDTA, 0.5 M NaCl, 7 M Urea, 0.1% β-mercaptoethanol and 2% SDS), subjected to phenol:chloroform:isoamyl alcohol extraction, and followed by precipitation of genomic DNA by addition of sodium acetate (3 M, 0.1 volume) and isopropanol (0.7 volume). The DNA was recovered by centrifugation, dissolved in TE buffer (Tris-Cl:10 mM, EDTA: 1 mM, pH: 8.0) and treated with 50 μg of RNase (Roche Diagnostics, Mannheim, Germany) to remove the residual RNA contamination. DNA preparation was assessed for quantity (A260 nm) and quality (A260 nm/A280 nm) on a spectrophotometer (UV-1800, Shimadzu, Tokyo, Japan), and the integrity was assessed by electrophoresis on a 0.8% agarose gel (Sigma-Aldrich, St. Louis, MO, USA). DNA samples with good quality and integrity were used for analysis.

Oligonucleotide primers for wheat and rice STMS loci

Oligonucleotide primer pairs for PCR amplification of STMS markers were synthesized from Bangalore Genei Pvt. Ltd. (Bengaluru, India). Oligonucleotide primer-pairs for fifty-five wheat and eighteen rice STMS marker loci were synthesized as per the sequences given in previous publications [38,39]. General characteristics of wheat and rice STMS loci analyzed are listed in S1 Table.

Polymerase chain reaction: Optimization of amplification and multiplexing

PCR amplification of STMS markers was performed on Mastercycler gradient PCR machine (Eppendorf, Hamburg, Germany) using reaction components from Bangalore Genei Pvt. Ltd. (Bengaluru, India). The PCR reaction mix (volume: 25 μl) contained genomic DNA (50–75 ng), dNTPs (250 μM each), 10X reaction buffer (15 mM Tris-Cl pH 9.0, 50 mM KCl, 0.01% gelatin, 2.0–3.0 mM MgCl2), 3–5 pmol of each primer and 1.0 unit of Taq DNA polymerase. Following thermal cycling conditions were used for PCR amplification: initial denaturation at 94 °C (5 min), 40 cycles of denaturation (94 °C, 30 sec), annealing (62 °C, 45 sec), extension (72 °C, 40 sec), and final extension at 72 °C (7 min). Annealing temperature for PCR amplification was optimized by gradient PCR. Multiplex PCR analysis was attempted for different combinations of STMS markers using the same conditions described above.

Agarose gel electrophoresis

The amplification of PCR products was verified by electrophoresis at 8–10 V cm-1 in 1X TBE buffer, on 2.0% agarose gel (Sigma-Aldrich, St. Louis, MO, USA). The DNA fragments were stained with ethidium bromide and, photographed under UV light on a gel-documentation system from Syngene (Syngene, Cambridge, UK), and the sizes were estimated by GeneTools software (Syngene, Cambridge, UK).

SYBR Green dye-based melt-profiling of microsatellite amplicons

For in-tube and gel-less detection of STMS markers, SYBR Green (S9430, Sigma-Aldrich, St. Louis, MO, USA), a non-specific DNA binding fluorescent dye, was included in the PCR reaction mix (described above) at 1X final concentration. PCR assays were carried out on Mastercycler ep Realplex4 (Eppendorf, Hamburg, Germany) and LightCycler 480 II (Roche, Mannheim, Germany) PCR instruments, as detailed above. After the PCR, melt-profile analysis was carried out by measuring the fluorescence intensity of the amplicons in continuous mode (temperature range: 60 °C to 95 °C). Different temperature ramp rates (1.75 °C min-1, 3.5 °C min-1 and 7.0 °C min-1) were used to optimize the melt-profile analysis. The raw melt-profile data was transformed into the negative first derivative data (as a function of temperature) to identify maximum intensity changes (represented as peak curves) using the Eppendorf Mastercycler ep realplex software (version 2.2) or LightCycler® 480 Software (version 1.5) for assays carried out on LC 480 II instrument. For uniformity in data presentation, the fluorescence intensity was plotted as percent values versus temperature. Melt-profile analysis was also performed for STMS amplicons amplified by multiplex PCR assay, by using the optimized temperature ramp conditions as described above. In an alternative strategy, the PCR amplification of STMS markers was carried using normal PCR assay, SYBR Green dye was added post-PCR followed by melt-profiling on a real-time instrument as mentioned above. The STMS melt-profiling experiments were carried out using two independent DNA preparations and repeated at least two times, and appropriate controls were included for each set of analysis.

Results

Optimization of conditions for PCR amplification of STMS markers

Optimization of PCR conditions is necessary to minimize non-specific amplification products and primer-dimers, particularly when sensitive dyes such as SYBR Green are used in the assay. Using representative wheat and rice genotypes, amount of genomic DNA, primer concentration and annealing temperature were optimized for STMS PCR amplification. Use of 50–75 ng genomic DNA and 3–5 pmol primer resulted in optimum amplification with minimum non-specific signal. Gradient PCR assay (annealing temperature range: 58°C to 62°C) was carried out to find optimum annealing temperature for amplification. Annealing temperature of 62°C enhanced specificity and minimized non-specific products in PCR amplification of most STMS (S1 Fig). Using optimized conditions, the STMS markers specific to A-, B- and D-genomes of wheat yielded clean profiles on PCR amplification from a representative genotype (Fig 1A, 1B and 1C). Under optimized PCR conditions the rice STMS markers also yielded clean PCR amplification profiles (Fig 1D).

Fig. 1. Analysis of PCR amplified STMS markers on 2% agarose gel.
Analysis of PCR amplified STMS markers on 2% agarose gel.
A) wheat A-genome STMS markers, B) wheat B-genome STMS markers, C) wheat D-genome STMS markers, and D) rice STMS markers. Designations of the STMS markers are indicated on the top of the lanes. Lane ‘M’ indicates 100 bp ladder.

SYBR Green dye at 1X concentration was optimum (good fluorescence signal and negligible effect on PCR) for STMS melt-profile analysis. The melt-curve analysis was carried out using different ramping rates (1.75°C min-1, 3.5°C min-1 and 7.0°C min-1). Ramp rate of 3.5°C min-1 was found to be optimal for melt-profiling as it yielded low background signal and few non-specific signal spikes. The melt-profiling approach also showed enhanced specificity at higher annealing temperature in PCR, as shown for two wheat STMS markers (S2A and S2B Fig). However, certain STMS markers that showed a doublet on agarose gel yielded two peaks on SYBR Green melt-profile analysis despite increase in annealing temperature (S2C Fig).

SYBR Green melt-profiling yielded STMS marker specific profiles

The STMS markers that yielded clean amplification on agarose gel were included for SYBR Green melt-profiling analysis. SYBR Green melting curve analysis was carried for thirty-seven STMS marker loci from A-, B- and D-genomes of wheat, and for seven STMS loci from rice (Table 2), as detailed in materials and methods. The SYBR Green melt-profiling approach yielded characteristic profiles of STMS markers of wheat and rice. As an example, Fig 2A–2C show melt-profiles of three STMS markers specific to A-genome, B-genome, D-genome of wheat, and Fig 2D shows melt-profiles of three rice STMS markers. In general, the melting temperature (Tm) of the STMS profiles ranged from ~75 °C to ~95 °C (Fig 2).

Tab. 2. List of wheat A, B, and D-genome, and rice STMS marker loci analyzed in the present study.
List of wheat A, B, and D-genome, and rice STMS marker loci analyzed in the present study.
Fig. 2. SYBR Green melt-profiles specific to different STMS markers.
SYBR Green melt-profiles specific to different STMS markers.
A) melt-profiles of three STMS markers specific to wheat A-genome, B) melt-profiles of three STMS markers specific to wheat B-genome, C) melt-profiles of three STMS markers specific to wheat D-genome, and D) melt-profiles of three rice STMS markers. The STMS markers were amplified using a representative genotype. Designation of STMS is indicated on upper left corner of each plot and the Tm is indicated by vertical dashed line.

Results show that the melt-profiles can be useful to differentiate several STMS markers from one another. Several pairs of wheat STMS markers could be differentiated based on the melt-profiles such as: Xgwm 459–6A (77.7 °C) and Xgwm 160–4A (83 °C), Xgwm 459–6A (77.7 °C) and Xgwm 304–5A (90.5 °C), Xgwm 459–6A (77.7 °C) and Xgwm 155–3A (84.5 °C), Xgwm 459–6A (77.7 °C) and Xgwm 135–1A (87.5 °C), Xgwm 459–6A (77.7 °C) and Xgwm 356–2A (92.5 °C), Xgwm 264–1B (80.8 °C) and Xgwm 165–4B (88.5 °C), Xgwm 368–4B (75.5 °C) and Xgwm 66–4B (88.5 °C), Xgwm 368–1B (75.5 °C) and Xgwm 210–2B (85.5 °C), Xgwm 320–2D (82.5 °C) and Xgwm 111–7D (89.5 °C), Xgwm 320–2D (82.5 °C) and Xgwm 174–5D (90.5 °C), Xgwm 320–2D (82.5 °C) and Xgwm 232–1D (91.5 °C), Xgwm 469–6D (82.8 °C) and Xgwm 232–1D (91.5 °C) (Fig 2). These results show that the SYBR Green melt-profiles can be used for gel-less detection of STMS markers, and based on their specific Tm values and melt-curve characteristics many of these can be easily distinguished from one another.

SYBR Green melt-profiling for detecting STMS allele polymorphism

The SYBR Green melt-profiling approach was further evaluated for differentiation between alleles of STMS markers in both wheat and rice, using multiple genotypes (Table 1). Several STMS amplicons exhibited length polymorphism among the wheat (Fig 3A–3H, Table 2) and rice genotypes (Fig 3I and 3J, Table 2).

Fig. 3. Analysis of allelic polymorphism of STMS marker.
Analysis of allelic polymorphism of STMS marker.
Allelic polymorphism of STMS markers among multiple wheat (A-H) and rice (I, J) genotypes on agarose gels: A) Xgwm 282–7A, B) Xgwm 162–3A, C) Xgwm 304–5A, D) Xgwm 169–6A, E) Xgwm 99–1A, F) Xgwm 136–1A, G) Xgwm 135–1A, H) Xgwm 155–3A, I) RM 259, and J) RM 447. Numbers on the top indicates the wheat (A-H) and rice (I, J) genotypes as mentioned in the Table 1. Lane ‘M’ indicates 100 bp DNA ladder.

In addition, both wheat and rice STMS showed few cases of monomorphic alleles (Xgwm 135–1A, Xgwm 357–1A) or null alleles (Xgwm 162–3A, Xgwm 169–6A, Xgwm 264–1B, Xgwm 368–4B) (Fig 3, S3 Fig, Table 2). Alleles of sixteen wheat STMS and seven rice STMS markers were subjected to SYBR Green melt-profiling to assess its utility in differentiating them. The melt-profiles were compared for variation in Tm, profile shape or both. Among the twelve wheat genotypes Xgwm 162–3A, showed single type allele or null allele (Fig 4A), while Xgwm 304–5A showed two distinct allelic profiles with minor difference in Tm (Fig 4B). Similarly, STMS maker Xgwm 169–6A showed three profiles and a null allele, (Fig 4C), Xgwm 282–7A showed four profiles and a null allele (Fig 4D), and Xgwm 448–2A showed four profiles with variable features (Fig 4E). Multiple allele specific melt-profiles were also obtained for of STMS RM 447 among twelve rice genotypes (Fig 4F).

Fig. 4. STMS allele differentiation by SYBR Green melt-profiling.
STMS allele differentiation by SYBR Green melt-profiling.
SYBR Green melt-profiles of alleles of STMS markers among twelve wheat (A-E) and rice (F) genotypes: A) wheat STMS Xgwm 162–3A, B) wheat STMS Xgwm 304–5A, C) wheat STMS Xgwm 169–6A, D) wheat STMS Xgwm 282–7A, E) wheat STMS Xgwm 448–2A, and F) rice STMS RM 447. Multiple melt-profiles of STMS marker alleles (indicative of variation in Tm and curve shape difference) are indicated by number (1–4) while null alleles (if any) are indicated by arrows.

Allelic differentiation capability of SYBR Green melt-profiling was evaluated for six STMS markers that show low/no length polymorphism (allelic homoplasy) on agarose gel (S3 Fig). The SYBR Green melt-profiles could differentiate (on basis of Tm or curve shape or both) STMS alleles of certain markers with low or no allelic variability on gels, in wheat (Fig 5A and 5B) and rice (Fig 5C and 5D). Collectively, these results show the feasibility of differentiation of STMS alleles by melt-profiling, where a null allele can be differentiated in a straightforward manner, while others can be differentiated on the basis of Tm, melt-profile characteristics or both.

Fig. 5. SYBR Green melt-profiles of STMS with low length polymorphism.
SYBR Green melt-profiles of STMS with low length polymorphism.
SYBR Green melt-profiles of STMS marker alleles that showed low/no length polymorphism among twelve wheat genotypes: A) Xgwm 357–1A and B) Xgwm 232–1D. SYBR Green melt-profiles of STMS marker alleles that showed low/no length polymorphism among twelve rice genotypes: C) RM 154 and D) RM 431. Numbers indicate the profiles obtained for each STMS along with the corresponding Tm values.

SYBR Green melt-profiling based multiplexing of STMS markers

Feasibility of SYBR Green melt-profiling for multiplex analysis was evaluated for STMS marker pairs that showed non-overlapping melt-profiles with melting temperature difference (ΔTm) of > 5 °C. Several such wheat STMS marker pairs were optimized for multiplex PCR (S4 Fig). The multiplexed STMS products when subjected to SYBR Green melt-profiling yielded distinct signal peaks specific to individual STMS that were included in the multiplex assay. SYBR Green multiplex melt-profiles of three pairs of wheat STMS markers with ΔTm > 5 °C (Xgwm 162–3A+Xgwm 155–3A, Xgwm 160–4A+Xgwm 356–2A, Xgwm 160–4A+Xgwm 304–5A) are shown in Fig 6A. Multiplex analysis was also carried out for six rice STMS pairs, of which three with ΔTm > 5 °C (RM 259+RM 154, RM 413+RM 154, RM4 31+RM 154) are shown in Fig 6B. Results showed that STMS marker pairs with ΔTm of ≥ 5 °C can yield well resolved peaks. Furthermore, STMS marker pairs (RM 431+RM 447, RM 447+RM 514, RM 447+ RM 413) with ΔTm value < 5 °C also showed STMS marker specific peaks but not completely resolved (Fig 6C). This demonstrates the feasibility of SYBR Green melt-profiling for STMS multiplex assay, thereby extending the utility of GLADS approach. However, multiplexing was not feasible for markers with overlapping melt-profiles or low ΔTm value.

Fig. 6. Multiplex STMS analysis.
Multiplex STMS analysis.
SYBR Green melt-profiles generated in multiplex PCR of STMS marker pairs in wheat and rice: A) multiplex analysis of three pair of wheat STMS markers with ΔTm > 5 °C, B) multiplex analysis of three pair of rice STMS markers with ΔTm > 5 °C, C) multiplex analysis of three pair of rice STMS markers with ΔTm < 5 °C. ΔTm is ‘melting temperature difference’. Designation of STMS used in multiplex assays are shown in each melt-profile plot and arrows indicate the STMS specific peaks.

Discussion

This study shows the utility of SYBR Green dye based melt-profiling as a simple, convenient and low-cost gel-less approach for detection of STMS markers (referred to as GLADS). Crop-breeding involves multiple experiments (executed in parallel and involve large populations) that are routinely carried out using laborious and time-consuming conventional methodologies. DNA maker assisted selection (MAS) allow rapid screening of linked desirable traits and reduce overall breeding time [17], Among the PCR markers, STMS are preferable in breeding experiments due to their co-dominant nature, high abundance, wide genome coverage, and transferability [1415,18]. At present, most STMS studies primarily rely on low-throughput, laborious, and time-consuming agarose or polyacrylamide gels [4043]. This is an important concern while handling large crop populations [17,44], thereby limiting the full potential of the STMS based MAS.

Several gel-free STMS detection methods have been reported, however many of these are either technically intensive or rely on specialized consumables/hardware/software that makes these expensive for large scale analysis as in crop breeding (S2 Table). The marker screening approach need to be technically simple, convenient, breeder friendly and cost effective for analysis of large experimental populations [4,45]. SYBR Green based GLADS approach reported here addresses such these concerns for easy STMS analysis. Many previously reported STMS detection methods are often technically intensive and economically not viable for large scale usage. For example, STMS analysis using fluorescently labeled primers automate the scoring but high cost of labeling, expensive detection systems comprise major negative factors [28,29]. Similarly, capillary electrophoresis for automated and high-throughput analysis [27] also need specialized instrumentation and consumables resulting in high running cost (S2 Table). Sensitive approaches like TaqMan assays, molecular beacons, scorpions probes are more appropriate for small scale studies, and some of these require primers to be redesigned for effective detection [6,4648]. Similarly, utility of HRM has also been shown for diverse applications including STMS analysis [12,32,4953]. it uses expensive dyes, may require primer resigning, and rely on specific real-time hardware/software that might have limited its widespread usage [34]. The present GLADS approach, on the other hand simplifies the detection using a convenient, user friendly and relatively simple setup using already available primers.

For two major aspects of DNA marker work (development of new and use of available markers), convenience and cost-effectiveness of an approach ensure its easy adoption and widespread use. For example, in several MAS experiments, tightly linked STMS (to a trait) are often ascertained on gel-based methods for several generations [38,5457]. In such cases, the GLADS approach offer a simple, convenient gel-less STMS detection alternative. It can be effective in utilization of available STMS markers linked to important traits in wheat (http://maswheat.ucdavis.edu/protocols/index.htm), rice (http://www.ricebase.org/ http://www.gramene.org) and other crops. This SYBR Green based approach ascertains the presence/absence of STMS and differentiates STMS markers/alleles solely by melting-profiles, in a gel-free manner.

DNA binding dyes (ethidium bromide, SYBR Green, LC Green etc.) can be utilized for STMS detection in a post-PCR end-point assay. Hernández and coworkers demonstrated in-tube detection of STMS by addition of ethidium bromide directly in the PCR tubes [31]. However, the end-pint assays cannot differentiate the specific signal (due to an amplicon) from false non-specific signal (due to primer-dimers, unused primers and template). Additionally, ethidium bromide has lower sensitivity, inhibits PCR and is carcinogenic in nature. The present two-step approach first optimized the use of SYBR Green (more sensitive and safe dye than ethidium bromide) in the PCR step, followed by a melt-profiling step to ascertain the signal specificity. The melt-profiling allows differentiation of amplicon specific and non-specific signal [19,46,58], which is not feasible in an end-point method [24]. The SYBR Green based GLADS is flexible in execution: the dye can be included in the PCR assay mix and the samples can be subjected to post-PCR melt-profiling, with complete analysis on a real-time PCR or alternatively the PCR can be performed on a regular machine followed by addition of dye and melt-profiling on a real-time PCR instrument.

Real time PCR assays for gene expression analysis carry out melt-profiling to assess amplicon specificity [34,59,60], while GLADS uses it for STMS analysis. Unlike a gel that analyzes amplicons for length polymorphism, the melt-profiles reflect variation due to a combination of length, %GC, secondary structures [61], and generate marker-specific profiles useful for gel-less analysis. It is a sensitive and useful assay but needs to be optimized to minimize non-specific interference due to certain parameters. The non-specific binding of SYBR Green is affected by salt concentration, and DNA composition [61,62]. It may also show inhibitory effect on PCR [63]. Optimized melt-profiling assay show lower problems due to non-specific peaks and spikes [59], as also seen in the present study. The SYBR Green melt-profiling for STMS detection was also helpful for allele differentiation, which is important in cases where a particular allele is linked to a desirable trait [11,12]. The assay differentiated between a STMS allele (signal peak) and a null allele (no signal peak) in a straightforward manner and showed capability to detect polymorphism among STMS alleles. However, discrimination was not feasible between alleles with overlapping melt curves.

Present approach is cost-effective and saves time as evident from the comparison of several approaches for STMS analysis (S2 Table). For example, analysis of 96–384 samples (on a Roche LC 480 II or other high-throughput systems) can be completed in 30 minutes which is considerably faster than traditional gel based methods. It is economical (20–51% lower cost) than several other gel and non-gel based methods (S2 Table). For analysis of large number of markers/experimental samples cost of analysis is a critical factor. The economy of the SYBR Green melt-profiling is enhanced by multiplexing that further reduces the cost, time and efforts [present study, 19,56]. Multiplex PCR often require re-designed primers, however in the present study it was successfully carried out for STMS marker pairs showing non-overlapping melt-profiles (ΔTm > 3.0 °C), using existing primer combinations.

Due to simple and low cost, the SYBR Green melt-profiling assays have been utilized in various studies viz. pathogen identification [64], analysis of ISBP (insertion site-based polymorphism) markers [36], SCAR marker detection [19], and SNP marker analysis [65,66]. Present study further extends the scope of simple SYBR Green melt-profiling approach for gel-less detection of STMS markers. The usage of real-time PCR based marker analysis is limited to small numbber of crop breeding studies viz. hybridization probes based analysis [67], oleic acid content linked maker analysis [8], HRM analysis [68,69], primarily due to high cost associated with the consumables used. Simplified approaches like SYBR Green based GLADS can enhance the usage of real-time PCR based analysis in crop breeding experiments for markers like STMS (this study) and SCARs [19], which is otherwise mostly restricted to analysis of gene expression [34] and ascertaining transgene copy number [70].

Overall, use of GLADS for STMS analysis is more advantageous than cumbersome long-format polyacrylamide or high-resolution agarose gels. It is more convenient, economical and breeder friendly than alternative technologically intensive or expensive methods for crop breeding applications. GLADS can be used as a stand lone approach or it can be a part of an integrated STMS analysis scheme. It can be employed initially to assess the STMS suitable for melt-profiling analysis. Such markers can be directly analyzed by GLADS approach, while remaining can be scored by alternative approaches or a combination of methods. The approach will be useful in specialized applications such as, MAS (use single trait-linked STMS marker) and MABB (involve scoring of several STMS markers for background and foreground selection), in wheat, rice and other crops.

Conclusions

The GLADS approach combined the simplicity of PCR, sensitivity of SYBR Green, and informativeness of melt-profiles for a simple, rapid and effective assay for various types of STMS analysis viz. detection/scoring, differentiation, allelic polymorphism, and multiplex analysis. It is relatively economical (20–51% lower cost than other approaches) and can be performed on a routine real-time PCR and without any specialized consumables/hardware/software requirements. The efficacy of GLADS can be assessed during initial phase of STMS analysis, and it can be integrated with existing methods. GLADS based STMS analysis seems a promising approach to reduce the dependence on cumbersome gel-based detection approaches in wheat, rice as well as other crops.

Supporting information

S1 Fig [tif]
Gradient PCR assay.

S2 Fig [c]
Effect of annealing temperature on SYBR Green melt-profiles.

S3 Fig [tif]
Analysis of STMS alleles on agarose gel.

S4 Fig [tif]
STMS multiplex analysis.

S1 Table [docx]
List of STMS markers specific to wheat (A, B, and D-genome) and rice analyzed in the present study.

S2 Table [docx]
Comparison of approximate cost (in USD), time of analysis, and other important aspects of SYBR Green based approach and few other techniques for STMS marker detection.


Zdroje

1. Appels R, Lagudah ES. Manipulation of chromosomal segments from wild wheat for the improvement of bread wheat. Funct Plant Biol. 1990;17: 253–266.

2. Calderini DF, Slafer GA. Has yield stability changed with genetic improvement of wheat yield? Euphytica. 1999;107: 51–59.

3. Fleury D, Delannay X, Langridge P. Quantitative Trait Loci and Breeding. In: John Wiley & Sons, Ltd, editor. eLS. Chichester, UK: John Wiley & Sons, Ltd; 2012. http://doi.wiley.com/10.1002/9780470015902.a0023712.

4. Kumar LS. DNA markers in plant improvement: an overview. Biotechnol Adv. 1999;17: 143–182. 14538138

5. Kalendar R, Schulman AH. IRAP and REMAP for retrotransposon-based genotyping and fingerprinting. Nat Protoc. 2006;1: 2478–2484. doi: 10.1038/nprot.2006.377 17406494

6. Semagn K, Babu R, Hearne S, Olsen M. Single nucleotide polymorphism genotyping using Kompetitive Allele Specific PCR (KASP): overview of the technology and its application in crop improvement. Mol Breed. 2014;33: 1–14. doi: 10.1007/s11032-013-9917-x

7. Appleby N, Edwards D, Batley J. New Technologies for Ultra-High Throughput Genotyping in Plants. In: Gustafson JP, Langridge P, Somers DJ, editors. Plant Genomics. Totowa, NJ: Humana Press; 2009. pp. 19–39. http://link.springer.com/10.1007/978-1-59745-427-8_2.

8. Mienie CMS, Pretorius AE. Application of marker-assisted selection for ahFAD2A and ahFAD2B genes governing the high-oleic acid trait in South African groundnut cultivars (Arachis hypogaea L.). Afr J Biotechnol. 2013;12: 4283.

9. Tsilo TJ, Jin Y, Anderson JA. Diagnostic Microsatellite Markers for the Detection of Stem Rust Resistance Gene in Diverse Genetic Backgrounds of Wheat. Crop Sci. 2008;48: 253. doi: 10.2135/cropsci2007.04.0204

10. Randhawa HS, Mutti JS, Kidwell K, Morris CF, Chen X, Gill KS. Rapid and targeted introgression of genes into popular wheat cultivars using marker-assisted background selection. PLoS One. 2009;4: e5752. doi: 10.1371/journal.pone.0005752 19484121

11. Jaiswal S, Sheoran S, Arora V, Angadi UB, Iquebal MA, Raghav N, et al. Putative Microsatellite DNA Marker-Based Wheat Genomic Resource for Varietal Improvement and Management. Front Plant Sci. 2017;8. doi: 10.3389/fpls.2017.02009 29234333

12. Distefano G, Caruso M, La Malfa S, Gentile A, Wu S-B. High Resolution Melting Analysis Is a More Sensitive and Effective Alternative to Gel-Based Platforms in Analysis of SSR–An Example in Citrus. Niedz RP, editor. PLoS ONE. 2012;7: e44202. doi: 10.1371/journal.pone.0044202 22957003

13. Yan Z, Wu F, Luo K, Zhao Y, Yan Q, Zhang Y, et al. Cross-species transferability of EST-SSR markers developed from the transcriptome of Melilotus and their application to population genetics research. Sci Rep. 2017;7. doi: 10.1038/s41598-017-18049-8 29263338

14. Vieira MLC, Santini L, Diniz AL, de Munhoz CF. Microsatellite markers: what they mean and why they are so useful. Genet Mol Biol. 2016;39: 312–328. doi: 10.1590/1678-4685-GMB-2016-0027 27561112

15. Kuleung C, Baenziger PS, Dweikat I. Transferability of SSR markers among wheat, rye, and triticale. Theor Appl Genet. 2004;108: 1147–1150. doi: 10.1007/s00122-003-1532-5 15067402

16. Varshney RK, Sigmund R, Börner A, Korzun V, Stein N, Sorrells ME, et al. Interspecific transferability and comparative mapping of barley EST-SSR markers in wheat, rye and rice. Plant Sci. 2005;168: 195–202. doi: 10.1016/j.plantsci.2004.08.001

17. Collard BC., Mackill DJ. Marker-assisted selection: an approach for precision plant breeding in the twenty-first century. Philos Trans R Soc B Biol Sci. 2008;363: 557–572. doi: 10.1098/rstb.2007.2170 17715053

18. Gupta PK, Rustgi S, Mir RR. Array-based high-throughput DNA markers for crop improvement. Heredity. 2008;101: 5–18. doi: 10.1038/hdy.2008.35 18461083

19. Vishwakarma G, Saini A, Das BK, Bhagwat SG, Jawali N. Rapid and convenient gel-free screening of SCAR markers in wheat using SYBR green-based melt-profiling. Plant Breed. 2016;135: 643–653. doi: 10.1111/pbr.12415

20. Taheri S, Lee Abdullah T, Yusop M, Hanafi M, Sahebi M, Azizi P, et al. Mining and development of novel ssr markers using next generation sequencing (Ngs) data in plants. Molecules. 2018;23: 399. doi: 10.3390/molecules23020399 29438290

21. Cheng J, Zhao Z, Li B, Qin C, Wu Z, Trejo-Saavedra DL, et al. A comprehensive characterization of simple sequence repeats in pepper genomes provides valuable resources for marker development in Capsicum. Sci Rep. 2016;6. doi: 10.1038/srep18919 26739748

22. Varshney R, Graner A, Sorrells M. Genomics-assisted breeding for crop improvement. Trends Plant Sci. 2005;10: 621–630. doi: 10.1016/j.tplants.2005.10.004 16290213

23. Ma W, Zhang W, Gale KR. Multiplex-PCR typing of high molecular weight glutenin alleles in wheat. Euphytica. 2003;134: 51–60.

24. Hernández P, Dorado G, Cabrera A, Laurie DA, Snape JW, Martín A. Rapid verification of wheat–introgressions by direct staining of SCAR, STS, and SSR amplicons. Genome. 2002;45: 198–203. doi: 10.1139/g01-087 11908662

25. Heid CA, Stevens J, Livak KJ, Williams PM. Real time quantitative PCR. Genome Res. 1996;6: 986–994. doi: 10.1101/gr.6.10.986 8908518

26. Dong C, Vincent K, Sharp P. Simultaneous mutation detection of three homoeologous genes in wheat by High Resolution Melting analysis and Mutation Surveyor®. BMC Plant Biol. 2009;9: 143. doi: 10.1186/1471-2229-9-143 19958559

27. Vemireddy LR, Archak S, Nagaraju J. Capillary Electrophoresis Is Essential for Microsatellite Marker Based Detection and Quantification of Adulteration of Basmati Rice (Oryza sativa). J Agric Food Chem. 2007;55: 8112–8117. doi: 10.1021/jf0714517 17867634

28. Agarwal M, Shrivastava N, Padh H. Advances in molecular marker techniques and their applications in plant sciences. Plant Cell Rep. 2008;27: 617–631. doi: 10.1007/s00299-008-0507-z 18246355

29. Schuelke M. An economic method for the fluorescent labeling of PCR fragments. Nat Biotechnol. 2000;18: 233–234. doi: 10.1038/72708 10657137

30. Gupta PK, Rustgi S, Sharma S, Singh R, Kumar N, Balyan HS. Transferable EST-SSR markers for the study of polymorphism and genetic diversity in bread wheat. Mol Genet Genomics. 2003;270: 315–323. doi: 10.1007/s00438-003-0921-4 14508680

31. Helguera M, Khan IA, Kolmer J, Lijavetzky D, Zhong-qi L, Dubcovsky J. PCR Assays for the Cluster of Rust Resistance Genes and Their Use to Develop Isogenic Hard Red Spring Wheat Lines. Crop Sci. 2003;43: 1839. doi: 10.2135/cropsci2003.1839

32. Simko I. High-Resolution DNA Melting Analysis in Plant Research. Trends Plant Sci. 2016;21: 528–537. doi: 10.1016/j.tplants.2016.01.004 26827247

33. Croxford AE, Rogers T, Caligari PDS, Wilkinson MJ. High-resolution melt analysis to identify and map sequence-tagged site anchor points onto linkage maps: a white lupin (Lupinus albus) map as an exemplar. New Phytol. 2008;180: 594–607. doi: 10.1111/j.1469-8137.2008.02588.x 18684160

34. Gachon C, Mingam A, Charrier B. Real-time PCR: what relevance to plant studies? J Exp Bot. 2004;55: 1445–1454. doi: 10.1093/jxb/erh181 15208338

35. Sánchez-Pérez R, Ballester J, Dicenta F, Arús P, Martínez-Gómez P. Comparison of SSR polymorphisms using automated capillary sequencers, and polyacrylamide and agarose gel electrophoresis: Implications for the assessment of genetic diversity and relatedness in almond. Sci Hortic. 2006;108: 310–316. doi: 10.1016/j.scienta.2006.02.004

36. Paux E, Faure S, Choulet F, Roger D, Gauthier V, Martinant J-P, et al. Insertion site-based polymorphism markers open new perspectives for genome saturation and marker-assisted selection in wheat. Plant Biotechnol J. 2010;8: 196–210. doi: 10.1111/j.1467-7652.2009.00477.x 20078842

37. Eswaran N, Bhagwat S, Jawali N. A simple method for isolation of DNA from plants suitable for long term storage and DNA marker analysis. BARC Newsl. 2004;249: 208–214.

38. Röder MS, Korzun V, Wendehake K, Plaschke J, Tixier M-H, Leroy P, et al. A microsatellite map of wheat. Genetics. 1998;149: 2007–2023. 9691054

39. McCouch SR. Development and Mapping of 2240 New SSR Markers for Rice (Oryza sativa L.). DNA Res. 2002;9: 199–207. doi: 10.1093/dnares/9.6.199 12597276

40. Pallavi J, Singh A, Rao IU, KV P. Identification, validation of a SSR marker and marker assisted selection for the goat grass derived seedling resistance gene lr28 in wheat. J Plant Pathol Microbiol. 2015;6. doi: 10.4172/2157-7471.1000277

41. Ashkani S, Rafii MY, Rusli I, Sariah M, Abdullah SNA, Abdul Rahim H, et al. SSRs for marker-assisted selection for blast resistance in rice (Oryza sativa L.). Plant Mol Biol Report. 2012;30: 79–86. doi: 10.1007/s11105-011-0315-4

42. Hayden MJ, Kuchel H, Chalmers KJ. Sequence tagged microsatellites for the Xgwm533 locus provide new diagnostic markers to select for the presence of stem rust resistance gene Sr2 in bread wheat (Triticum aestivum L.). Theor Appl Genet. 2004;109: 1641–1647. doi: 10.1007/s00122-004-1787-5 15340687

43. Zhou W-C, Kolb FL, Bai G-H, Domier LL, Boze LK, Smith NJ. Validation of a major QTL for scab resistance with SSR markers and use of marker-assisted selection in wheat. Plant Breed. 2003;122: 40–46. doi: 10.1046/j.1439-0523.2003.00802.x

44. Ma W, Zhang W, Gale KR. Multiplex-PCR typing of high molecular weight glutenin alleles in wheat. Euphytica. 2003;134: 51–60. doi: 10.1023/A:1026191918704

45. Bagge M, Lübberstedt T. Functional markers in wheat: technical and economic aspects. Mol Breed. 2008;22: 319–328. doi: 10.1007/s11032-008-9190-6

46. Monis PT, Giglio S, Saint CP. Comparison of SYTO9 and SYBR Green I for real-time polymerase chain reaction and investigation of the effect of dye concentration on amplification and DNA melting curve analysis. Anal Biochem. 2005;340: 24–34. doi: 10.1016/j.ab.2005.01.046 15802126

47. Gibson NJ. The use of real-time PCR methods in DNA sequence variation analysis. Clin Chim Acta. 2006;363: 32–47. doi: 10.1016/j.cccn.2005.06.022 16182268

48. Singh BD, Singh AK. Marker-assisted plant breeding: principles and practices. New Delhi: Springer; 2015.

49. Li J, Xiong C, He X, Lu Z, Zhang X, Chen X, et al. Using SSR-HRM to Identify Closely Related Species in Herbal Medicine Products: A Case Study on Licorice. Front Pharmacol. 2018;9. doi: 10.3389/fphar.2018.00407 29740326

50. Xanthopoulou A, Ganopoulos I, Koubouris G, Tsaftaris A, Sergendani C, Kalivas A, et al. Microsatellite high-resolution melting (SSR-HRM) analysis for genotyping and molecular characterization of an Olea europaea germplasm collection. Plant Genet Resour. 2014;12: 273–277. doi: 10.1017/S147926211400001X

51. An Jianyu, Yin Mengqi, Zhang Qin, Gong Dongting, Jia Xiaowen, Guan Yajing, et al. Genome Survey Sequencing of Luffa Cylindrica L. and Microsatellite High Resolution Melting (SSR-HRM) Analysis for Genetic Relationship of Luffa Genotypes. Int J Mol Sci. 2017;18: 1942. doi: 10.3390/ijms18091942 28891982

52. Ganopoulos I, Argiriou A, Tsaftaris A. Microsatellite high resolution melting (SSR-HRM) analysis for authenticity testing of protected designation of origin (PDO) sweet cherry products. Food Control. 2011;22: 532–541. doi: 10.1016/j.foodcont.2010.09.040

53. Ganopoulos I, Argiriou A, Tsaftaris A. Adulterations in Basmati rice detected quantitatively by combined use of microsatellite and fragrance typing with High Resolution Melting (HRM) analysis. Food Chem. 2011;129: 652–659. doi: 10.1016/j.foodchem.2011.04.109 30634282

54. Somers DJ, Isaac P, Edwards K. A high-density microsatellite consensus map for bread wheat (Triticum aestivum L.). Theor Appl Genet. 2004;109: 1105–1114. doi: 10.1007/s00122-004-1740-7 15490101

55. Periyannan S, Moore J, Ayliffe M, Bansal U, Wang X, Huang L, et al. The Gene Sr33, an Ortholog of Barley Mla Genes, Encodes Resistance to Wheat Stem Rust Race Ug99. Science. 2013;341: 786–788. doi: 10.1126/science.1239028 23811228

56. Das BK, Saini A, Bhagwat SG, Jawali N. Development of SCAR markers for identification of stem rust resistance gene Sr31 in the homozygous or heterozygous condition in bread wheat. Plant Breed. 2006;125: 544–549. doi: 10.1111/j.1439-0523.2006.01282.x

57. Das B, Saini A, Bhagwat S, Jawali N. Marker assisted selection for stem rust resistance gene Sr24 in Indian wheat genotypes: validation of a SCAR marker. J Genet Breed. 2006;60: 189–196.

58. Li W, Xi B, Yang W, Hawkins M, Schubart UK. Complex DNA melting profiles of small PCR products revealed using SYBR ®$ Green I. BioTechniques. 2003;35: 702–706. doi: 10.2144/03354bm07 14579734

59. Varga A, James D. Real-time RT-PCR and SYBR Green I melting curve analysis for the identification of Plum pox virus strains C, EA, and W: effect of amplicon size, melt rate, and dye translocation. J Virol Methods. 2006;132: 146–153. doi: 10.1016/j.jviromet.2005.10.004 16293321

60. Lipsky R, Mazzanti C, Rudolph J, Xu K, Vyas G, Bozak D, et al. DNA melting analysis for detection of single nucleotide polymorphisms. Clin Chem. 2001;47: 635–644. 11274012

61. Ririe KM, Rasmussen RP, Wittwer CT. Product Differentiation by Analysis of DNA Melting Curves during the Polymerase Chain Reaction. Anal Biochem. 1997;245: 154–160. doi: 10.1006/abio.1996.9916 9056205

62. Arikawa E, Sun Y, Wang J, Zhou Q, Ning B, Dial SL, et al. Cross-platform comparison of SYBR Green real-time PCR with TaqMan PCR, microarrays and other gene expression measurement technologies evaluated in the MicroArray Quality Control (MAQC) study. BMC Genomics. 2008;9: 328. doi: 10.1186/1471-2164-9-328 18620571

63. Zipper H. Investigations on DNA intercalation and surface binding by SYBR Green I, its structure determination and methodological implications. Nucleic Acids Res. 2004;32: e103–e103. doi: 10.1093/nar/gnh101 15249599

64. Meyer N, Lind V, Karlovsky P, Zahn M, Friedt W, Ordon F. Development of a real-time PCR method for the identification of wheat genotypes carrying different eyespot resistance genes. Plant Breed. 2011;130: 16–24. doi: 10.1111/j.1439-0523.2010.01808.x

65. Germer S, Higuchi R. Single-tube genotyping without oligonucleotide probes. Genome Res. 1999;9: 72–78. 9927486

66. Baris I, Etlik O, Koksal V, Ocak Z, Baris ST. SYBR green dye-based probe-free SNP genotyping: Introduction of T-Plex real-time PCR assay. Anal Biochem. 2013;441: 225–231. doi: 10.1016/j.ab.2013.07.007 23872005

67. Barkley NA, Chamberlin KDC, Wang ML, Pittman RN. Development of a real-time PCR genotyping assay to identify high oleic acid peanuts (Arachis hypogaea L.). Mol Breed. 2010;25: 541–548. doi: 10.1007/s11032-009-9338-z

68. Giménez MJ, Pistón F, Martín A, Atienza SG. Application of real-time PCR on the development of molecular markers and to evaluate critical aspects for olive oil authentication. Food Chem. 2010;118: 482–487. doi: 10.1016/j.foodchem.2009.05.012

69. Orsi I, Malatrasi M, Belfanti E, Gullì M, Marmiroli N. Determining resistance to Pseudomonas syringae in tomato, a comparison of different molecular markers. Mol Breed. 2012;30: 967–974. doi: 10.1007/s11032-011-9681-8

70. Huang Y, Yin X, Zhu C, Wang W, Grierson D, Xu C, et al. Standard Addition Quantitative Real-Time PCR (SAQPCR): A Novel Approach for Determination of Transgene Copy Number Avoiding PCR Efficiency Estimation. Alvarez ML, editor. PLoS ONE. 2013;8: e53489. doi: 10.1371/journal.pone.0053489 23308234


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