About the Authors:
Hee-Jong Woo
* E-mail: [email protected]
Affiliation: Biosafety Division, National Academy of Agricultural Science, Rural Development Administration (RDA), Jeonju, Republic of Korea
Yang Qin
Affiliation: Biosafety Division, National Academy of Agricultural Science, Rural Development Administration (RDA), Jeonju, Republic of Korea
Soo-Yun Park
Affiliation: Biosafety Division, National Academy of Agricultural Science, Rural Development Administration (RDA), Jeonju, Republic of Korea
Soon Ki Park
Affiliation: School of Applied Biosciences, Kyungpook National University, Daegu, Republic of Korea
Yong-Gu Cho
Affiliation: Department of Crop Science, Chungbuk National University, Cheongju, Republic of Korea
Kong-Sik Shin
Affiliation: Biosafety Division, National Academy of Agricultural Science, Rural Development Administration (RDA), Jeonju, Republic of Korea
Myung-Ho Lim
Affiliation: Biosafety Division, National Academy of Agricultural Science, Rural Development Administration (RDA), Jeonju, Republic of Korea
Hyun-Suk Cho
Affiliation: Biosafety Division, National Academy of Agricultural Science, Rural Development Administration (RDA), Jeonju, Republic of Korea
Introduction
Rice is one of the most important food crops consumed worldwide. Rice is also a good source of vitamin E, an essential lipid-soluble nutrient that consists of four tocopherols and four tocotrienols. Each of these types of compounds has α-, β-, δ-, and γ-forms determined by the number of methyl groups on the chromanol ring. Tocopherols can efficiently quench singlet oxygen and scavenge various radicals, particularly lipid peroxy radicals, thereby terminating lipid peroxidation chain reactions [1, 2]. Tocopherols are important constituents of the human diet and have been shown to aid in immune function [3] and to decrease the risk of a number of degenerative diseases, such as Parkinson’s disease [4] and heart disease [5]. Additionally, recent reports have demonstrated that tocopherols can affect important physiological processes in plants, such as germination, photoassimilate export, growth, and leaf senescence; tocopherols also have antioxidant functions in photosynthetic membranes and play important roles in plant responses to abiotic stresses [6].
In addition to its importance as a source of vitamin E, rice is also an important model system for functional identification of genes in monocots. Several transformation systems have been developed in rice plants using different approaches, such as protoplast transformation, particle bombardment transformation, and Agrobacterium-mediated transformation methods [7–9]. The advantages of Agrobacterium-mediated gene transfer over other methods include the high efficiency of transformation, the ability to transfer relatively large segments of DNA, and the relatively short duration of transformation [10]. Thus, Agrobacterium-mediated methods have become popular in recent years.
In general, antibiotic- or herbicide-resistant genes linked to a transgene have been used as selectable marker genes for the preferential growth of transformed cells in transformation systems. However, once transformation is accomplished, the presence of these resistance genes is no longer necessary and can even be undesirable. Moreover, the presence of selectable marker genes in genetically modified (GM) crops has generated a number of environmental and consumer concerns, despite scientific evidence supporting the safety of GM crops [11]. However, regardless of scientific assurance of the safety of selectable marker genes, consumer acceptance is ultimately the most important element determining the successful commercialization of transgenic plants and products. Therefore, marker gene elimination is desirable in order to alleviate public concerns over the safety of food derived from transgenic crops.
Several strategies have been developed to generate selectable marker-free transgenic plants genes using different transformation systems. These strategies include co-transformation, site-specific recombination, transposon-based methods, and intrachromosomal homologous recombination [11–14]. The principle of the co-transformation strategy is the introduction of a selectable marker gene and a gene of interest from different T-DNAs. If the two genes are integrated into unlinked loci, subsequent segregation can separate the gene of interest from the selectable marker gene. Marker genes of transgenic plants can also be removed by site-specific recombination systems, such as Cre/lox, FLP/FRT, and R/RS. Several types of site-specific recombination systems function in plants [11]. Among these, the Cre/lox system from bacteriophage P1 has been most extensively used for the generation of marker-free plants. Moreover, strategies for generation of marker-free plants via site-specific recombination systems require either the transient expression of the recombinase gene, crossing with a recombinase-expressing line, or an inducible factor to turn on the expression of the recombinase gene. Among these methods, auto-excision using an inducible promoter has been developed due to the advantages of reduced time requirements of avoidance of crossing procedures. Several inducible systems responsive to external stimuli have been reported for plants. The heat-shock regulated system has been shown to be functional in Arabidopsis [15], tobacco [16], potato [17], maize [18], rice [19], and aspen [20]. The chemically regulated self-excision system, i.e., combination of the Cre gene with the XVE system, has been successfully applied in Arabidopsis [21], rice [22], and tomato [23, 24]. In another FLP/FRT system from Saccharomyces cerevisiae, the selectable marker gene of transgenic tobacco was removed by a stress-inducible FLP/FRT site-specific recombination system [25]. In this system, an oxidative stress-inducible peroxidase (POD) promoter is fused to the recombinase gene FLP. Hydrogen peroxide is then used to induce expression of the recombinase gene, and successful excision of selectable marker genes via hydrogen peroxide-regulated site-specific recombination is achieved. Despite the advantages of temporally regulated recombinase expression, heat-shock or chemically regulated promoters require an external signal to be activated, and the recombination frequencies are greatly dependent on the penetration of the signal into plant cells [26]. Therefore, these systems may be needed further improvements for broad applications in the agricultural industry.
In our present study, we describe the construction of a spontaneous self-excision binary vector using the oxidative-stress inducible mFLP/FRT system for rice transformation. In a recent report, Woo et al. [27] showed that overexpression of NtTC could increase the tocopherol contents in leaves of rice plants. Therefore, for efficient generation of marker-free transgenic rice plants via the spontaneous auto-excision method with enhancement of the tocopherol content of rice seeds, we generated marker-free T1 transgenic rice plants overexpressing NtTC by Agrobacterium-mediated transformation using hygromycin as a selective agent, followed by segregation of selectable marker genes and analysis of tocopherol content.
Materials and Methods
Vector construction and codon optimization
Molecular manipulation methods, such as plasmid DNA isolation, restriction enzyme analysis, ligation of DNA fragments, and transformation of Escherichia coli, were performed as described previously [28]. The binary vectors for this study were constructed as follows. The 6.6-kb backbone DNA fragment for binary vector construction was obtained by polymerase chain reaction (PCR) from the pCAMBIA2301 vector (CAMBIA, Canberra, Australia) with the following primers, incorporating the HindIII and SacI sites: forward primer, 5′-AAGAGCTCAACGTCCGCAATGTGTTATTAAGTTGTCTAAGCG-3′ and reverse primer, 5′-AAAAGCTTGGTGACCAGCTCGAATTTCCCCGA-3′. The 1,817-bp DNA fragment containing the P35S-FRTm-hpt-T35S cassette and 2,964-bp Ppod-FLP-Tnos-MCS cassette were synthesized (Bio Basic Inc., Markham, Canada). The P35S-FRTm-hpt-T35S cassette was excised with SacI and SpeI and inserted into the same restriction enzyme sites of the pBluescript II KS vector (Stratagene, La Jolla, CA). The Ppod-FLP-Tnos-MCS fragment was excised with SpeI and HindIII and subcloned into the SpeI/HindIII site of the pBluescript-P35S-FRTm-hpt-T35S plasmid to generate pBluescript-P35S-FRTm-hpt-T35S-Ppod-FLP-Tnos-MCS. The insertion fragment was then excised from this construct with SacI and HindIII and ligated with the backbone fragment treated with SacI/HindIII restriction enzymes to generate the binary vector pHWMF.
The FLP recombinase gene originated from a 2-μm plasmid in S. cerevisiae. To optimize codon usage, the relative synonymous codon usage (RSUC) values of Oryza sativa and the native FLP gene were calculated using the information obtained from the codon usage database (http://www.kazusa.or.jp/codon/). RSUC values were calculated by dividing the observed codon usage by that expected when all codons for the same amino acids were used equally [29]. The entire mFLP gene was synthesized based on the RSUC values of O. sativa and the codon usage of the rice high-GC gene [30]. The synthetic mFLP gene contained the BglII sites at the 5′ and 3′ ends to facilitate gene exchange. The mFLP gene, excised from the pUC57 vector with BglII, was inserted into the corresponding FLP gene site of the pHWMF vector. The resulting binary expression vector, designated as pCMF, was verified by DNA sequencing and restriction enzyme analysis. The full-length NtTC gene (Genbank accession number KJ645980) was obtained from pMJ102TC [27] by PCR with the following primers incorporating BamHI and HindIII sites: forward primer, 5′-TTGGATCCATGGAGAACATATACGATTTTTCCACCATCTCTTC-3′ and reverse primer, 5′-TTAAGCTTACAGGCCAGGAGGTTTGAGAAATGGAG-3′. The gene was then inserted into MCS of the pCMF vector with BamHI and HindIII, yielding pCMF-TC.
Rice transformation and growth conditions
pCMF-TC was introduced into A. tumefaciens strain LBA4404 for genetic transformation of rice (O. sativa subsp. japonica cv. Dongjin). Rice transgenic plants were generated by the Agrobacterium-mediated cocultivation method [31], and transformants were selected based on hygromycin resistance. The regenerated shoots were transferred to Murashige and Skoog (MS) solid medium for root induction for 2 weeks and then transferred to 0.1% Hyponex solution (Hyponex, Imlay, MI, USA) for 1 week in a culture room for acclimatization. Regenerated plantlets were subsequently transplanted into the soil in pots and grown in a greenhouse. Transgenic rice plants and seeds were sown in a vermiculite and potting soil mixture soaked with water. All plants were grown under white fluorescent light (600 μmol m-2 s-1, 12 h photoperiod) and 75% relative humidity at 28°C in a greenhouse.
PCR analysis
Plant genomic DNA for PCR was isolated from fresh leaves and purified using a DNeasy Plant Mini kit (Qiagen GmbH, Hilden, Germany), according to the manufacturer’s instructions. The DNA concentration was determined using a NanoDrop Spectrophotometer ND-1000 (NanoDrop Technologies, Wilmington, DE, USA) at 260 nm wavelength. A typical 25-μL PCR tube contained 10 ng genomic DNA, 200 nM of each primer, 200 μM dNTPs, 1× PCR buffer, and 1 U Taq DNA polymerase (Takara Bio, Shiga, Japan). The PCR was carried out at 94°C for 5 min, followed by 34 cycles of denaturation at 94°C for 1 min, annealing at 65°C for 1 min, and extension at 72°C for 1 min, with a final extension for 5 min at 72°C using a TProffesional TRIO thermocycler (Biometa, Berlin, Germany). Transgenic plants were analyzed with P35SF (5′-TCAGAAGACCAGAGGGCTATTGAGACTTTTCA-3′) and HPTR (5′-AATTGCCGTCAACCAAGCTCTGATAGAGTTG-3′) primers for transformation and P35SF and TCR (5′-GCAGTCAAAGCAACATCTCCAATCGC-3′) primers for gene excision.
Southern blot analysis
Genomic DNA was isolated from mature leaves of rice using the CTAB DNA extraction method [32]. About 20 μg of total DNA was digested overnight with EcoRV. The digested DNA was separated on 0.8% agarose gels and transferred onto a Hybond-N+ membrane (Amersham Biosciences, Piscataway, NJ, USA). The blot was hybridized with the DIG-labeled probe, and the signal was detected with the Fusion FX imaging system (Vilber Lourmat, Eberhardzell, Germany). DNA probes for hygromycin and the tocopherol cyclase gene were obtained by PCR using the following primers: hpt, 5′-TTCTGATCGAAAAGTTCGACAGCGTCTCC-3′ and 5′-AATTGCCGTCAACCAAGCTCTGATAGAGTTG-3′; and NtTC, 5′-AATTTGAGCACTTTTCCGTCTACCTTGAAGCTG-3′ and 5′-CAGCAGTCAAAGCAACATCTCCAATCGC-3′. DNA probe preparation, hybridization, and membrane washing were performed using a DIG High Prime DNA Labeling and Detection Starter Kit II according to the manufacturer’s instructions (Roche Inc., Mannheim, Germany).
Reverse transcription (RT)-PCR analysis
To examine transgene expression and gene excision, total RNA leaves was extracted from powdered leaf tissue using an RNeasy Mini Kit and on-column DNase treatment according to the manufacturer’s protocol (Qiagen, Valencia, CA, USA). Two micrograms of total RNA was reverse-transcribed using SuperScript II Reverse Transcriptase with oligo(dt) primers (Invitrogen, Carlsbad, CA, USA) according to the manufacturer’s instructions. PCR amplification was carried out for 28–34 cycles using 100 ng of cDNA and gene-specific primers. The primers used to amplify hpt, NtTC, and Tub were as follows: hpt, 5′-TTCTGATCGAAAAGTTCGACAGCGTCTCC-3′ and 5′-AATTGCCGTCAACCAAGCTCTGATAGAGTTG-3′; NtTC, 5′-CAGCAGTCAAAGTAACATCTCCAATCGC-3′ and 5′-AATTTGAGCACTTTTCCGTCTACCTTGAAGCTG-3′; and Tub, 5′-AAGGAGGGAGTGGGTAGAGAGGACACTGTTGTAT-3′ and 5′-TGCTTTCAACACCTTCTTCAGTGAGACTGGTG-3′. PCR was performed under the following conditions: 10 min at 94°C; 28–34 cycles at 94°C for 30 s, 65°C for 30 s, and 72°C for 1 min; and a final extension at 72°C for 10 min.
Seed germination assay
Self-pollinated seeds were harvested from wild-type and T0 transgenic rice plants, surface-sterilized for 10 min in 1.5% sodium hypochloride solution, and rinsed thoroughly (3–4 times) in sterile water. Surface-sterilized seeds were grown on germination medium (MS medium 2% [w/v] sucrose and 0.7% [w/v] agar) containing hygromycin (30 mg L-1) or without any antibiotics. Ten days later, seedlings grown on MS media were evaluated for resistance.
Tocopherol extraction and analysis
Mature seeds harvested from T1 transgenic rice plants and wild-type rice seeds were husked and ground to a fine powder using a stainless-steel planetary ball mill (Pulverisette 6, Fritsch GMBH, Germany). Alpha- and gamma-tocopherol in rice seeds were quantified by gas chromatography (GC) coupled with time-of-flight mass spectrometry (TOF-MS) as described by Park et al. [33]. Quantitative calculations were based on the corrected peak area ratios relative to the peak area of the internal standard (IS). Linearity was tested by least-squares regression analysis of the corrected peak area ratios against increasing weight ratios (relative to IS).
Results
Construction and characteristics of pHWMF, pCMF, and pCMF-TC vectors
The region between the left and right T-DNA borders in the binary vector pHWMF is depicted schematically in Fig 1, in which the hygromycin-selectable marker gene (hpt) and the recombinase gene FLP under the control of the oxidative stress-inducible promoter of the sweet potato were placed between two opposite FRT sites.
[Figure omitted. See PDF.]
Fig 1. Schematic diagram of the T-DNA region of binary vectors for marker elimination and an DNA excised product.
Restriction sites within the MCS were unique digestion sites in the vector. The structure of pCMF was the same to as of pHWMF except that the modified FLP gene was replaced with the native FLP gene. pCMF-TC was derived from inserting the NtTC gene, which is a tocopherol cyclase ortholog isolated from tobacco, into multiple cloning sites of pCMF. After gene excision, the CaMV 35S promoter was inserted adjacent to the NtTC coding region. P35SF, HPTR, and TCR primers were designed to detect the DNA excision. The PCR product amplified with P35SF/TCR would be 1.5 kb if DNA excision occurred and 5.7 kb otherwise. P35S, CaMV 35S gene promoter; hpt, hygromycin phosphotransferase gene; T35S, 35S CaMV gene terminator; Ppod, stress-inducible peroxidase gene promoter; FLP; recombinase gene from Saccharomyces cerevisiae; Tnos: Agrobacterium nopaline synthase gene terminator; MCS, multiple cloning site; LB, left border; RB, right border; NtTC, tocopherol cyclase gene isolated from tobacco; FRT, FLP recognition site.
https://doi.org/10.1371/journal.pone.0132667.g001
The multiple cloning sites contained unique restriction sites, where the gene of interest could be inserted, located between the FRT site and nopaline synthase (nos) gene terminator. The pHWMF vector was constructed with modular components having unique pairs of restriction sites flanking each genetic element within the T-DNA region, enabling the replacement of each of genetic element by equivalent counterparts with ease. Additionally, we used the modified FRT site (FRTm) and one full-length FRT site in the pHWMF vector. Although FRTm contained only two symmetry elements for the FLP protein compared with the full-length FRT sequence having three FLP binding sites, this modification did not substantially affect the function of the FLP recombinase and provided a means to clearly distinguish site-specific recombination products from possible artifacts generated by other genomic DNA modifications [34].
Genes with a high GC content are generally expressed at high levels in rice [30]. Furthermore, codon bias has a significant influence on protein yields. When we compared the codon bias of the native FLP recombinase gene from yeast with the codon usage in coding sequences of O. sativa using the codon usage database, we found distinct differences (Table 1).
[Figure omitted. See PDF.]
Table 1. Differences in codon usage between Oryza sativa, native FLP, and S. cerevisiae and codons used for mFLP gene synthesis.
https://doi.org/10.1371/journal.pone.0132667.t001
For example, proline can be encoded by the codons CCU, CCA, CCC, and CCG. However, the amino acid proline in the native FLP gene was mostly encoded by the triplets CCU and CCA, while CCC and CCG were rare codons. In contrast, CCG was the favored codon for proline in O. sativa and was used significantly more often in high-GC genes than in low-GC genes (GC content < 60%) in the rice genome. Furthermore, the S. cerevisiae FLP gene had a GC content of 37%. In contrast, the nuclear genome of O. sativa has an overall GC content of 43% [35], with coding regions having a GC content of 55% (as determined using the codon usage database). Due to these differences between S. cerevisiae and O. sativa, we synthesized the modified FLP recombinase (mFLP) gene with a bias for preference in high-GC genes of rice. The resulting sequence had a GC content of 61% with 70% DNA homology to the native FRT recombinase gene (S1 Fig). The mFLP gene was substituted with the native FLP gene of the pHWMF vector to generate the pCMF binary vector.
Tocopherol cyclase (TC/VTE1) catalyzes the conversion of 2,3-dimethyl-5-phytyl-1,4-benzoquinone (DMPBQ) to γ-tocopherol (S2 Fig). Previous studies have reported the characterization of NtTC, a tocopherol cyclase ortholog originating from tobacco, and have demonstrated a relative increase in tocopherol content in the leaves of transgenic rice plants upon overexpression of NtTC [27]. To enhance the tocopherol contents of rice seed, the plasmid binary pCMF-TC was constructed as shown in Fig 1 and introduced into A. tumefaciens strain LBA4404 for rice transformation.
Rice transformation and identification of transgenes in T0 rice plants
A total of 14 regenerated rice plants were obtained after Agrobacterium-mediated transformation and hygromycin selection. Gene integration and excision from T-DNA-regenerated rice plants was first verified by PCR with genomic DNA extraction from fresh leaves using P35SF and TCR primers specific for the CaMV 35S promoter and NtTC gene, respectively. The results, shown in Fig 2A, revealed the presence of a PCR band of about 1.5 kb in many regenerated plants; this was consistent with the expected size of the PCR amplicon for the excised T-DNA with the P35S-NtTC fragment. PCR amplification of the full T-DNA without excision did not yield a visible band presumably due to the large size of the amplicon (5,721 bp). To further validate that DNA excision had occurred in the FRT site, the PCR fragments were sequenced, as shown in Fig 2B. The sequencing result showed correct sequences matching the FRTm site and flanked NtTC sequences, as expected from the recombinant T-DNA.
[Figure omitted. See PDF.]
Fig 2. PCR and sequencing analysis for identification of transgenes and gene excision in transgenic T0 plants.
(a) PCR results with the primer pair P35S/TCR using the genomic DNAs prepared from fresh leaves of transgenic plants after regeneration. (b) Sequence analysis to confirm gene excision from the genome of transgenic T0 plants. The PCR fragments amplified using the primers P35S and TCR were sequenced. (c) PCR results with the primer sets P35SF/HTPR and P35SF/TCR using genomic DNAs prepared from the mature leaves of five randomly selected transgenic T0 lines. M, molecular marker. Line numbers are indicated at the top of each lane.
https://doi.org/10.1371/journal.pone.0132667.g002
The regenerated rice plants were planted in a greenhouse, and five lines were then randomly chosen to reconfirm the excision of T-DNA for further analysis. The presence of the integrated T-DNA into the rice genome was reassessed by PCR with the gene specific primer sets P35SF/HTPR and P35SF/TCR. PCR results indicated that the 1,256-bp P35S-hpt fragment could be detected in all of five plant lines, while the 1,480-bp P35S-NtTC fragment was detectable in only two plant lines, indicating that these transgenic lines contained multiple T-DNAs with excised and unexcised sequences. These cotransformed plants were designated TC2 and TC3.
Selection of marker-free transgenic rice plants (T1) expressing a NtTC gene
If a transgenic plant harbored the excised T-DNA and unexcised full T-DNA in unlinked loci, genetic separation of excised marker-less T-DNA from the selectable marker gene may be feasible by segregation in the T1 generation. Therefore, some of T1 progenies from the TC2 and TC3 line were analyzed for the presence of the hph and NtTC transgene by Southern blotting. All five T1 progenies of the TC2 line and three T1 progenies of the TC3 line were randomly chosen, and nontransformed wild-type Dongjin was used as control for Southern blotting. All of these T1 plants exhibited multiple NtTC bands, and progenies of crosses between the TC2 and TC3 lines showed different band patterns representing independent transgenic lines. In addition, a weak 9.4-kb band also appeared in the wild-type strain; this band may have been associated with the endogenous rice tocopherol cyclase gene, which exhibited high similarity with the NtTC probe. In the case of hybridization with the hpt probe, two T1 progeny of the TC2 line (TC2-2 and TC2-3) and one T1 progeny of the TC3 line (TC3-3) did not exhibit a signal, thus confirming complete excision (Fig 3).
[Figure omitted. See PDF.]
Fig 3. Southern blot analysis of T1 progenies of the transgenic lines.
Genomic DNA was digested with EcoRV, which created one cut in pCMF-TC, and hybridized with the DIG-labeled NtTC (a) or hpt (b) probe. M, DIG-labeled molecular marker; P, positive control; lanes 1–5, progenies of the TC2 line; lanes 6–8, progenies of the TC3 line.
https://doi.org/10.1371/journal.pone.0132667.g003
To validate these Southern blotting results, the excision status of T1 rice progeny from transgenic lines TC2 and TC3 was also analyzed by PCR using the P35SF/HTPR and P35SF/TCR primer sets (Fig 4A). PCR analyses indicated the presence of the expected P35S-NtTC fragment and the absence of the P35S-hpt gene in the TC2-2, TC2-3, and TC3-3 lines, consistent with Southern blot analysis data. Moreover, these marker-free rice lines did not exhibit expression of the hpt gene but expressed high levels of NtTC, as shown by RT-PCR analysis (Fig 4B).
[Figure omitted. See PDF.]
Fig 4. Identification of the T-DNA in transgenic rice plants to select marker-free transgenic rice lines.
(a) PCR analysis of T1 transgenic rice plants for marker excision. (b) RT-PCR analysis of NtTC and hpt from leaves of T1 transgenic rice plants. The rice tubulin (tub) gene was used for normalization.
https://doi.org/10.1371/journal.pone.0132667.g004
Next, we determined the hygromycin resistance of T1 seeds of transgenic rice lines. The four transgenic lines confirmed above, in which the hpt gene was excised or existed, were chosen for resistance analysis. Rice seeds derived from the TC2 and TC3 lines that had been selfed were sown on hygromycin-supplemented medium. As shown in Fig 5, the TC2-1 and TC3-1 lines, which were chimeric with excised and unexcised T-DNA loci coexisting in the chromosomal DNA, grew on hygromycin-supplemented medium, while TC2-2 and TC3-3 did not, indicating that the hpt gene was excised successfully by mFLP/FRT-mediated marker gene excision. In addition, transgenic plants grew normally and showed no visually detectable phenotypic differences from nontransgenic wild-type plants in the field and greenhouse.
[Figure omitted. See PDF.]
Fig 5. Germination test of T1 progenies derived from the transgenic lines.
Seeds of the transgenic primary plants and nontransgenic wild-type plants were sown on germination medium containing hygromycin or without antibiotics.
https://doi.org/10.1371/journal.pone.0132667.g005
Tocopherol contents of transgenic rice grains
The TC3-1 transgenic rice line, carrying a single copy of the transgene in its genome, and the untransformed controls were grown in the same field under normal culture conditions, and mature seeds were harvested for determination of tocopherol content using GC coupled with TOF-MS. In rice, β- and δ-tocopherol usually appear in trace amounts, while α-tocopherol and γ-tocotrienol are the most abundant isomers [36,37]. Therefore, these two isomers were not included, and the total tocopherol content is given here as the sum of α- and γ-tocopherol.
The contents of α-, γ-, and total tocopherol in the seeds of wild-type rice plants were 6.57 ± 1.05, 0.39 ± 0.03, and 6.96 ± 1.06 μg/g dry weight, respectively. In the case of the transgenic TC3-1 line, α-, γ-, and total tocopherol levels were approximately 53%, 194%, and 61% higher than those in seeds of wild-type plants (Fig 6; p < 0.01). These results demonstrated that overexpression of NtTC could increase tocopherol levels in rice seeds.
[Figure omitted. See PDF.]
Fig 6. Tocopherol contents from seeds of marker-free transgenic rice plants and wild-type rice plants.
Black and gray bars correspond to transgenic TC3-1 plants and wild-type rice plants. Values are means ± SDs (n = 5), and student’s t tests were used to compare values obtained from transgenic lines to those of the wild-type plants. ** p < 0.01.
https://doi.org/10.1371/journal.pone.0132667.g006
Discussion
Selectable marker genes, such as antibiotic- or herbicide-resistant gene, are powerful selection tools for use in plant transformation processes. However, once transformation is accomplished, the presence of these resistance genes is no longer necessary and can even be undesirable. Therefore, various genetic approaches have been developed to produce marker-free transgenic plants, and several techniques, including cotransformation and auto-excision using site-specific recombination, have been successfully established for the elimination of selectable marker genes [11, 14, 38]. However, these methods still require additional steps or more labor to obtain marker-free transgenic plants, and further improvements are needed for practical application and conventional use. Accordingly, in this study, we developed a spontaneous self-excision binary vector using an oxidative stress-inducible modified FLP/FRT system. This system was successfully applied to produce marker-free transgenic rice plants with enhanced seed tocopherol content.
The oxidative-stress inducible POD promoter from sweet potato was not expressed in any tissues in differentiated plants, but was strongly expressed and induced by environmental stress conditions, including hydrogen peroxide and wounding in cultured cells [39]. Also, spontaneous excision of a marker gene in an oxidative stress-inducible FLP/FRT system was reported in tobacco plants without chemical induction, presumably resulting from activity of the POD promoter in transgenic cells during the transformation process [39].
In this study, in order to develop a simple and convenient method of producing marker-free transgenic rice plants using the oxidative-stress inducible FLP/FRT system, we synthesized the pHWMF vector, in which the site-specific recombinase gene FLP and selectable marker gene hpt were inserted between two FRT sites. The FLP gene was under the control of oxidative-stress inducible POD promoter; thus, both the selectable marker and mFLP genes could be excised spontaneously in the rice callus stage of transformation. However, when the pHWMF vector was introduced into E. coli or A. tumefaciens, weak gene excision was observed in our experiments, possibly due to the expression of the FLP gene driven by leakiness of POD promoter activity. This phenomenon has been reported by other laboratories using chemical- or heat shock-inducible promoters for recombinase gene expression [40] and could be associated with the maintenance of plasmid constructs and transformation efficiency. To solve this problem, the FLP gene was modified based on the codon usage criteria for rice and was altered to have elevated GC content. As a result, pCMF containing the mFLP gene controlled by the POD promoter was stably maintained in E. coli and Agrobacterium (data not shown). Additionally, this modification may contribute to the efficient expression of the construct in rice and other cereals with the same GC content preference.
In Agrobacterium-mediated transformants, transformed T-DNAs are often integrated into different loci in the plant genome, and more than one-third contain a single T-DNA insert, while half contain 2–3 copies and the remainder (about 15%) contain 4–5 copies [41]. The principle of the spontaneous auto-excision strategy doe generation of marker-free transgenic rice plants is the introduction of multiple T-DNAs. If the T-DNAs were integrated into unlinked loci, and gene excision occurred in some of the T-DNAs resulting from stress stimuli during the transformation procedure, excised T-DNA was inherited independently, consequently producing marker-free transgenic plants in the subsequent T1 generation (Fig 7). Although we did not attempt to analyze the excision rates of all regenerated transgenic plants, about half of regenerated plants obtained by hygromycin selection presented a P35S-NtTC fragment, representing the expected PCR amplification band of an excised T-DNA. Moreover, marker-free T1 transgenic rice plants were generated from two T0 transgenic lines among the five transgenic lines analyzed in this study. Thus, this method was effective for production of marker-free transgenic rice plants. Compared with other methods for developing marker-free transgenic plants, this spontaneous auto-excision strategy has various unique advantages. For example, this strategy does not require additional procedures for eliminating the selectable marker gene, such as crossing of the recombinase gene or chemical treatment, and can therefore be applied with general rice transformation methods to obtain marker-free rice plants.
[Figure omitted. See PDF.]
Fig 7. Schematic showing the production of selectable marker-free transgenic rice.
https://doi.org/10.1371/journal.pone.0132667.g007
We attempted to produce the marker-free transgenic rice plants overexpressing NtTC using the pCMF-TC vector in order to verify efficient generation of marker-free transgenic rice plants via the spontaneous auto-excision method and improve the tocopherol content of rice seeds. Tocopherols, which are collectively known as vitamin E, are essential antioxidant components of both human and animal diets, and the main source for the dietary uptake of tocopherols is plants, consumed as seeds, vegetables, fruits, and plant seed oils. Hence, increased levels of tocopherols in rice grains would be greatly beneficial for human health. Here, we demonstrated that overexpression of NtTC under the CaMV 35s promoter resulted in increases levels of total tocopherols by approximately 1.6-fold in T2 seeds of marker-free transgenic rice plants. In addition, γ-tocopherol content was significantly increased by 194% compared to that in wild-type plants. Similar results have also been reported in other transgenic rapeseed plants expressing the TC gene from Arabidopsis or maize; indeed, the seeds of transgenic B. napus plants exhibit significantly enhanced tocopherol content by a factor of 1.6 [42]. Thus, these results implied that TC activity may be the limiting factor for tocopherol biosynthesis, and overexpression of TC influences the total tocopherol content of plants.
In conclusion, the results reported herein demonstrate that the spontaneous auto-excision method using a FLP/FRT recombination system is able to produce marker-free transgenic rice plants with enhanced seed tocopherol content by Agrobacterium-mediated transformation with antibiotic selection. This method is simple and does not require additional procedures to eliminate the selectable marker gene. Hence, this method provides a useful tool for production of marker-free transgenic rice plants. Importantly, this system may also be applicable to other cereals. Additionally, the nutritional enhancement of rice seeds through elevation of tocopherol content coupled with this marker-free strategy may improve human health and public acceptance of GM rice.
Supporting Information
[Figure omitted. See PDF.]
S1 Fig. DNA sequence alignment of the native and modified FLP genes.
The alignment was created using ClustalW2 software with sequences available in the EMBL database. DNA sequences conserved within the alignment are designated with an asterisk (*).
https://doi.org/10.1371/journal.pone.0132667.s001
(TIF)
S2 Fig. Simplified tocopherol biosynthetic pathway.
HGA, homogentisic acid; PDP, phytyl-diphosphate; DMPBQ, 2,3-dimethyl-5-phytyl-1,4-benzoquinone; MPBQ, 2-methyl-6-phytyl-1,4-benzoquinone; HPT/VTE2, homogentisate phytyltransferase; TC/VTE1, tocopherol cyclase; MPBQ MT/VTE3, MPBQ methyltransferase; γ-TMT/VTE4; γ-tocopherol methyltransferase.
https://doi.org/10.1371/journal.pone.0132667.s002
(TIF)
Acknowledgments
This study was supported by a grant from the Research Program for Agricultural Science & Technology Development (Project No. PJ010902) of the National Academy of Agricultural Science and the Next-Generation BioGreen 21 Program (Plant Molecular Breeding Center No. PJ008021), Rural Development Administration, Republic of Korea. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Author Contributions
Conceived and designed the experiments: HJW YGC. Performed the experiments: YQ SYP KSS MHL. Analyzed the data: HJW SYP. Contributed reagents/materials/analysis tools: SKP HSC. Wrote the paper: HJW.
Citation: Woo H-J, Qin Y, Park S-Y, Park SK, Cho Y-G, Shin K-S, et al. (2015) Development of Selectable Marker-Free Transgenic Rice Plants with Enhanced Seed Tocopherol Content through FLP/FRT-Mediated Spontaneous Auto-Excision. PLoS ONE 10(7): e0132667. https://doi.org/10.1371/journal.pone.0132667
1. Bramley PM, Elmadfa I, Kafatos A, Kelly FJ, Manios Y, Roxborough HE, et al. Vitamin E. J Sci Food Agric. 2000; 80: 913–938.
2. Schneider C (2005) Chemistry and biology of vitamin E. Mol Nutr Food Res. 2005; 49: 7–30. pmid:15580660
3. Meydani SN, Barklund MP, Liu S, Meydani M, Miller RA, Cannon JC, et al. Vitamin E supplementation enhances cell-mediated immunity in healthy elderly subjects. Am J Clin Nutr. 1990; 52: 557–563. pmid:2203257
4. De Rijk MC, Breteler MMB, den Breeijen JH, Launer LJ, Grobbee DE, van der Meché FGA, et al. Dietary antioxidants and Parkinson disease. The Rotterdam study. Arch Neurol. 1997; 54: 762–765. pmid:9193212
5. Stampfer MJ, Hennekens CH, Manson JE, Colditz GA, Rosner BSB, Willett WC. Vitamin E consumption and the risk of coronary disease in women. N Engl J Med. 1993; 328: 1444–1449. pmid:8479463
6. Falk J, Munné-Bosch S. Tocochromanol functions in plants: antioxidation and beyond. J Exp Bot. 2010; 61: 1549–1566. pmid:20385544
7. Hayashimoto A, Li Z, Murai N. A polyethylene glycol-mediated protoplast transformation system for production of fertile transgenic rice plants. Plant Physiol. 1990; 93: 857–863. pmid:16667593
8. Chan MT, Chang HH, Ho SL, Tong WF, Yu SM. Agrobacterium-mediated production of transgenic rice plants expressing a chimeric alpha-amylase promoter/beta-glucuronidase gene. Plant Mol Biol. 1993; 22: 491–506. pmid:8392395
9. Christou P. Particle bombardment. Methods Cell Biol. 1995; 50: 375–382. pmid:8531809
10. Gelvin SB. Agrobacterium-mediated plant transformation: the biology behind the “gene-jockeying” tool. Microbiol Mol Biol Rev. 2003; 67: 16–37. pmid:12626681
11. Miki B, McHugh S. Selectable marker genes in transgenic plants: applications, alternatives and biosafety. J Biotechnol. 2004; 107: 193–232. pmid:14736458
12. Puchta H. Marker-free transgenic plants. Plant Cell Tiss Organ Cult. 2003; 74: 123–134.
13. Darbani B, Eimanifar A, Stewart CN, Camargo WN. Methods to produce marker-free transgenic plants. Biotechnol J. 2007; 2: 83–90. pmid:17167767
14. Woo HJ, Suh SC, Cho YG. Strategies for developing marker-free transgenic plants. Biotechnol Bioprocess Eng. 2011; 16: 1053–1064.
15. Hoff T, Schnorr KM, Mundy J. A recombinase-mediated transcriptional induction system in transgenic plants. Plant Mol Biol. 2001; 45: 41–49. pmid:11247605
16. Wang Y, Chen B, Hu Y, Li J, Lin Z. Inducible excision of selectable marker gene from transgenic plants by the Cre/lox site-specific recombination system. Transgenic Res. 2005; 14: 605–614. pmid:16245151
17. Cuellar W, Gaudin A, Solorzano D, Casas A, Nopo L, Chudalayandi P, et al. Self-excision of the antibiotic resistance gene nptII using a heat inducible Cre-loxP system from transgenic potato. Plant Mol Biol. 2006; 62: 71–82. pmid:16912912
18. Zhang W, Subbarao S, Addae P, Shen A, Armstrong C, Peschke V, et al. Cre/lox mediated marker gene excision in transgenic maize (Zea mays L.) plants. Theor Appl Genet. 2003; 107: 1157–1168. pmid:14513214
19. Khattri A, Nandy S, Srivastava V. Heat-inducible Cre-lox system for marker excision in transgenic rice. J Biosci. 2011; 36: 37–42. pmid:21451246
20. Fladung M, Becker D. Targeted integration and removal of transgenes in hybrid aspen (Populus tremula L. x P. tremuloides Michx.) using site-specific recombination systems. Plant Biol. 2010; 12: 334–340. pmid:20398239
21. Zuo J, Niu QW, Moller SG, Chua NH. Chemical-regulated, site-specific DNA excision in transgenic plants. Nat Biotechnol. 2001; 19: 157–161. pmid:11175731
22. Sreekala C, Wu L, Gu Wang D, Tian D. Excision of a selectable marker in transgenic rice (Oryza sativa L.) using a chemically regulated Cre/loxP system. Plant Cell Rep. 2005; 24: 86–94. pmid:15662501
23. Zhang Y, Li H, Ouyang B, Lu Y, Ye Z. Chemical-induced autoexcision of selectable markers in elite tomato plants transformed with a gene conferring resistance to lepidopteran insects. Biotechnol Lett. 2006; 28: 1247–1253. pmid:16802102
24. Zhang Y, Liu H, Li B, Zhang JT, Li Y, Zhang H. Generation of selectable marker-free transgenic tomato resistant to drought, cold and oxidative stress using the Cre/loxP DNA excision system. Transgenic Res. 2009; 18: 607–619. pmid:19263233
25. Woo HJ, Cho HS, Lim SH, Shin KS, Lee SM, Lee KJ, et al. Auto-excision of selectable marker genes from transgenic tobacco via a stress inducible FLP/FRT site-specific recombination system. Transgenic Res. 2009; 18: 455–465. pmid:19160066
26. Kopertekh L, Schiemann J. Elimination of transgenic sequences in plants by Cre gene expression. In Çiftçi Y Özden, editor. Transgenic Plants: Advances and limitations. InTech: Rijeka, Croatia; 2012. pp. 449–468.
27. Woo HJ, Sohn SI, Shin KS, Kim JK, Kim BG, Lim MH. Expression of tobacco tocopherol cyclase in rice regulates antioxidative defense and drought tolerance. Plant Cell Tiss Organ Cult. 2014; 119: 257–267.
28. Sambrook J, Maccallum P, Russel D. Molecular cloning: a laboratory manual. 3nd ed. NY: Cold Springs Harbour Press; 2001.
29. Sharp PM, Li WH. On the rate of DNA sequence evolution in Drosophila. J Mol Evol. 1989; 28: 398–402. pmid:2501501
30. Guo X, Bao J, Fan L. Evidence of selectively driven codon usage in rice: implications for GC content evolution of Gramineae genes. FEBS Letters. 2007; 581: 1015–1021. pmid:17306258
31. Toki S, Hara N, Ono K, Onodera H, Tagiri A, Oka S, et al. Early infection of scutellum tissue with Agrobacterium allows high-speed transformation of rice. Plant J. 2006; 47: 969–976. pmid:16961734
32. Murray MG, Thompson WF. Rapid isolation of high molecular weight plant DNA. Nucleic Acids Res. 1980; 8: 4321–4325. pmid:7433111
33. Park SY, Lee SM, Lee JH, Ko HS, Kweon SJ, Suh SC, et al. Compositional comparative analysis between insectresistant rice (Oryza sativa L.) with a synthetic cry1Ac gene and its non-transgenic counterpart. Plant Biotechnol Rep. 2012; 6: 29–37.
34. Lyznik LA, Rao KV, Hodges TK. FLP-mediated recombination of FRT sites in the maize genome. Nucleic Acids Res. 1996; 24: 3784–3789. pmid:8871559
35. Delseny M. Towards an accurate sequence of the rice genome. Curr Opin Plant Biol. 2003; 6: 101–105. pmid:12667864
36. Heinemann RJB, Xu Z, Godber S, Lanfer-Marquez UM. Tocopherols, tocotrienols and γ-oryzanol contents in japonica and indica subspecies of rice (Oryza sativa L.) cultivated in Brazil. Cereal Chem. 2008; 85: 243–247.
37. Zhang GY, Liu RR, Xu G, Zhang P, Li Y, Tang KX, et al. Increased α-tocotrienol content in seeds of transgenic rice overexpressing Arabidopsis γ-tocopherol methyltransferase. Transgenic Res. 2013; 22: 89–99. pmid:22763462
38. Yau YY, Stewart CN Jr. Less is more: strategies to remove marker genes from transgenic plants. BMC Biotechnology. 2013; 13:36. pmid:23617583
39. Kim KY, Kwon SY, Lee HS, Hur Y, Bang JW, Kwak SS. A novel oxidative stress-inducible peroxidase promoter from sweet potato: molecular cloning and characterization in transgenic tobacco plants and cultured cells. Plant Mol Biol. 2003; 51: 831–838. pmid:12777043
40. Gidoni D, Srivastava V, Carmi N. Site-specific excisional recombination strategies for elimination of undesirable transgenes from crop plants. In Vitro Cell Dev Biol-Plant 2008; 44: 457–467.
41. Cheng M, Joyce E, Pang S, Zhou H, Hironaka CM, Duncan DR, et al. Genetic transformation of wheat mediated by Agrobacterium tumefaciens. Plant Physiol. 1997; 115: 971–980. pmid:12223854
42. Kumar R, Raclaru M, Schüßeler T, Gruber J, Sadre R, Lühs W, et al. Characterisation of plant tocopherol cyclases and their overexpression in transgenic Brassica napus seeds. FEBS Letters. 2005; 579: 1357–1364. pmid:15733841
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
© 2015 Woo et al. This is an open access article distributed under the terms of the Creative Commons Attribution License: http://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
Abstract
Development of marker-free transgenic plants is a technical alternative for avoiding concerns about the safety of selectable marker genes used in genetically modified (GM) crops. Here, we describe the construction of a spontaneous self-excision binary vector using an oxidative stress-inducible modified FLP/FRT system and its successful application to produce marker-free transgenic rice plants with enhanced seed tocopherol content. To generate selectable marker-free transgenic rice plants, we constructed a binary vector using the hpt selectable marker gene and the rice codon-optimized FLP (mFLP) gene under the control of an oxidative stress-inducible promoter between two FRT sites, along with multiple cloning sites for convenient cloning of genes of interest. Using this pCMF binary vector with the NtTC gene, marker-free T1 transgenic rice plants expressing NtTC were produced by Agrobacterium-mediated stable transformation using hygromycin as a selective agent, followed by segregation of selectable marker genes. Furthermore, α-, γ-, and total tocopherol levels were significantly increased in seeds of the marker-free transgenic TC line compared with those of wild-type plants. Thus, this spontaneous auto-excision system, incorporating an oxidative stress-inducible mFLP/FRT system to eliminate the selectable marker gene, can be easily adopted and used to efficiently generate marker-free transgenic rice plants. Moreover, nutritional enhancement of rice seeds through elevation of tocopherol content coupled with this marker-free strategy may improve human health and public acceptance of GM rice.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer