Micronutrient deficiency results in malnutrition, which is prevalent all over the world and may lead to premature death in women and children (White and Broadley, 2009). Strategies formulated earlier including supplementation and fortified foods were not successful, owing to socio‐economic and technical hurdles (Mayer et al., 2008). The subsequently evolved strategy of biofortification is a viable biotechnological tool to achieve desired results without compromising the agronomical values of crops. Conferring the genetic trait to improve vital nutrient accumulation in the edible parts of staple food crops, such as rice, through metabolic engineering is considered a fast, sustainable and cost‐effective alternative to conventional breeding (Maestre et al., 2017). In earlier reports from our laboratory, enhanced α‐tocopherol levels in the stable transformants of Nicotiana tabacum (Harish et al., 2013a, 2013b) and in Nicotiana benthamiana adopting a transient expression system using A. thaliana tocopherol cyclase (TC) and homogentisate phytyl transferase (HPT) (Sathish et al., 2018) were shown. In the present study, Agrobacterium‐mediated transformation of Indica rice ASD16 with two genes involved in tocopherol biosynthesis, viz., TC and HPT, was carried out and the transgenic plants were analysed for the vitamin E (α‐tocopherol) content.
Mature seed‐derived embryogenic calli were subjected to genetic transformation (Sundararajan et al., 2020) by employing two gene constructs, viz., pCAMBIA 1305.1 harbouring TC and pNutKan harbouring HPT (Fig 1a), individually, and in a co‐transformation system, the calli were infected with both gene constructs. Putative transgenic plants recovered from all three independent experiments were established in a containment facility and no detectable morphological variations were found between the acclimatized NT and the transgenic plants (Fig 1b). Ten plants from all three experiments were taken for initial PCR analysis with the marker genes respective to each gene construct, that is hptII in pCAMBIA 1305.1 TC and nptII in pNutKan HPT. Nine plants harbouring TC, 6 plants harbouring HPT and 7 TC + HPT plants showed positive PCR amplification of the marker genes (data not shown).
Figure 1.
1(a) Maps of binary vectors harbouring TC and HPT mobilized into Agrobacterium strain LBA4404; (b) transgenic lines recovered from genetic transformation experiments hardened in plant containment facility; (c) representative chromatograms of HPLC analysis in T0 and T1 lines harbouring TC and HPT; and (d) quantification of α‐tocopherol in T0 and T1 transgenic rice.
A preliminary GUS histochemical assay for the transgenic lines generated with TC and TC + HPT revealed the formation of blue colour in the leaves and roots of transgenic plants confirming the presence of the GUS gene, whereas no blue coloration was detected in the NT control. PCR analysis of the transgenic plants harbouring individual TC and HPT showed the expected band sizes (1.2 Kb for HPT and 1.4 Kb for TC). With the TC + HPT plants, amplification of both selectable marker genes during the initial PCR analysis was observed. However, in the PCR using gene‐specific primers, among the seven plants, only five showed the presence of both the transgenes (plants subsequently renamed as TH1 to TH5). Southern blot analysis revealed the expected hybridization signals corresponding to HPT (1.2 kb) in all the six plants digested with PstI and NotI, and TC (1.4 kb) in all the nine plants digested with KpnI and BamHI. For the TC + HPT lines, two individual blots were prepared using genomic DNA digested with KpnI and BamHI for TC and PstI and NotI for HPT. The HPT‐probed blot showed a corresponding hybridization signal of 1.2 kb, and a hybridization signal corresponding to 1.4 kb of the TC gene was observed in the TC‐probed blot in all the five transgenic lines demonstrating the stable integration of the transgenes in the plants (data not shown).
Transcript analysis indicated that among the TC plants, TC3, TC4 and TC7 showed significantly higher levels of transgene expression (19.7‐fold, 21‐fold and 20.2‐fold, respectively) as compared to the control. The relative gene expression of HPT lines was found to be higher as compared to TC lines. The quantum increase ranged from 9.5 to 17.0 among HPT lines with HPT4 showing the highest gene expression (26.3‐fold) followed by HPT5 (23.6‐fold increase). Among the TC + HPT lines, TH4 showed maximum gene expression to the tune of 26.7‐fold (HPT) and 32.5‐fold (TC) (data not shown).
Two plants each harbouring TC, HPT and TC + HPT were analysed for α‐tocopherol content in the transgenic leaves by HPLC. The determination of α‐tocopherol in the samples was based on peaks observed at 295 nm with a UV detection lamp. The retention time of the metabolite was confirmed by injecting the authentic standard (Sigma‐Aldrich, St. Louis, MO), and the quantification in transgenic lines was performed accordingly. Results showed that among the TC lines, TC1 showed a 3.26‐fold and TC4 showed a 2.2‐fold increase in α‐tocopherol. The HPT lines showed relatively higher α‐tocopherol content as compared to that of the TC lines, wherein HPT3 showed a 3.5‐fold and HPT2 showed a 2.8‐fold increase in α‐tocopherol. The TC + HPT plants exhibited the highest α‐tocopherol content among all the transgenic lines. Accordingly, the line TH4 showed a 5.3‐fold increase in α‐tocopherol followed by TH3 (4.3‐fold). Subsequently, three lines (TC1, HPT3 and TH4) were chosen for T1 analysis where transgenic plants germinated from T0 seeds showed a segregation ratio of 3:1 confirming the Mendelian pattern of inheritance. Ten samples for each progeny were checked by PCR, and the progenies showed respective positive amplicons for the TC (1.4 kb) and HPT (1.2 kb) and presence of both the genes in the TC + HPT progenies (data not shown).
Subsequently, Southern blot analysis revealed the stable integration of the transgenes in the T1 progenies. Accordingly, the hybridization signals corresponding to the expected sizes of transgenes were detected in all the samples and no hybridization signal was detected in the NT control. qRT‐PCR analysis of the two randomly selected PCR‐positive plants from each gene construct revealed comparable results as that of the T0 plants. The TC + HPT lines showed higher relative gene expression as compared to that of the lines that harbour only one gene. Both TC1 progenies showed a comparable increase to the tune of 8.36‐fold (TC 1‐1) and 11.6‐fold (TC 1‐2), and HPT4 progenies showed a significant increase of 11.26‐fold (HPT 4‐1) and 8.95‐fold (HPT 4‐2). The TC + HPT progeny TH4 showed the highest relative gene expression about 15.35 (TH 4‐1) and 14.80 (TH 4‐2) folds (data not shown). A sample each from T1 progeny that carried TC, HPT and TC + HPT were analysed for their α‐tocopherol content. Results revealed that TC1‐1 showed a 2.7‐fold increase, HPT3‐1 showed an increase of 3.3‐fold and the TC + HPT progeny TH4‐1 showed a 4.1‐fold increase in α‐tocopherol content in the transgenic leaves similar to that of the T0 progenies where the TC + HPT line showed the highest α‐tocopherol as compared to the lines harbouring either TC or HPT (Fig. 1c, d). The transgenic T1 seeds from the selected progenies were assessed for their α‐tocopherol content and a 0.29‐fold increase in the TC + HPT line (TH4‐1) was observed as compared to TC1‐1 (0.12‐fold) and HPT3‐1 (0.18‐fold). Enhanced level of vitamin E in numerous plant species including A. thaliana leaves (4.4‐fold) and seeds (40%), tobacco leaves (5.5‐fold), lettuce (2‐fold), Brassica napus (2.7‐fold) and potato tuber (106%) has been reported utilizing various enzymes of the vitamin E biosynthesis pathway (reviewed by Mène‐Saffrané and Pellaud, 2017). Harish et al., (2013a) proposed that in higher plants, co‐expression of TC and HPT might increase the overall rate of total pathway flux resulting in a higher content of the end products. In summary, successful enhancement of vitamin E in rice was achieved using overexpression of both TC and HPT. Though the accumulation is not significant in the seeds, improvement with a multi‐gene strategy with appropriate endosperm‐specific promoters might offer an attractive model for vitamin E biofortification in rice, which would immensely benefit human nutrition and health care.
Conflict of interest
All authors read, approved the manuscript and declare that there is no conflict of interest.
Author contributions
SS did the experiments and prepared the manuscript. VR and HPS did the experimental analysis. SN contributed to manuscript preparation and data representations. HMC carried out the initial cloning and assisted in manuscript editing. AS contributed to experimental design, technical interpretation and manuscript editing, and SR conceptualized, supervised the research and critically evaluated the manuscript.
Acknowledgements
The author Sathish S acknowledges ICMR, India (No.3/1/2/102/2018‐Nut.) for fellowship support. Hari Priya S thanks DST‐INSPIRE, India, for fellowship support (IF80901). We acknowledge UGC‐SAP (UGC‐SAP‐II:F‐3‐20/2013) and DST‐FIST (DST‐FIST:SR/FST/LSI‐618/2014) for providing infrastructure to carry out this research.
Sundararajan, S. , Rajendran, V. , Sivakumar, H. P. , Nayeem, S. , Mani Chandra, H. , Sharma, A. and Ramalingam, S. (2021) Enhanced vitamin E content in an Indica rice cultivar harbouring two transgenes from Arabidopsis thaliana involved in tocopherol biosynthesis pathway. Plant Biotechnol. J., 10.1111/pbi.13578
Contributor Information
Ashutosh Sharma, Email: asharma@tec.mx.
Sathishkumar Ramalingam, Email: rsathish@buc.edu.in.
References
- Harish, M.C. , Dachinamoorthy, P. , Balamurugan, S. , Murugan, S.B. and Sathishkumar, R. (2013a) Overexpression of homogentisate phytyl transferase (HPT) and tocopherol cyclase (TC) enhances α‐tocopherol content in transgenic tobacco. Biol. Plant. 57(2), 395–400. [Google Scholar]
- Harish, M.C. , Dachinamoorthy, P. , Balamurugan, S. , Murugan, S.B. and Sathishkumar, R. (2013b) Enhancement of α‐tocopherol content through transgenic and cell suspension culture systems in tobacco. Acta Physiol. Plant. 35(4), 1121–1130. [Google Scholar]
- Maestre, M. , Poole, N. and Henson, S. (2017) Assessing food value chain pathways, linkages and impacts for better nutrition of vulnerable groups. Food Policy, 100, 31–39. [Google Scholar]
- Mayer, J.E. , Pfeiffer, W.H. and Beyer, P. (2008) Biofortified crops to alleviate micronutrient malnutrition. Curr. Opin. Plant Biol. 11(2), 166–170. [DOI] [PubMed] [Google Scholar]
- Mène‐Saffrané, L. and Pellaud, S. (2017) Current strategies for vitamin E biofortification of crops. Curr. Opin. Biotechnol. 44, 189–197. [DOI] [PubMed] [Google Scholar]
- Sathish, S. , Preethy, K.S. , Venkatesh, R. and Sathishkumar, R. (2018) Rapid enhancement of α‐tocopherol content in Nicotianabenthamiana by transient expression of Arabidopsis thaliana Tocopherol cyclase and Homogentisate phytyl transferase genes. 3 Biotech. 8(12), 485. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Sundararajan, S. , Rajendran, V. , Nayeem, S. and Ramalingam, S. (2020) Physicochemical factors modulate regeneration and Agrobacterium‐mediated genetic transformation of recalcitrant Indica rice cultivars‐ASD16 and IR64. Biocat Agric Biotechnol 24, 101519. [Google Scholar]
- White, P.J. and Broadley, M.R. (2009) Biofortification of crops with seven mineral elements often lacking in human diets–iron, zinc, copper, calcium, magnesium, selenium and iodine. New Phytol. 182(1), 49–84. [DOI] [PubMed] [Google Scholar]