Abstract
Survival and productivity of crop plants under different stress scenarios are critical for sustainable crop production. Crop improvement towards achieving higher yield potentials under multiple stresses requires targeted breeding of crop varieties that can withstand different levels of abiotic and biotic stresses and still produce a reliable yield. In addition to this, many candidate genes have been validated for studying their role in enhancing tolerance levels in crops. Transgenic development with targeted stress tolerance trait manipulation can be a viable approach for attaining multiple stress tolerance. By this method, multilevel stress tolerance can be achieved by either manipulating candidate regulatory genes which can govern the functionality of a range of downstream genes or by adopting multigene stacking approach to pyramid genes in a same genetic background. The careful selection of genes linked to specific traits is the key to achieve marginal increase in productivity under multiple stresses. Diverse genes associated with various cellular tolerance mechanisms act in a concerted manner to impart varying degrees of stress tolerance. It will be highly rewarding if we examine different pathway-linked genes active in the stress scenario under scrutiny. Targeted genetic manipulation to enhance cellular tolerance under stress will be more economically viable if we combine multiple trait regulatory genes by using modern biotechnological tools. The different strategies employed, advantages of simultaneous expression of trait regulatory genes and the resultant crop adaptive mechanisms that are emerging in the recent years are discussed in this chapter.
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References
Abe H, Urao T, Ito T, Seki M, Shinozaki K, Yamaguchi-Shinozaki K (2003) Arabidopsis AtMYC2 (bHLH) and AtMYB2 (MYB) function as transcriptional activators in abscisic acid signaling. Plant Cell 15:63–78
Alves AAC, Setter TL (2004) Response of cassava leaf area expansion to water deficit: cell proliferation, cell expansion and delayed development. Ann Bot 94:605–613
Babitha KC (2012) Development of multiple gene construct with regulatory genes and their functional validation. Ph.D thesis, University of Agricultural Sciences, Bangalore
Babitha KC, Ramu SV, Pruthvi V, Mahesh P, Nataraja KN, Udayakumar M (2013) Co-expression of AtbHLH17 and AtWRKY28 confers resistance to abiotic stress in Arabidopsis. Transgenic Res 22:327–341
Babitha KC, Ramu SV, Nataraja KN, Sheshshayee MS, Udayakumar M (2015a) EcbZIP60, a basic leucine zipper transcription factor from Eleusine coracana L. improves abiotic stress tolerance in tobacco by activating unfolded protein response pathway. Mol Breed 35:181
Babitha KC, Vemanna RS, Nataraja KN, Udayakumar M (2015b) Overexpression of EcbHLH57 transcription factor from Eleusine coracana L. in tobacco confers tolerance to salt, oxidative and drought stress. PLoS One 10(9):e0137098
Bakshi S, Dewan D (2013) Status of transgenic cereal crops: a review. Clon Transgen 3:1
Bos HJ, Tijani-Eniola H, Struik PC (2000) Morphological analysis of leaf growth of maize: responses to temperature and light intensity. NJAS – Wageningen J Life Sci 48(2):181–198
Bouaziz D, Pirrello J, Charfeddine M, Hammami A, Jbir R, Dhieb A et al (2013) Over expression of StDREB1 transcription factor increases tolerance to salt in transgenic potato plants. Mol Biotechnol 54:803–817
Budhagatapalli N, Narasimhan R, Rajaraman J, Viswanathan C, Nataraja KN (2016) Ectopic expression of AtICE1 and OsICE1 transcription factor delays stress-induced senescence and improves tolerance to abiotic stresses in tobacco. J Plant Biochem Biotechnol. doi:10.1007/s13562-015-0340-8
Cai R, Zhao Y, Wang Y, Lin Y, Peng X, Li Q et al (2014) Overexpression of a maize WRKY58 gene enhances drought and salt tolerance in transgenic rice. Plant Cell Tissue Organ Cult 119:565–577
Cai H, Tian S, Dong H, Guo C (2015) Pleiotropic effects of TaMYB3R1 on plant development and response to osmotic stress in transgenic Arabidopsis. Gene 558:227–234
Chen X, Wang Y, Lv B, Li J, Luo L, Lu S et al (2014) The NAC family transcription factor OsNAP confers abiotic stress response through the ABA pathway. Plant Cell Physiol 55:604–619
Comas LH, Becker SR, Cruz VMV, Byrne PF, Dierig DA (2013) Root traits contributing to plant productivity under drought. Front Plant Sci 4:442
Curtis MD, Grossniklaus U (2003) A gateway cloning vector set for high-throughput functional analysis of genes in planta. Plant Physiol 133(2):462–469
Demmig-Adams B, Adams WW III (2006) Photoprotection in an ecological context: the depleted in digalactosyldiacylglycerol. New Phytol 172:11–21
Essemine J, Govindachary S, Joly D, Ammar S, Bouzid A, Carpentier R (2012) Effect of moderate and high light on photosystem II function in Arabidopsis thaliana. Biochim Biophys Acta 1817:1367–1373
Feng X-M, Zhao Q, Zhao L-L, Qiao Y, Xie X-B, Li H-F et al (2012) The cold-induced basic helix-loop-helix transcription factor gene MdCIbHLH1 encodes an ICE-like protein in apple. BMC Plant Biol 12:22
Gao SQ, Chen M, Xu ZS, Zhao CP, Li L, Xu HJ et al (2011) The soybean GmbZIP1 transcription factor enhances multiple abiotic stress tolerances in transgenic plants. Plant Mol Biol 75:537–553
Hadiarto T, Tran LP (2011) Progress studies of drought-responsive genes in rice. Plant Cell Rep 30:297–310
Halpin C (2005) Gene stacking in transgenic plants – the challenge for 21st century plant biotechnology. Plant Biotechnol J 3:141–155
Hu H, Xiong L (2014) Genetic engineering and breeding of drought-resistant crops. Annu Rev Plant Biol 65:715–741
Huang Q, Wang Y, Li B, Chang J, Chen M, Li K et al (2015) TaNAC29, a NAC transcription factor from wheat, enhances salt and drought tolerance in transgenic Arabidopsis. BMC Plant Biol 15:268
ISAAA (2013) Stacked traits in biotech crops. Pocket K No. 42. http://www.isaaa.org/kc
Jacobsen E, Nataraja KN (2008) Cisgenics – facilitating the second green revolution in India by improved traditional plant breeding. Curr Sci 94(11):1365–1366
Jiang Y, Yang B, Deyholos MK (2009) Functional characterization of the Arabidopsis bHLH92 TF in abiotic stress. Mol Genet Genomics 282:503–516
Joo J, Choi HJ, Lee YH, Kim YK, Song SI (2013) A transcriptional repressor of the ERF family confers drought tolerance to rice and regulates genes preferentially located on chromosome 11. Planta 238:155–170
Kamoshita A, Chandra Babu R, Boopathi NM, Fukai S (2008) Phenotypic and genotypic analysis of drought-resistance traits for development of rice cultivars adapted to rainfed environments. Field Crop Res 109:1–23
Kathuria K, Giri J, Karaba N, Nataraja KN, Murata N et al (2009) Glycine betaine-induced water stress tolerance in codA-expressing transgenic indica rice is associated with up-regulation of several stress responsive genes. Plant Biotechnol J 7:512–526
Lawlor DW (2013) Genetic engineering to improve plant performance under drought: physiological evaluation of achievements, limitations, and possibilities. J Exp Bot 64(1):83–108
Liu H, Zhou X, Dong N, Liu X, Zhang H, Zhang Z (2011) Expression of a wheat MYB gene in transgenic tobacco enhances resistance to Ralstonia solanacearum, and to drought and salt stresses. Funct Integr Genomics 11:431–443
Liu X, Liu S, Wu J, Zhang B, Li X, Yan Y et al (2013) Overexpression of Arachis hypogaea NAC3 in tobacco enhances dehydration and drought tolerance by increasing superoxide scavenging. Plant Physiol Biochem 70:354–359
Liu C, Mao B, Ou S, Wang W, Liu L, Wu Y et al (2014) OsbZIP71,a bZIP transcription factor, confers salinity and drought tolerance in rice. Plant Mol Biol 84:19–36
Liu L, Zhang Z, Dong J, Wang T (2016) Overexpression of MtWRKY76 increases both salt and drought tolerance in Medicago truncatula. Environ Exp Bot 123:50–58
Lu M, Ying S, Zhang DF, Shi YS, Song YC, Wang TY et al (2012) A maize stress-responsive NAC transcription factor, ZmSNAC1, confers enhanced tolerance to dehydration in transgenic Arabidopsis. Plant Cell Rep 31:1701–1711
Lv SL, Lian LJ, Tao PL, Li ZX, Zhang KW et al (2009) Overexpression of Thellungiella halophila H+ −PPase (TsVP) in cotton enhances drought stress resistance of plants. Planta 229:899–910
Mahesh P. (2015) Stacking of upstream regulatory genes to confer abiotic stress tolerance in rice (Oryza sativa). Ph.D thesis, University of Agricultural Sciences, Bangalore
Mamrutha HM, Mogili T, Jhansi Lakshmi K, Rama N, Kosma DK, Udaya Kumar M, Jenks MA, Nataraja KN (2010) Involvement of leaf cuticular wax amount and crystal morphology in regulating post harvest water loss in mulberry (Morus species). Plant Physiol Biochem 48:690–696
Meng X, Wang JR, Wang GD, Liang XQ, Li XD, Meng QW (2015) An R2R3-MYB gene, LeAN2, positively regulated the thermo-tolerance in transgenic tomato. J Plant Physiol 175:1–8
Mittler R (2006) Abiotic stress, the field environment and stress combination. Trends Plant Sci 11(1):15–19
Nagaveni BH (2013) Engineering drought tolerant traits in rice. Ph.D thesis, University of Agricultural Sciences, Bangalore
Naqvi S, Farré G, Sanahuja G, Capell T, Zhu C, Christou P (2010) When more is better: multigene engineering in plants. Trends Plant Sci 15(1):48–56
Niyogi KK, Li XP, Rosenberg V, Jung HS (2005) Is PsbS the site of non-photochemical quenching in photosynthesis? J Exp Bot 56(411):375–382
Parvathi MS, Nataraja KN (2016) Emerging tools, concepts and ideas to track the modulator genes underlying plant drought adaptive traits: an overview. Plant Signal Behav 11:1
Parvathi MS, Sreevathsa R, Rama N, Nataraja KN (2015) Simultaneous expression of AhBTF3, AhNF-YA7 and EcZF modulates acclimation responses to abiotic stresses in rice (Oryza sativa L). Procedia Environ Sci 29:236–237
Patil M, Ramu SV, Jathish P, Rohini S, Reddy PC, Prasad TG, Udayakumar M (2014) Overexpression of AtNAC2 (ANAC092) in groundnut (Arachis hypogaea L.) improves abiotic stress tolerance. Plant Biotechnol Rep 8(2):161–169
Poorter H, Niinemets Ü, Poorter L, Wright IJ, Villar R (2009) Causes and consequences of variation in leaf mass per area (LMA): a meta-analysis. New Phytol 182:565–588
Pruthvi V (2013) Validation of abiotic stress responsive transcription factors by over expression in crop plants. Ph.D thesis, University of Agricultural Sciences, Bangalore
Pruthvi V, Narasimhan R, Nataraja KN (2014) Simultaneous expression of abiotic stress responsive transcription factors, AtDREB2A, AtHB7 and AtABF3 improves salinity and drought tolerance in peanut (Arachis hypogaea L.). PLoS One 9(12):e111152
Qin Y, Tian Y, Liu X (2015) A wheat salinity-induced WRKY transcription factor TaWRKY93 confers multiple abiotic stress tolerance in Arabidopsis thaliana. Biochem Biophys Res Commun 464:428–433
Qiu Y, Yu D (2009) Over-expression of the stress-induced OsWRKY45 enhances disease resistance and drought tolerance in Arabidopsis. Environ Exp Bot 65:35–47
Ramegowda V, Senthil-Kumar M, Nataraja KN, Reddy MK, Mysore KS, Udayakumar M (2012) Expression of a finger millet transcription factor, EcNAC1, in tobacco confers abiotic stress-tolerance. PLoS One 7(7):e40397
Rampino P, Pataleo S, Gerardi C, Mita G, Perrotta C (2006) Drought stress response in wheat: physiological and molecular analysis of resistant and sensitive genotypes. Plant Cell Environ 29:2143–2152
Ramu VS, Swetha TN, Sheela SH, Babitha CK, Rohini S, Reddy MK, Tuteja N, Reddy CP, Prasad TG, Udayakumar M (2016) Simultaneous expression of regulatory genes associated with specific drought-adaptive traits improves drought adaptation in peanut. Plant Biotechnol J 14:1008–1020
Ravikumar G, Manimaran P, Voleti SR, Subrahmanyam D, Sundaram RM, Bansal KC et al (2014) Stress-inducible expression of AtDREB1A transcription factor greatly improves drought stress tolerance in transgenic indica rice. Transgenic Res 23:421–439
Reguera M, Peleg Z, Blumwald E (2012) Targeting metabolic pathways for genetic engineering abiotic stress tolerance in crops. Biochim Biophys Acta 1819(2):186–194
Rizhsky L, Liang H, Mittler R (2002) The combined effect of drought stress and heat shock on gene expression in tobacco. Plant Physiol 130:1143–1151
Rizhsky L, Liang H, Shuman J, Shulaev V, Davletova S, Mittler R (2004) When defense pathways collide: the response of Arabidopsis to a combination of drought and heat stress. Plant Physiol 134:1683–1696
Rong W, Qi L, Wang A, Ye X, Du L, Liang H et al (2014) The ERF transcription factor TaERF3 promotes tolerance to salt and drought stresses in wheat. Plant Biotechnol J 12:468–479
Saad AS, Li X, Li HP, Huang T, Gao CS, Guo MW et al (2013) A rice stress-responsive NAC gene enhances tolerance of transgenic wheat to drought and salt stresses. Plant Sci 203–204:33–40
Shi W, Liu D, Hao L, Wu CA, Guo X, Li H (2014) GhWRKY39, a member of the WRKY transcription factor family in cotton, has a positive role in disease resistance and salt stress tolerance. Plant Cell Tissue Organ Cult 118:17–32
Singla-Pareek SL, Reddy MK, Sopory SK (2003) Genetic engineering of the glyoxalase pathway in tobacco leads to enhanced salinity tolerance. PNAS 100(25):14672–14677
Singla-Pareek SL, Yadav SK, Pareek A, Reddy MK, Sopory SK (2006) Transgenic tobacco overexpressing glyoxalase pathway enzymes grow and set viable seeds in zinc-spiked soils. Plant Physiol 140(2):613–623
Suzuki N, Rivero RM, Shulaev V, Blumwald E, Mittler R (2014) Abiotic and biotic stress combinations. New Phytol 203:32–43
Tirado R, Cotter J (2010) Ecological farming: drought-resistant agriculture. 02/2010; Greenpeace Research Laboratories, University of Exeter, UK, GRL-TN
Todaka D, Shinozaki K, Yamaguchi-Shinozaki K (2015) Recent advances in the dissection of drought-stress regulatory networks and strategies for development of drought-tolerant transgenic rice plants. Front Plant Sci 6:84
Vemanna RS, Babitha KC, Rao HMH, Sathyanarayanagupta SK, Sarangi SK, Nataraja KN, Udayakumar M (2013) Modified multisite gateway cloning strategy for consolidation of genes in plants. Mol Biotechnol 53(2):129–138
Vile D, Pervent M, Belluau M, Vasseur F, Bresson J, Muller B, Granier C, Simonneau T (2012) Arabidopsis growth under prolonged high temperature and water deficit: independent or interactive effects? Plant Cell Environ 35:702–718
Wahid A, Gelani S, Ashraf M, Foolad MR (2007) Heat tolerance in plants: an overview. Environ Exp Bot 61:199–223
Wasson AP, Richards RA, Chatrath R, Misra SC, Sai Prasad SV, Rebetzke GJ, Kirkegaard JA, Christopher J, Watt M (2012) Traits and selection strategies to improve root systems and water uptake in water-limited wheat crops. J Exp Bot 63(9):3485–3498
Xu J, Duan X, Yang J, Beeching JR, Zhang P (2013) Enhanced reactive oxygen species scavenging by overproduction of superoxide dismutase and catalase delays postharvest physiological deterioration of cassava storage roots. Plant Physiol 161:1517–1528
Yadav SK, Singla-Pareek SL, Reddy MK, Sopory SK (2005) Transgenic tobacco plants overexpressing glyoxalase enzymes resist an increase in methylglyoxal and maintain higher reduced glutathione levels under salinity stress. FEBS Lett 579(27):6265–6271
Zhang H, Liu W, Wan L, Li F, Dai L, Li D et al (2010) Functional analyses of ethylene response factor JERF3 with the aim of improving tolerance to drought and osmotic stress in transgenic rice. Transgenic Res 19:809–818
Zhang L, Zhang L, Xia C, Zhao G, Jia J, Kong X (2015a) The novel wheat transcription factor TaNAC47 enhances multiple abiotic stress tolerances in transgenic plants. Front Plant Sci 6:1174
Zhang L, Zhang L, Xia C, Zhao G, Liu J, Jia J et al (2015b) A novel wheat bZIP transcription factor, TabZIP60, confers multiple abiotic stress tolerances in transgenic Arabidopsis. Physiol Plant 153:538–554
Zhu N, Cheng S, Liu X, Du H, Dai M, Zhou DX et al (2015) The R2R3-type MYB gene OsMYB91 has a function in coordinating plant growth and salt stress tolerance in rice. Plant Sci 236:146–156
Acknowledgement
This work is partly supported by the Department of Biotechnology and the Indian Council of Agricultural Research, Government of India, New Delhi. PMS would like to thank University Grants Commission, New Delhi, for providing research fellowship.
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Parvathi, M.S., Nataraja, K.N. (2017). Simultaneous Expression of Abiotic Stress-Responsive Genes: An Approach to Improve Multiple Stress Tolerance in Crops. In: Senthil-Kumar, M. (eds) Plant Tolerance to Individual and Concurrent Stresses. Springer, New Delhi. https://doi.org/10.1007/978-81-322-3706-8_10
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