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View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by Elsevier - Publisher Connector THE CROP JOURNAL 4 (2016) 162–176 Available online at www.sciencedirect.com ScienceDirect Phytohormones and their metabolic engineering for abiotic stress tolerance in crop plants Shabir H. Wania,⁎, Vinay Kumarb,⁎, Varsha Shriramc, Saroj Kumar Sahd aDivisionofGeneticsandPlantBreeding,FacultyofAgricultureWADURA,Sher-e-KashmirUniversityofAgriculturalSciencesandTechnology, Kashmir191121,India bDepartmentofBiotechnology,ModernCollegeofArts,ScienceandCommerce,S.P.PuneUniversity,Ganeshkhind,Pune411016,India cDepartmentofBotany,Prof.RamkrishnaMoreCollege,S.P.PuneUniversity,Akurdi,Pune411044,India dDepartmentofBiochemistry,MolecularBiology,EntomologyandPlantPathology,MississippiStateUniversity,MS39762,USA A R T I C L E I N F O A B S T R A C T Articlehistory: Abioticstressesincludingdrought,salinity,heat,cold,flooding,andultravioletradiation Received22August2015 causescroplossesworldwide.Inrecenttimes,preventingthesecroplossesandproducing Receivedinrevisedform more food and feed to meet the demands of ever-increasing human populations have 15January2016 gained unprecedented importance. However, the proportion of agricultural lands facing Accepted15March2016 multipleabioticstressesisexpectedonlytoriseunderachangingglobalclimatefueledby Availableonline1April2016 anthropogenicactivities.Identifyingthemechanismsdevelopedanddeployedbyplantsto counteractabioticstressesandmaintaintheirgrowthandsurvivalunderharshconditions Keywords: thus holds great significance. Recent investigations have shown that phytohormones, Phytohormones includingtheclassicalauxins,cytokinins,ethylene,andgibberellins,andnewermembers Abioticstress including brassinosteroids, jasmonates, and strigolactones may prove to be important Metabolicengineering metabolic engineering targets for producing abiotic stress-tolerant crop plants. In this Plantstresses review, we summarize and critically assess the roles that phytohormones play in plantgrowthanddevelopmentandabioticstresstolerance,besidestheirengineeringfor conferringabioticstresstoleranceintransgeniccrops.Wealsodescriberecentsuccessesin identifying the roles of phytohormones under stressful conditions. We conclude by describingtherecentprogressandfutureprospectsincludinglimitationsandchallenges ofphytohormoneengineeringforinducingabioticstresstoleranceincropplants. ©2016CropScienceSocietyofChinaandInstituteofCropScience,CAAS.Productionand hostingbyElsevierB.V.ThisisanopenaccessarticleundertheCCBY-NC-NDlicense (http://creativecommons.org/licenses/by-nc-nd/4.0/). Contents 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 163 2. Abioticstresses:Challengingthechangingworld . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 163 3. Importanceofstudyingplantstressesincombination . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 164 ⁎ Correspondingauthors. E-mailaddresses:[email protected](S.H.Wani),[email protected](V.Kumar). PeerreviewunderresponsibilityofCropScienceSocietyofChinaandInstituteofCropScience,CAAS. http://dx.doi.org/10.1016/j.cj.2016.01.010 2214-5141/©2016CropScienceSocietyofChinaandInstituteofCropScience,CAAS.ProductionandhostingbyElsevierB.V.Thisisan openaccessarticleundertheCCBY-NC-NDlicense(http://creativecommons.org/licenses/by-nc-nd/4.0/). THE CROP JOURNAL 4 (2016) 162–176 163 4. Phytohormones:Keymediatorsofplantresponsestoabioticstresses . . . . . . . . . . . . . . . . . . . . . . . . . . . 164 4.1. Abscisicacid(ABA),theabioticstresshormone . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 164 4.2. Auxins(IAA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 164 4.3. Cytokinins(CKs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 165 4.4. Ethylene(ET) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 165 4.5. Gibberellins(GAs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 165 4.6. Brassinosteroids(BRs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 166 4.7. Jasmonates(JAs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 166 4.8. Salicylicacid(SA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 166 4.9. Strigolactones(SL) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 166 5. Crosstalkbetweenphytohormonessignaling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 167 6. Recentattemptsatdecipheringtheroleofphytohormonesinabioticstresstolerance . . . . . . . . . . . . . . . . 168 6.1. Hormoneshelpinpollendevelopmentundercoldstress . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168 6.2. Hormonalbalanceundercoldstress . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168 6.3. Salicylicacidincreasesgermination,seedlinggrowth,andenzymesactivity . . . . . . . . . . . . . . . . . . 168 6.4. Hormoneresponsiveproteinmediatedstressresponses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168 6.5. Putativeauxineffluxcarrierinvolvedinthedroughtstressresponseanddroughttolerance . . . . . . . . . 169 6.6. Phytohormonesalleviatehigh-temperaturestress . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 169 7. Engineeringphytohormonesforproducingabiotic-stresstolerantcropplants . . . . . . . . . . . . . . . . . . . . . 169 7.1. Engineeringtechniques . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 169 7.2. Metabolicengineeringofphytohormonesforconferringabioticstresstoleranceoncropplants . . . . . . . 169 8. Conclusionandfutureoutlook . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171 1.Introduction improvecropsnutritionallyandeconomically.Inthisreview,we present an overview of the phytohormones and their roles in plant growth, development, and abiotic stress response, in The human population is rapidly increasing and needs a additiontotheirmetabolicengineeringtoconferabioticstress substantial increase in agricultural productivity worldwide. toleranceincropplantstoincreasefoodquantityandquality. However,variousbioticandabioticstressesaremajorfactors Wediscussrecentsuccessesandfutureprospects. limiting crop productivity [1]. To feed the world population, productivity must be increased by 70% for an additional 2.3 billion people by 2050 [2]. The mechanisms underlying envi- ronmentalstressresponseandtoleranceinplantsaredifferent 2.Abioticstresses:Challengingthechangingworld andmorecomplexthananimals[3].Identifyingtheprinciples bywhichplantsrespondtovariousenvironmentalstressesis Investigating how abiotic stresses affect plant growth and oneofthecriticalaspectsforplantbiotechnologists.Amongst developmentatthephysiological,biochemical,andmolecular variousabioticstresses,drought,salinity,andextremetemper- levels is critical to increasing the productivity of crops, atures are most widespread and significant [4]. Because of because stresses cause widespread crop losses throughout thecomplexityofstresstolerancetraits,conventionalbreeding the world [6]. Environmental factors imposing stress on techniques have met with limited success. They demand plants, including drought, salinity, heat, chilling, freezing, effectiveadvancestofeedthegrowingworldwidefooddemand. ozone, pathogens, and UV radiation are the major environ- In this direction, novel and potent approaches should be mental cues that limit crop productivity. The period and devised.Engineeringofphytohormonescouldbeamethodof development of stress, stages of the plant, and biotic and choicetoproduceclimate-resilientcropswithhighyields. abiotic factors may influence the stress response [8]. Some Phytohormones are molecules produced in very low cropsmaybeaffectedatanearlystage,butrecoverandfinally concentrations but able to regulate a variety of cellular survive. Susceptibility or resistance to stresses may differ processes in plants. They work as chemical messengers to markedlyamongspeciesorgenotypesofcrops.Amongthese communicate cellular activities in higher plants [5]. Phyto- stressconditions,droughtisperhapsthemostseverestress, hormones play key roles and coordinate various signal responsiblefordecreasedagriculturalproductionworldwide. transductionpathwaysduringabiotic-stressresponse.They It affects plants in many ways: plant growth, membrane regulate external as well as internal stimuli [6]. Some integrity,pigmentcontent,osmoticadjustments,waterrela- phytohormones, such as ABA, have been identified as stress tions,andphotosyntheticactivity[9,10].Asrightlypointedout hormones. ABA plays critical roles in plant development: byPostel[11],waterwillbetheoilofthe21stcentury.Many maintenance of seed dormancy, inhibition of germination, riversaroundtheglobesaredryingdaily;mosthavenowater growth regulation, stomatal closure, fruit abscission, besides to discharge to the sea [11]. After drought, salinity is the mediatingabioticandbioticstressresponses[7].Phytohormone secondmajorstressreducingcropproductivity.Variousplant engineeringcouldbeaperfectplatformforbiotechnologiststo hormones have shown positive plant-protective functions 164 THE CROP JOURNAL 4 (2016) 162–176 against abiotic stresses and attempts have been made to plays an influential during several plant physiological pro- assign specific hormone(s) for specific stresses as well as cesses and developmental stages including seed dormancy combinations of stresses, as some hormones have shown anddevelopment,stomatalopening,embryomorphogenesis, multiplestress-resistancefunctions. andsynthesisofstorageproteinsandlipids[16]. ABA isconsidered anessential messengerinthe adaptive response of plants to abiotic stress and its role in stress 3.Importanceofstudyingplantstresses tolerancehasreceivedmuchattention.Inresponsetoenviron- incombination mental stresses, endogenous ABA levels increase rapidly, activating specific signaling pathways and modifying gene Previously,tostudyabioticstressconditions,generallyspecific expressionlevels[17].Nemhauseretal.[18]havereportedthat stressconditionswereinvestigated,includingdrought,salinity, ABAtranscriptionallyregulatesupto10%ofprotein-encoding orheat,andthediversemolecularaspectsofplantacclimation genes. ABA also acts as an internal signal enabling plants to were analyzed. However, conditions differ in the natural surviveunderadverseenvironmentalconditions[19]. environments. In nature, crops face different stresses or Under water-deficit conditions, ABA plays a vital role in combinations of stresses found in the environment. The providingplantstheabilitytosignaltotheirshootsthattheyare majority of molecular studies are conducted under con- experiencingstressfulconditionsaroundtheroots,eventually trolledconditionsinthelaboratoryorgreenhouseanddonot resulting in water-saving antitranspirant activity, notably reflect the actual conditions that occur in the field. In the stomatalclosureandreducedleafexpansion[20].ABAisalso laboratory or greenhouse, conditions are controlled so that involvedinrobustrootgrowthandotherarchitecturalmodifi- one stress is imposed, but in natural conditions there are cationsunderdroughtstress[21]andnitrogendeficiency[22]. manyenvironmentalstressesthatareappliedincombination. ABAregulatestheexpressionofnumerousstress-responsive Therefore,theexperimentsconductedforevaluatingeffectsof genes and in the synthesis of LEA proteins, dehydrins, and acombinationofstressfactorsratherthananindividualstress other protective proteins [23,24]. ABA upregulates the pro- mayproveadvantageous.Droughtandheatstressincombina- cessesinvolvedincellturgormaintenanceandsynthesisof tion caused losses of $200 billion in the USA (readers are osmoprotectantsandantioxidantenzymesconferringdesic- encouragedtorefertotheexcellentreviewofSuzukietal.[12]). cationtolerance[25].Zhangetal.[26]reportedaproportional increase in ABA concentration upon exposure of plants to salinity. 4.Phytohormones:Keymediatorsofplantresponses toabioticstresses 4.2.Auxins(IAA) Plantsmustregulatetheirgrowthanddevelopmenttorespond Although auxin has been studied for over 100 years, its tovariousinternalandexternalstimuli[13].Phytohormones,a biosynthesis, transport, and signaling pathways are still not diversegroupofsignalingmoleculesfoundinsmallquantitiesin clear[27].However,someinterconnectingpathwayshavebeen cells,mediatetheseresponses.Theirpivotalrolesinpromoting proposedso farforbiosynthesisof auxininplants, including plant acclimatization to ever-changing environments by four tryptophan (Trp)-dependent and one Trp-independent mediating growth, development, source/sink transitions, pathway [28]. IAA (indole-3-acetic acid) is one of the most and nutrient allocation have been well established [14]. multi-functionalphytohormonesandisvitalnotonlyforplant Although plant response to abiotic stresses depends on growthanddevelopmentbutalsoforgoverningand/orcoordi- various factors, phytohormones are considered the most natingplantgrowthunderstressconditions[29].Thepresence important endogenous substances for modulating physio- ofanauxinbiosynthesis,signaling,andtransportapparatusin logical and molecular responses, a critical requirement for single-celledgreenalgaeisclearevidenceoftheevolutionary plantsurvivalassessileorganisms[14].Phytohormonesact roleplayedbyauxinduringtheadaptationofplantstodiverse eitherattheirsiteofsynthesisorelsewhereinplantsfollowing land environments [30]. Though there has been a recent theirtransport [15]. Phytohormonesareofkeyimportancein upsurge in our understanding of auxin regulation of plant plant development and plastic growth. They include auxin growth and development, its role as a regulator of stress (IAA), cytokinins (CKs), abscisic acid (ABA), ethylene (ET), responseisstilllittleunderstood[29]. gibberellins (GAs), salicylic acid (SA), brassinosteroids (BRs), Interestingly, there is growing evidence that IAA plays an andjasmonates(JAs).Thestrigolactone(SL)arerelativelynew integral part in plant adaptation to salinity stress [14,31]. It phytohormones.Fig.1showsthechemicalstructuresofmajor increasesrootandshootgrowthofplantsgrowingundersalinity phytohormones. or heavy metal stresses [32,33]. Salinity reduced IAA levels in maizeplants,butsalicylicacidapplicationeffectivelyincreased 4.1.Abscisicacid(ABA),theabioticstresshormone them [34], indicating that hormonal balance and crosstalk arecriticaltosignalperception,transduction,andmediationof Abscisicacid(ABA)owesitsnametoitsroleinabscissionof stressresponse[14].Auxinstimulatesthetranscriptionofalarge plantleavesandisperhapsthemoststudiedphytohormone numberofgenescalledprimaryauxinresponsegenes,andthese for its response and distinct role in plant adaptation to genes have been identified and characterized inseveral plant abiotic stresses, and is accordingly termed a “stress hor- species including rice, Arabidopsis, and soybean [35]. Auxin is mone.” It is an isoprenoid plant hormone produced in the regarded as an influential constituent of defense responses plastidal2-Cmethyl-D-erythritol-4-phosphatepathway.ABA via regulation of numerous genes and mediation of crosstalk THE CROP JOURNAL 4 (2016) 162–176 165 Abscisic Acid IAA (auxin) Zeatin (cytokinin) Ethylene Gibberellic acid Brassinolide (brassinosteroid) Jasmonic acid Salicylic acid (+)-Strigol (strigolactone) Fig.1–Majorclassesofphytohormonesinvolvedinabioticstressresponseandtoleranceinplants. between abiotic and biotic stress responses [36]. However, AdoMettoACC,whileACCoxidasecatalyzestheconversionof identificationofnovelgenesinvolvedinstressresponsesmay ACCtoethylene. provetobeavitaltargetforengineeringabioticstresstolerance Abiotic stresses including low temperature and salinity inprincipalcrops. alterendogenousETlevelsinplants.Enhancedtolerancewas accordingly achieved with higher ET concentrations [44]. ET 4.3.Cytokinins(CKs) also plays a major role in the defense response of plants to heat stress[45]. Environmental stressinducesET accumula- CKsplayinfluentialrolesinmanyplantgrowthanddevelop- tion which increases plant survival chances under these mental processes and are considered as master regulators adverse conditions [42]. ET has been proposed to function during plant growth and development [37,38]. Alteration of viamodulationofgeneexpressionconsideredastheeffectors endogenouslevelsofCKsinresponsetostressindicatestheir ofethylenesignal[46]. involvementinabioticstress[17],includingdrought[37]and ET incombination withotherphytohormonessuchas JA salinity[38].Mutantsandtransgeniccells/tissueswithaltered and SA often acts cooperatively. These are considered the activity of cytokinin metabolic enzymes or perception ma- main players involved in regulating plant defense against chinery points toward their crucial involvement in several pests and pathogens [6]. The biosynthesis, transport, and crop traits including productivity and increased stress toler- accumulationofthesehormonestriggeracascadeofsignal- ance[39]. ingpathwaysinvolvedinplantdefense[47].Asconcludedby Although plant responses to CKs have been evaluated Yin et al. [48], ET and ABA seem to act synergistically or mostoftenviatheirexternalapplication,stressfulconditions antagonisticallytocontrolplantgrowthanddevelopment. are also known to enhance their endogenous levels via uptake and enhanced biosynthesis [40]. In contrast to the 4.5.Gibberellins(GAs) ABA inhibition of seed germination, they also release seeds from dormancy [36]. CKs are often considered ABA antago- The gibberellins (GAs) are a large group of tetracyclic nists[41].Inwater-stressedplants,decreasedCKcontentand diterpenoidcarboxylicacids,butonlyafewofthemfunction accumulation of ABA lead to an increased ABA/CK ratio. asgrowthhormonesinhigherplants,predominantformsbeing The reduced CK levels enhance apical dominance, which, GA and GA [49]. The GAs show positive effects on seed 1 4 togetherwiththeABAregulationofstomatalaperture,aidsin germination, leaf expansion, stem elongation, flower and adaptationtodroughtstress[17]. trichome initiation, and flower and fruit development [50]. They are essential for plants throughout their life cycle for 4.4.Ethylene(ET) growth-stimulatoryfunctions.Theyalsopromotedevelopmen- tal phase transitions [51]. Interestingly, there is increasing ET, a gaseous phytohormone, is involved in several phases of evidence for their vital roles in abiotic stress response and plant growth and development, notably fruit ripening, flower adaptation[51].Recently,experimentshavebeenperformedto senescence, and leaf and petal abscission, besides being an investigate the role of GAs in osmotic stress response in essentialregulatorofstressresponses[42,43].Itisbiosynthesized Arabidopsisthalianaseedlings[52,53].GAsareknowntointeract frommethionineviaS-adenosyl-L-methionine(AdoMet)andthe withallotherphytohormonesinnumerousdevelopmentaland cyclic non-protein amino acid ACC. ACC synthase convert stimulus-responseprocesses[54].TheinteractionsbetweenGA 166 THE CROP JOURNAL 4 (2016) 162–176 and ET include both negative and positive mutual regulation thaliana plants against Cu and Cd stress via accumulation of dependingonthetissueandsignalingcontext[54]. phytochelatins[76]. 4.6.Brassinosteroids(BRs) 4.8.Salicylicacid(SA) Brassinosteroids (BRs) comprise a relatively new group of Salicylicacid(SA)isanaturallyoccurringphenoliccompound polyhydroxysteroidalplanthormoneswithstronggrowthand involved intheregulation ofpathogenesis-associatedprotein development-promoting potential. They were first isolated expression[77].Inadditiontodefenseresponses,itplaysavital and characterizedinpollenof the rapeplant (Brassicanapus). role in the regulation of plant growth, ripening and develop- More than 70 BRs have been isolated from plants. However, ment, as well as responses to abiotic stresses [78,79]. The brassinolide,28-homobrassinolide,and24-epibrassinolidecon- synthesisofSAoccursviatwopathways:theisochorismate(IC) stitute the three most bioactive BRs and are widely used in andthephenylalanineammonia-lyase(PAL)pathway.Ofthese, physiologicalandexperimentalstudies[55].Theyarepresentin themajorpathwayistheICpathwayinNicotianabenthamiana almosteverypartofplantsincludingpollen,flowerbuds,fruits, [80]andtomato[81]. seeds,vascularcambium,leaves,shoots,androots[56].They An interesting and noteworthy general belief is that low playacriticalroleinnumerousdevelopmentalprocessessuch concentrations of SA enhance the antioxidant capacity of asstemandrootgrowth,floralinitiation,anddevelopmentof plants, but high concentrations of SA cause cell death or flowersandfruits[56]. susceptibilitytoabioticstresses[82].Mostgenesthatrespond However,recentfindingssuggeststress-impactmitigating positively to acute SA treatment are associated with stress roles of BRs and associated compounds in various plants andsignalingpathwaysthateventuallyledtocelldeath.SA subjected to various abiotic stresses. These abiotic stresses consistsofgenesencodingchaperones,heatshockproteins, arehightemperature[57],chilling[58],soilsalinity[59],light antioxidants, and genes involved in the biosynthesis of [60], drought [61], flooding [62], metals/metalloids [63], and secondary metabolites, such as sinapyl alcohol dehydroge- organic pollutants [64]. Recent research has shown tremen- nase,cinnamylalcoholdehydrogenase,andcytochromeP450 dous potential of BRs and associated compounds in the [82]. modulation of components of antioxidant defense system SAisinvolvedinplantresponsetoabioticstressessuchas in-response-to and to counteract the abiotic stress-induced drought [83], salinity [34,84], chilling [85], and heat [86]. SA oxidative burst, reviewed by Vardhini and Anjum [65]. along with ABA is involved in the regulation of drought However, there is tremendous scope for further research response[77]. Drought stress induced a five-fold increase in focused on the sites, pathways, and enzymology of their the endogenous levels of SA in Phillyrea angustifolia[87]. The biosynthesis, source–sink relationships, developmental and SA content in barley roots was increased approximately stress physiology, their interactions with microorganisms, twofoldbywaterdeficit[88].TheSA-induciblegenesPR1and fungi, and animals, and the realization of their powerful PR2 (pathogenesis-related genes) are induced by drought applications[14]. stress [83]. However, the detailed molecular mechanisms of SA’srolesinabioticstresstoleranceremainlargelyunknown 4.7.Jasmonates(JAs) and more comprehensive investigations are needed in this direction. Thecyclopentanonephytohormonesderivedfromthemetab- olism of membrane fatty acids including primarily methyl 4.9.Strigolactones(SL) jasmonate (MeJA) and its free acid jasmonic acid (JA) are collectivelycalledjasmonates(JAs)andarewidespreadinthe Strigolactones (SLs) constitutes a small class of carotenoid- plantkingdom.Thesemultifunctionalcompoundsareinvolved derived compounds, first characterized more than 45years in crucial processes associated with plant development and ago as seed germination stimulants in root parasitic plants survival including reproductive processes, flowering, fruiting, such as Striga, Orobanche, and Phelipanche species [89,90]. senescence, secondary metabolism, and direct and indirect Several types of SLs can be synthesized by single plant defenseresponses[66,67].JAisthemostabundant,bestknown, species, whereas mixtures of different types and quantities andbestcharacterizedoftheJAs.Inadditiontodevelopmental ofSLmoleculesareproducedinintraspecificvarieties[89,91]. functions of plants, JA activates plant defense responses to Although they are produced and exuded in small amounts pathogenicattackaswellasenvironmentalstressesincluding primarilyinroots,otherplantpartscanalsosynthesizethem drought, salinity, and low temperature [68,69]. JAs are vital [92]. A comparative study involving wild-type and mutant signalingmoleculesinducedbyvariousenvironmentalstresses Arabidopsis plants indicatestheir role in the development of includingsalinity[68],drought[69,70],andUVirradiation[71]. rootsystemarchitecture[93].ApplicationofGR24,asynthetic Theyhavegreatpotentialtomitigateanarrayofthreatening and biologically active SL [94,95], repressed lateral root environmentalstresses[72].TheexogenousapplicationofMeJA formation in wild-type seedlings and SL-synthesis mutants effectivelyreducedsalinitystresssymptomsinsoybeanseed- (max3andmax4)butnotinthestrigolactone-responsemutant lings [73]. Remarkably, endogenous levels of JA increased in (max2), suggesting the MAX2-dependent negative effect of rice roots under salinity stress and reported to counteract strigolactoneonlateralrootformation[93,96].Apparently,SLs the deleterious effects of salinity stress [74]. JAs applications are involved in plant responses to environmental stimuli alleviate heavy metal stress in plants by activating the fromtheirearlyevolution.Inhigherplants,theyparticipatein antioxidant machinery [75]. MeJA confers tolerance in A. both shoot and root architecture in response to nutritional THE CROP JOURNAL 4 (2016) 162–176 167 conditions[97].SLs alsoactassignalingmoleculesfor plant We now discuss stomatal closure as a rapid response interactions with microbes. They stimulate nodulationin to water deficit conditions and phytohormonal crosstalk in the legume–rhizobium interaction process [98,99]. Overall, it its regulation. Stomatal closure is regulated by a complex can be concluded that SLs constitute an important group of networkofsignalingpathways,andasashort-termresponse signaling molecules and are key regulators of plants’ devel- istriggeredprimarilybyABA.ABAcontrolslong-termgrowth opmentaladaptationstochangingenvironmentalconditions. responses via the regulation of gene expression that favors Theyhavethepotentialtobeusedinagricultureforvarious maintenance of root growth, which optimizes water uptake purposesincluding as inducers of suicidal seed germination [26].However,followingtherulesofdroughtstressresponse, ofparasiticplants[100]. ABA apparently interacts with other plant hormones and signaling molecules such as JA and nitric oxide (NO) to stimulate stomatal closure, whereas its regulation of gene expression includes the induction of genes associated with 5.Crosstalkbetweenphytohormonessignaling response to ethylene, cytokinin, or auxin [101]. It has been proposed by the authors that stress-induced JA production Environmentalstressesrequireplantstoperceiveandreactto interactswithABA-mediatedstomatalclosurebystimulating thesesignalsinahighlycoordinatedandinteractivemanner. theinfluxofextracellularCa2+and/orbyactivatingH O /NO 2 2 Plantsbeingsessileorganismsneedtomaintainplasticityin signaling [101]. In contrast, Desikan et al. [106] provided growthandabilitytoadapttoharshchangingenvironmental evidence that stomatal closure by ethylene is regulated via conditions, and this adaptation is mediated by elaborate its signal transduction pathway, which both stimulates signalingnetworks.Signaltransductioncascadesthatinteract production and requires H O synthesis. This crosstalk also 2 2 with the baseline pathways transduced by phytohormones involves JA, whose biosynthesis is induced by stress condi- get triggered by the perception of abiotic stresses [101]. tionsincludingherbivory[107], whereasmanyJA-associated The fluctuations of stress-responsive hormones help alter signaling genes are regulated by drought stress [108]. JA cellulardynamicsandthusplayacentralroleincoordinately interacts with ABA-regulated stomatal closure by increasing regulating growth responses under stress conditions [102]. Ca2+ influx, which ultimately stimulates calcium-dependent Theconvergencepointsamonghormonesignaltransduction protein kinase (CDPK) production and the resulting signal cascadesare considered crosstalk, and together they form a cascade [101]. A 10-min treatment with either ABA or MeJA signaling network [101]. In this way, hormones seemingly resulted in a reduction of stomatal aperture in turgid and interactbyactivatingeitheracommonsecondmessengerora excised leaves of Arabidopsis [109]. The authors postulated phosphorylation cascade. In the last few decades, insights thatbothABAandMeJAinteractinguardcellsandinducethe intothebiosyntheticandcoresignalingcomponentsofmajor formation of reactive oxygen species and NO and that both phytohormones including ABA, IAA, BRs, GAs, JA, and ET are present at reduced concentrations in MeJA-insensitive have been revealed [103]. However, owing to the extreme plants. In another experiment, Kim et al. [110] found that complexityofresponsestodifferentstressthresholds,lackof droughtstressinduceda19-foldincreaseinMeJAlevelsanda knowledge about tissue-specific stress response, and inade- 2-foldincreaseinABAlevels,whichwasassociatedwithsevere quateunderstandingofgeneticplasticityanditsadaptability yield loss due mainly to poor seed set. This phenotype was to environments, the mechanistic basis of abiotic stress mimickedbyconcentrationsofMeJAinyoungpaniclesofrice tolerance remains largely unclear and confusing [102]. Con- through the ubiquitous expression of AtJMT transgenically, sequently, all these factors collectively contribute to more which also led to a dramatic reduction in grain yield and a confusion than resolution [104]. Still, perturbed phytohor- substantialincreaseinABA,suggestingcrosstalkbetweenMeJA monefluxesandthesubsequentsignaltransductioncascade andABAbiosynthesis[110].Similarly,long-termphysiological have been revealed as one of the primary stress responses responses to abiotic stress conditions are caused and influ- evolvedbyplants. encedbyalteredABA-mediatedgeneregulationoftranscription Variousplanthormonesinteracttogetherforsignaldefense factors(TFs)thatbindtoABA-responsiveelements(ABREs)on networking to fine-tune the defense against environmental ABA-regulated genes. Notably, phosphorylation cascades like challenges. Among them, SA, JA, and ABA hold particular those signaling stomatal closure also lead to changes in importanceandareregardedaskeyplayersintheregulation ABA-regulatedTFs.Forinstance,theABA-responsiveTFsABF1 ofsignalingpathways.Inrecentyears,decipheringtheinterac- and ABF4 are activated upon their phosphorylation by tions between phytohormones and their coordinated roles ABA-inducible kinases CPK4 or CPK11 [111], as reviewed by in counteracting abiotic stresses has gained new attention. Harrisonetal[101]. Experimentalfindingsunequivocallyshowthattheinteractions Onasimilarline,preferentialupregulationofJApathway amongphytohormonesaretheruleratherthantheexception genesundersalinitystressinbarleyplantshasbeenreported inintegratingdiverseinputsignalsandreadjustinggrowthand [112].AlthoughthepreciseroleofJAindroughtandsalinity acquiring stress tolerance in plants [102]. The presence of remains unknown; it could be implicated as a molecule multiple and frequent redundant signaling intermediates for signaling cell death [102]. Nishiyama et al. [38], studying eachhormonehintsattheirapparentrolesinsuchcrosstalk. gene expression, concluded that exogenous ABA treatment Understanding the crosstalk between phytohormonal and strongly downregulated isopentenyltransferase (IPT), a key defensesignalingpathwaysisthusimportant,asitmayreveal cytokininbiosynthetic pathwaygene,butupregulatedgenes new potential targets for the development of host resistance encodingcytokininoxidasesanddehydrogenases.Further,in mechanismsandphytohormones[105]. addition to its well-documented role in controlling plant 168 THE CROP JOURNAL 4 (2016) 162–176 growth and development in close associations with auxins genetic male sterile line by using transcription regulation of and BRs [113], GA is also involved in cross-talk of hormonal pollendevelopment;fordetails,seereviewbySharma[123]. interactions in signaling environmental inputs [114,115]. Various recent reports make it clear that interplay between 6.2.Hormonalbalanceundercoldstress environmentally activated ABA, ET, GA, and CK signals is crucialindeterminingplantstressresponses[3,116,117]. Kolaksazov et al. [124] reported that stress phytohormones Thereisevidencethatsomephytohormonesalsocounteract such as ABA, JA, and SA triggerphosphoprotein cascade adverse conditions. For example, a signal peptide system pathways, leading to expression of genes associated with coupled with JA is reported to be involved in wound-induced cold stress tolerance. They reported high contents of JA in salt-stressadaptationintomato[118],indicatingcross-tolerance the three different populations at a controlled temperature signaling.Thepossiblerolesofphytohormonesinabioticstress of 22°C, with a 10-fold reduction in sensitive plants but no tolerance and crosstalk between phytohormone signaling are changeintolerantplantsat4°C. illustratedinFig.2. 6.3.Salicylicacidincreasesgermination,seedlinggrowth,and enzymesactivity 6. Recent attempts at deciphering the role of phytohormonesinabioticstresstolerance Gharib and Hegazi [125] showed that SA stimulated various growthaspectsofbeanseedlings,wasresponsibleforbiosyn- 6.1.Hormoneshelpinpollendevelopmentundercoldstress thesis of growth-promoting and -inhibiting substances, and reducedtheadverseeffectofcoldstressincommonbean.They Abiotic stress can affect any developmental stages, but the conductedanexperimentonsixcommonbeanvarietieswith reproductive stage is perhaps most critical. If stresses are optimal temperature 25°C and chilling stress at 15°C. They applied at the reproductive stage, it may damage the whole foundthatgerminationandseedlinggrowthofthesixvarieties plantandultimatelyreducethecropyield.Further,amongthe were slowed under chilling stress. Seeds treated with SA various reproductive stages, pollen development is crucial showedincreasedgerminationgerminationratecomparedto andisaffectedbyabioticstressessuchasdrought,cold,and untreated(control)seedsundercontrolaswellaschillingstress. heat, leading to reduced crop yield [119]. In pollen develop- ment,pollenmeiosisisthestagemostsensitivetocold,which 6.4.Hormoneresponsiveproteinmediatedstressresponses causes pollen sterility and also reduces anther dehiscence, pollen load to the stigma, pollen germination, and pollen Inplantstressresponse,phytohormonesplayavitalrole,and tube growth [120,121]. Hormones such as GA and ABA are someproteinscanbeusedforcommunication.Bhaskaretal. consideredmajorsignalsforcold-inducedpollensterilityand [126]reportedthatC1-(cysteinerichproteinfamily)domain- anunderstandingofmolecularmechanismofpollendevelop- containing proteins play a part in plant hormone-mediated mentunderstressandnon-stressconditionscanbebeneficial stress responses. Authors identified 72 other proteins in for hybrid seed production by producing novel sterile plants. Arabidopsis that contained all three unique signature do- In rice, Zhang and co-workers [122] developed a hybrid seed mains.Transgeniclinesalsoshoweddifferentialregulationof production line in the form of a new photoperiod-sensitive manyabioticstress-responsivedistinctgenes,indicatingthe High light Drought CK Aux SA ht C g o ou ld Dr alt Drought s h ABA ET g Hi High salt E alt xce s s BR High s wa te r SL GA Fig.2–Thepossiblerolesofphytohormonesinabioticstresstoleranceandcrosstalkbetweenphytohormonesignaling THE CROP JOURNAL 4 (2016) 162–176 169 involvementofC1-clanproteinfamilyinhormone-mediated [131,132].Theuseofbiolisticsorparticlebombardmentisbyfar stressremediation. themostwidelyuseddirectgenetransfermethod. Withitsever-increasinghostrange,Agrobacteriumtumefaciens 6.5.Putativeauxineffluxcarrierinvolvedinthedroughtstress hasbecometheclearmethodofchoiceforgenetransfertoallof responseanddroughttolerance themaincropplants.Thissoilbacteriumpossessesthenatural abilitytodeliveradistinctpartofitsplasmidDNA(transferor Auxinactsasanecessarysignalinreactiontoabioticstresses. T-DNA)intothenucleargenomeofitshostplant.Thiscondition Zhang et al. [127] identified a putative auxin efflux carrier has arisen also partly because although direct gene transfer gene (OsPIN3t) in rice that acts in polar auxin transport methodsareusefulforstabletransformationaswellastransient involved in the drought response in rice. They also found expression, there are still some problems: alow frequency of that knockdown of the OsPIN3t gene leads to crown root stabletransformation,unwantedgeneticrearrangementsdueto abnormalities in the seedling stage and that its overexpres- thehighcopynumberofgenes,andthelongperiodrequiredto sion increased drought tolerance. Under 20% polyethylene regeneratewholetransgenicplants.InAgrobacterium,bacterial glycolstress,GUSactivitysignificantlyincreasedunderNAA genescanbesuccessfullyreplacedwithgene(s)ofinterest,and treatment.ThestudyshowedthatOsPIN3tisinvolvedinauxin interestingly,thisreplacementdoesnotaffectthetransforma- transportandthedroughtstressresponseinplants. tionprocessorfrequency[133,134]. For efficient transformation and subsequent regenera- 6.6.Phytohormonesalleviatehigh-temperaturestress tion, Agrobacterium-mediated methods are dependent on severalfactors.Theyarethechoiceofexplant,thehormonal Owingtohightemperatures,cropproductivityisdecreasingin composition of the medium used, nutritional supplements, many parts of the world. Chhabra et al. [128] performed an cultureconditionsbeforeandduringinoculation,durationof experimenttotesttheeffectofvarioushormonalconcentrations co-cultivation, virulence of the Agrobacterium strain, and onheat-stresseffectsandobservedthatbothgrowth-promoting concentrationandcompositionofthebacteriostaticagentused. and growth-retarding hormones mitigated heat-stress effects. The length of selection and concentration of the antibiotic They also reported that the most effective concentration of selectionmarkerarealsoimportant.Otherimportantfactorsare kinetin was 100μmolL−1 followed by 50μmolL−1 and that the plantcultivar and various conditions of tissue culture, soaking seeds in ABA delayed 50% seedling mortality by 1h includingarobustsystemofplantregeneration[135].However, and50minat0.5and1.0μmolL−1concentrations. through extensive efforts, remarkable progress has been achievedduringthelast2–3decadesinplantgeneticengineering. OptimizedprotocolshavebeendevelopedfortheAgrobacterium- 7. Engineering phytohormones for producing mediatedgenetictransformationofabroadrangeofcropplants abiotic-stresstolerantcropplants including monocots, previously considered to lie outside the Agrobacteriumhostrange.Recently,successhasbeenachievedin 7.1.Engineeringtechniques developinginplantatransformationmethods.However,inspired by the complex patent landscape of Agrobacterium technology Geneticengineeringhasopenednewavenuesforintroducing and in search of a perfect (open source) platform for plant abioticstresstoleranceinnumerouseconomicallyimportant biotechnology, Broothaerts et al. [136] have identified three crop species. Recent success has made genetic engineering non-Agrobacteriumspecies:Rhizobiumsp.NGR234,Sinorhizobium approachesasoneofthemostpotentsolutionsforimproving meliloti, and Mesorhizobium loti as being capable of successful cropproductivity underchallengingenvironments.The suc- genetic transformation of different plant species. A recent cess of transgenic research, however, depends largely on additiontothislistofbiologicalvectorsforgenetictransforma- effectiveplanttransformationmethodsforstableintegration tionofplantsisvirus-basedvectors. and functional expression of foreign genes in the plant genome. Since initial reports in tobacco [129,130], rapid 7.2. Metabolic engineering of phytohormones for conferring developmentsintransformationtechnologyhaveresultedin abioticstresstoleranceoncropplants the genetic modification of large number of plant species [131]. Considering that phytohormones are key regulators of plant Twogeneralapproachesareavailablefortransferringgene(s) growthanddevelopmentaswellasmediatorsoftheresponse to plants: one vector-mediated, by a biological vector such as toenvironmentalstress[24],hormonemetabolismandsignal- Agrobacterium, and the other direct gene transfer approach, ing processes are excellent targets of manipulation to obtain whereDNAisintroducedintocellsbyphysical,chemical,oreven enhanced abiotic stress tolerance. However, maintenance of electricalmeans.Directornonbiologicalgenetransfermethods hormonal balance to minimize possible adverse effects on includeparticlebombardment,DNAuptakeintoprotoplastsin growthanddevelopmentiscritical[15,137]. the presence of polyvalent cations, protoplast fusion with Among various phytohormones, ABA is perhaps the most bacterialspheroplastsandwithliposomescontainingforeign sought-afterhormoneforengineeringabioticstresstolerancein DNA(lipofection),electrotransfection,polymer-basedtrans- crop plants owing to its identity as a stress hormone and its fection (polyfection), silicon carbide fiber-mediated DNA up- vastarrayoffunctionsunderenvironmentalstressconditions, take, injection-based methods (micro- and macro-injection), particularlydrought.Asaresult,manyofthekeyABAbiosyn- wave and beam-mediated transformation, desiccation-based theticpathwayenzymeshavebeeninvestigatedtransgenically transformation,andexogenousDNAapplicationandimbibition for improved abiotic stress tolerance [138]. Park et al. [139] 170 THE CROP JOURNAL 4 (2016) 162–176 reportedenhancedosmoticstresstolerancebyoverexpressing DREB1B from Arabidopsis improved tolerance to water-deficit anABA-responsivestress-relatedgeneinArabidopsis.C-repeat stress in tomato [140]. Likewise, Al-Abed et al. [141] found binding factor (CBF) and/or dehydration-responsive element- expressionofCBF/DREBgenesunderstress-induciblepromoters binding (DREB) genes have been manipulated to confer im- in transgenic plants that do not express detectable levels of proveddroughttolerance.Forexample,overexpressionofCBF1/ these genes under non-stress conditions, minimizing growth Table1–Listofattemptsmadeatengineeringphytohormonesforenhancedabioticstresstoleranceofplants. Item Gene Functionofgene Expression/ Phenotypeoftransgenics Reference knock-out Planthormone MoCo Regulationofthelaststep ↑ Transgenicsoybeanshowedhigherbiomass, [150] sulfurase ofABAbiosynthesis yield,andoverallenhanceddroughttolerance ABA LOS5 KeyregulatorofABA ↑ TransgenicmaizewithenhancedABA [142] biosynthesis accumulationandincreaseddroughttolerance AtLOS5 KeyregulatorofABA ↑ Increasedsalinitytoleranceattributedto [151] biosynthesis enhancedNa+effluxandH+influxand consequent NCED Importantroleinrate ↑ IncreasedlevelsofendogenousABA,decreased [152] limitingstepofABA stomatalconductanceandincreaseddrought biosynthesisforfeedback tolerance control MsZEP ImportantroleinABA ↑ Heterologousexpressionofgeneresultedin [153] biosynthesis bettersaltanddroughttolerance SnRK2.4 Importantserine/ ↑ TransgenicArabidopsisexhibitedenhanced [154] threonineproteinkinase tolerancetodrought,salt,andfreezingstress inABAsignalingnetwork associatedwithdecreasedwaterloss,improved photosynthesis,andosmoticpotential OsPIN3t Auxineffluxcarrier, ↑ Increaseddroughttoleranceinrice [127] importantinpolarauxin transport Auxin YUCCA6 ImportantgeneinAuxin/ ↑ Overproductionofauxinattributedforincreased [27] IPAbiosynthesis tolerancetodroughtandoxidativestress YUCCA6 ImportantgeneinAuxin/ ↑ Phenotypesofpotatowithhigherauxincontent [155] IPAbiosynthesis andenhanceddroughttolerance OsIAA6 Amemberofriceauxin/ ↑ Betterdroughttoleranceoftransgenicrice [156] IAAgenefamily plantsviaauxinbiosynthesisregulation IPT Cytokininbiosynthesis ↑ Transgenictomatoshowedenhancedgrowth [157] andyieldundersaltstress Cytokinins ↑ Transgenictobaccoshowedenhancedsaltstress [158] tolerance SlIPT3 ↑ Transgenictomatoshowedenhancedsalinity [159] stresstolerance CKX Cytokinindehydrogenase ↑ TransgenicArabidopsisplantsoverexpressing [160] cytokininoxidase/dehydrogenasegeneshowed enhanceddroughttolerance AtCKX1 Cytokinindehydrogenase ↑ Transgenicbarleyplantsshowedbetterdrought [161] toleranceviabetterdehydrationavoidance ERF-1(JERF1) Responsefactorsfor ↑ Riceplantsshowedincreaseddroughttolerance [162] Ethyleneaswellas Jasmonates Ethylene ETOL1 ↑ Increasedtolerancetodroughtand [163] submergence ACC-Synthase Catalyzesrate-limiting Gene-silencing Reducedethylenelevelswithbetterdrought [164] stepinethylene toleranceintransgenicmaizeplants biosynthesis ZmARGOS Negativeregulatorsof ↑ Improveddroughttoleranceoftransgenic [165] ethylenesignal Arabidopsisandmaizeplants transduction OsGSK1 BRnegativeregulator Knockoutof Increasedtoleranceofknockoutmutantstocold, [166] OsGSK1 heat,saltanddroughtstresses Brassinosteroids AtHSD1 RoleinBRbiosynthesis ↑ OverproductionofBRincreasedgrowthrateand [167] seedyield,increasedsalinitytolerance BdBRI1 BR-receptorgene Downregulation Improveddroughttolerancewithdwarf [168] phenotypesofpurplefalsebrome ↑:Overexpression THE CROP JOURNAL 4 (2016) 162–176 171 retardationandotheradverseeffects.Lietal.[142]overexpressed 8.Conclusionandfutureoutlook theMoCosulfurasegeneinsoybean,resultinginhigherbiomass productionandyieldwithoverallenhanceddroughttolerance Overall, phytohormone engineering represents an important attributed to higher ABA accumulation, reduced water loss platformforabioticstresstolerance,providingnewopportunities throughsmalleropeningsofstomata,andinducedantioxidant tomaintainsustainablecropproductiontofeedtheworldunder enzymaticmachinery. changingenvironmentalconditions.Ithasamajorapplicationin However, on some occasions, overexpression of gene(s) plant stress tolerance and adaptation to a variety of stresses, involvedinABAbiosynthesisorcatabolicpathwaysresulted owing to the involvement of multiple stress responsive genes. in increased drought tolerance, but led to impaired growth During the past few years, with the rapid development of due to pleiotropic effects even with the use of inducible genomictechnology,muchresearchhasbeenperformedtowards promoters[143].Tooffsettheseunwantedgrowthanomalies, understanding of plant abiotic stress response. Still many Zhang et al. [122] overexpressed CRK45, a stress-inducible challenges are lying ahead to uncover and understand the kinase involved in ABA signaling, and the resulting trans- complexity hidden in stress signal-transduction pathways. For genics showed enhanced drought tolerance but with tighter example, to acquire wide-ranging understanding of plant re- control of ABA levels and signaling, indicating the role sponsestoabioticstressincomingyears,moreextensivework of CRK45 in fine-tuning of ABA levels. Similarly, IPT was should be performed at the genetic level of the biosynthetic expressedunderthecontrolofstress-induciblepromotersto pathwayof hormones such as IAA. Research to date indicates avoid pleiotropic effects, leading to increased CK content, thatphytohormoneengineeringhasbeeninitiated.Therolesof antioxidant scavenging, and better root growth with overall planthormonesinresponsestofluctuatingenvironmentshave improved grain yield under drought conditions in Agrostis been demonstrated, and hormones play a primary role in stolonifera[144,145]. determining plant stress responses. In this review, we have Recently, transgenic poplars were produced via overex- summarized the role of phytohormones, crosstalk among pression of the Arabidopsis YUCCA6 gene (a member of the hormones,theimportanceofstudyingplantstressesincombi- YUCCA family of flavinmonooxygenase-like proteins), which nation,andengineeringtechniquesandstrategiesfordeveloping is involvedin tryptophan-dependent IAA biosynthesis path- stress tolerance in plants. In a wide range of stresses, plant way and known to respond to environmental cues, under hormones are involved directly or indirectly, and it is clear thecontrolofthestress-inducibleSWPA2promoter[27].The that plant hormones play roles in plant defense and plant– transgeniclinesdisplayedauxin-overproductionmorpholog- environmentinteractions. ical phenotypes, including rapid shoot growth and retarded In conclusion, although phytohormone engineering is main root development with increased root hair formation. promising for plant biologists, there isstill along wayto go Also, SY plants had higher levels of free IAA and early before the technology can reach its full potential. Among auxinresponsegenetranscripts.Thetransgeniclinesshowed the greatest challenges that remain to be addressed is the tolerancetodroughtstress,associatedwithreducedlevelsof development of stable phytohormone-engineered crops that reactiveoxygenspecies[27].ThericemutantCONSTITUTIVELY produce main staple foods such as rice, wheat, and corn. WILTED1 was deficient in the YUCCA homolog [146], and an Towardsthisgoal,studyshouldbefocusedonacombination activationtaglineofYUCCA7inArabidopsisshowedenhanced of stress responses such as those in field environments, droughttolerance[147].Droughttolerancebyoverexpressionof because different stresses are most likely to occur simulta- AtYUC6 in potato was also observed in 4-month-old potted neouslyunderfieldconditions. plantsingreenhousesbymonitoringrecoveryafterwithholding waterfor18days[148]. Sakamotoet al. [149]modified GA levelsbyoverexpres- REFERENCES sion of OsGA2ox1, a gene encoding GA2-oxidase. Interest- ingly,whentheactinpromoterconstitutivelyexpressedthe gene,transgenicriceshowedseveredwarfismbutfailedto [1] S.H.Wani,S.K.Sah,Biotechnologyandabioticstress setgrain,giventhatGAisinvolvedinbothshootelongation toleranceinrice,J.RiceRes.2(2014),e105http://dx.doi.org/ and reproductive development. In contrast, OsGA2ox1 ec- 10.4172/jrr.1000e105. topic expression at the site of bioactive GA synthesis in [2] D.Tilman,C.Balzer,J.Hill,B.L.Belfort,Globalfooddemand shootsunderthecontrolofthepromoterofaGAbiosynthe- andthesustainableintensificationofagriculture,Proc.Natl. Acad.Sci.U.S.A.108(2011)20260–20264. sis gene, OsGA3ox2 (D18), resulted in a semi-dwarf pheno- [3] F.Qin,S.Kazuo,Y.S.Kazuo,Achievementsandchallenges type showing normal flowering and grain development. inunderstandingplantabioticstressresponsesand Attempts at engineering phytohormones for enhanced tolerance,PlantCellPhysiol.52(2011)1569–1582. abioticstresstoleranceofplantsarelistedinTable1. [4] S.H.Wani,N.B.Singh,A.Haribhushan,J.A.Mir, Giventhatbiosyntheticpathwaysandconvergencepoints Compatiblesoluteengineeringinplantsforabioticstress for crosstalk are still not clear, there is further scope to tolerance—theroleofglycinebetaine,Curr.Genomics14 increase our understanding in this regard and to identify (2013)157–165. [5] U.Vob,A.Bishopp,E.Farcot,M.J.Bennett,Modelling novel genes encoding phytohormone metabolisms to be hormonalresponseanddevelopment,TrendsPlantSci.19 targeted for engineering abiotic stress tolerance in crop (2014)311–319. plants. Recent findings have opened various avenues for [6] K.Kazan,Diverserolesofjasmonatesandethylene targeting phytohormones for genetic engineering to confer- inabioticstresstolerance,TrendsPlantSci.20(2015) ringabioticstresstoleranceonimportantcropspecies. 219–229.

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2nd Vinay Kumar plant growth and development and abiotic stress tolerance, besides their .. second major stress reducing crop productivity.
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