This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.
Food and Agriculture Organisation of the United Nations. FAO Success Stories on Climate Smart Agriculture. FAO I3871E/1/05.14.Search in Google Scholar
International Society for the Acquisition of Agricultural Applications. GM Crops and the Environment. Pocket K 4 2017.2017Search in Google Scholar
Federoff NV. Food in a future of 10 billion. Agriculture and Food Security. 2015; 4: 11.10.1186/s40066-015-0031-7FederoffNVFood in a future of 10 billion2015411Open DOISearch in Google Scholar
Food and Agriculture Organisation, United Nations Development Programme, World Programme for Food. The State of Food Insecurity in the World. http://www.fao.org/3/a-i4646e.pdf.2015http://www.fao.org/3/a-i4646e.pdf.2015Search in Google Scholar
International Society for the Acquisition of Agricultural Applications. Can Mother earth feed 9 + Billion by 2050? ISAAA Infographic 1. 2016. www.isaaa.org2050?ISAAA Infographic 1. 2016www.isaaa.orgSearch in Google Scholar
International Society for the Acquisition of Agricultural Applications. Contribution of Biotech Crops to Sustainability. ISAAA Infographic 2. 2017. www.isaaa.org2017www.isaaa.orgSearch in Google Scholar
Klumper W, Qaim M. A Meta-analysis of the impacts of genetically modified crops. PLoS ONE 2014; 9(11): e111629.10.1371/journal.pone.011162925365303KlumperWQaimMA Meta-analysis of the impacts of genetically modified crops2014911e111629421879125365303Open DOISearch in Google Scholar
Brookes G, Barfoot P. GM Crops: global socio-economic and environmental impacts 1996-2015. 2017. PG Economics Ltd., UK, pp. 1-201.BrookesGBarfootP2017PG Economics LtdUK1201Search in Google Scholar
James C. 20th Anniversary (1996-2015) of the Global Commercialisation of Biotech Crops and Biotech Crop Highlights in 2015. ISAAA Brief 51 2015. www.isaaa.orgJamesC2015www.isaaa.orgSearch in Google Scholar
James C. ISAAA Brief 52. 2016. www.isaaa.orgJamesC2016www.isaaa.org10.1093/acprof:oso/9780198712077.003.0003Search in Google Scholar
Stua M, Dearnley E What will BREXIT mean for the climate? The Conversation 2017; https://theconversation.com/what-will-brexit-mean-for-the-climate-clue-it-doesnt-look-good-87476StuaMDearnleyE2017https://theconversation.com/what-will-brexit-mean-for-the-climate-clue-it-doesnt-look-good-87476Search in Google Scholar
Gartland KMA. Responding to climate change: barriers to progress and green opportunities. Biochemist 2006; October 54-55.GartlandKMAResponding to climate change: barriers to progress and green opportunities2006October 54-55Search in Google Scholar
Ruane J, Sonnino A. Agricultural biotechnologies in developing countries and their possible contribution to food security. J. Biotechnol. 2011; 156: 356-363.10.1016/j.jbiotec.2011.06.01321723334RuaneJSonninoAAgricultural biotechnologies in developing countries and their possible contribution to food security201115635636321723334Open DOISearch in Google Scholar
Gartland KMA, Gartland JS. Green biotechnology for food security in climate change. Reference Module in Food Sciences 2016; Elsevier pp.1-9. http://dx.doi.org/10.1016/B978-0-08-100596-5.03071-7GartlandKMAGartlandJSGreen biotechnology for food security in climate change2016Elsevier19http://dx.doi.org/10.1016/B978-0-08-100596-5.03071-710.1016/B978-0-08-100596-5.03071-7Search in Google Scholar
US National Academies of Sciences, Engineering & Medicine. Genetically engineered crops: experiences and prospects. 2016. https://doi.org/10.17226/233952016https://doi.org/10.17226/2339510.17226/2339528230933Search in Google Scholar
Royal Society. GM Plants: questions and answers. 2016; DES3710. https://royalsociety.org/~/media/policy/projects/gm-plants/gmplant-q-and-a.pdf2016https://royalsociety.org/~/media/policy/projects/gm-plants/gmplant-q-and-a.pdfSearch in Google Scholar
American Council for Science and Health. Meta-analysis shows GM crops reduce pesticide use by 37 percent.Search in Google Scholar
Guo D, Chen F, Inoue K et al. Downregulation of caffeic acid 3-O-methyltransferase and caffeoyl coA 3-O-methyltransferase in transgenic alfalfa: impacts on lignin structure and implications for the biosynthesis of G and S lignin. Plant Cell 2001; 13: 73-88.10.1105/tpc.13.1.73GuoDChenFInoueKet alDownregulation of caffeic acid 3-O-methyltransferase and caffeoyl coA 3-O-methyltransferase in transgenic alfalfa: impacts on lignin structure and implications for the biosynthesis of G and S lignin200113738810221511158530Open DOISearch in Google Scholar
Wechsler SJ, Milkove D. Genetically Modified Alfalfa Production in the United States. 2017; United States Department of Agriculture Economic Research Service. https://www.ers.usda.gov/amber-waves/2017/may/genetically-modified-alfalfa-production-in-the-united-states/WechslerSJMilkoveD2017United States Department of Agriculture Economic Research Servicehttps://www.ers.usda.gov/amber-waves/2017/may/genetically-modified-alfalfa-production-in-the-united-states/Search in Google Scholar
Brookes G, Taheripour F, Tyner WE. The contribution of glyphosate to agriculture and potential impact of restrictions on use at the global level. GM Crops and Food 2017; https://doi.org/10.1080/21645698.2017.1390637BrookesGTaheripourFTynerWEThe contribution of glyphosate to agriculture and potential impact of restrictions on use at the global level2017https://doi.org/10.1080/21645698.2017.139063710.1080/21645698.2017.1390637579041329035143Search in Google Scholar
United States Dept. of Agriculture Biotechnology Consultation - Note to File BNF 000153 2017. https://www.fda.gov/Food/IngredientsPackagingLabeling/GEPlants/Submissions/ucm5423392017https://www.fda.gov/Food/IngredientsPackagingLabeling/GEPlants/Submissions/ucm542339Search in Google Scholar
Rommens CM, Yan H, Swords K et al. Low-acrylamide French fries and potato chips. Plant Biotechnology Journal 2008; 6:843-853.1866237210.1111/j.1467-7652.2008.00363.xRommensCMYanHSwordsKet alLow-acrylamide French fries and potato chips20086843853260753218662372Search in Google Scholar
Simplot Plant Sciences 2017. Innate second generation potatoes with late blight protection receive EPA and FDA clearances. http://www.simplot.com/plant_sciencesSimplot Plant Sciences2017http://www.simplot.com/plant_sciencesSearch in Google Scholar
Halterman D, Guenthner J, Collinge S et al. Biotech crops in the 21st century: 20 years since the first biotech potato. Am. J. Potato Res. 2016; 93: 1-20.10.1007/s12230-015-9485-1HaltermanDGuenthnerJCollingeSet alBiotech crops in the 21st century: 20 years since the first biotech potato201693120Open DOISearch in Google Scholar
Armen, J. Arctic apples: Leading the ‘next wave’ of biotech foods with consumer benefits. Australasian Biotechnology, 2015; 25: 50. No. 2, http://search.informit.com.au/documentSummary;dn=296007511823496;res=IELHEAISSN:1036-7128ArmenJArctic apples: Leading the ‘next wave’ of biotech foods with consumer benefits20152550No. 2http://search.informit.com.au/documentSummary;dn=296007511823496;res=IELHEAISSN:1036-7128Search in Google Scholar
Smyth SJ. Canadian regulatory perspectives on genome engineered crops. GM Crops and Food 2017; 8: 35-43.10.1080/21645698.2016.1257468SmythSJCanadian regulatory perspectives on genome engineered crops201783543559297527858499Open DOISearch in Google Scholar
Silva KJP, Brunings AM, Pereira JA et al. The Arabidopsis ELP/ELO3 and ELP4/ELO1 genes enhance disease resistance in Fragaria vesca. BMC Plant Biology 2017; 17:230.2919117010.1186/s12870-017-1173-5SilvaKJPBruningsAMPereiraJAet alThe Arabidopsis ELP/ELO3 and ELP4/ELO1 genes enhance disease resistance in Fragaria vesca201717230570992629191170Search in Google Scholar
Van Der Straeten D, Fitzpatrick TB, De Steur H Biofortification of crops: achievements future challenges, socio-economic, health and ethical aspects. Curr. Op. Biotech. 2017; 44:vii-x.10.1016/j.copbio.2017.03.007Van Der StraetenDFitzpatrickTBDe SteurHBiofortification of crops: achievements future challenges, socio-economic, health and ethical aspects201744viix28342725Open DOISearch in Google Scholar
Barreca N. Biofortification pioneers win 2016 World Food Prize for fight against malnutrition. 2016; World Food Prize Organisation 2016; https://www.worldfoodprize.org/index.cfm/87428/40322/biofortification_pioneers_win_2016world_food_prizeBarrecaN2016World Food Prize for fight against malnutrition. 2016; World Food Prize Organisation 2016https://www.worldfoodprize.org/index.cfm/87428/40322/biofortification_pioneers_win_2016world_food_prizeSearch in Google Scholar
Blancquaert D, Van Daele J, Strobbe S et al. Improving folate (vitamin B9) stability in biofortified rice through metabolic engineering. Nature Biotechnology 2015; 33: 1076-1078.10.1038/nbt.335826389575BlancquaertDVan DaeleJStrobbeSet alImproving folate (vitamin B9) stability in biofortified rice through metabolic engineering2015331076107826389575Open DOISearch in Google Scholar
Li K-T, Moulin M, Mangel N et al. Increased bioavailable vitamin B6 in field grown transgenic cassava for dietary sufficiency. Nature Biotechnology 2015; 33: 1029-1032.10.1038/nbt.331826448082LiK-TMoulinMMangelNet alIncreased bioavailable vitamin B6 in field grown transgenic cassava for dietary sufficiency2015331029103226448082Open DOISearch in Google Scholar
Giuliano G. Provitamin A biofortification of crop plants: a gold rush with many miners. Current Opinion in Biotechnology 2017; 44: 169-182.2825468110.1016/j.copbio.2017.02.001GiulianoGProvitamin A biofortification of crop plants: a gold rush with many miners20174416918228254681Search in Google Scholar
Potrykus I. “Golden Rice”, a GMO-product for public good, and the consequences of GE-regulation. J of Plant biochemistry and biotechnology 2012; 21S: 68-75.PotrykusI.“Golden Rice”, a GMO-product for public good, and the consequences of GE-regulation201221S687510.1007/s13562-012-0130-5Search in Google Scholar
Golden Rice Project 2017. http://www.goldenrice.org2017http://www.goldenrice.orgSearch in Google Scholar
Stone GD, Glover D. Disembedding grain: Golden rice, the Green Revolution and heirloom seeds in the Philippines. Agriculture and Human Values 2017; 34: 87-102.10.1007/s10460-016-9696-1StoneGDGloverDDisembedding grain: Golden rice, the Green Revolution and heirloom seeds in the Philippines20173487102Open DOISearch in Google Scholar
Tang G, Qin J, Dolnikowski GG et al. Golden Rice is an effective source of vitamin A. American Journal of Clinical Nutrition 2009; 89: 1776-1783.10.3945/ajcn.2008.27119TangGQinJDolnikowskiGGet alGolden Rice is an effective source of vitamin A20098917761783268299419369372Open DOISearch in Google Scholar
De Steur H, Mehta S, Gellynck X et al. GM biofortified crops: potential effects on targeting the micronutrient intake gap in human populations. Current opinion in Biotechnology 2017; 44: 181-188.10.1016/j.copbio.2017.02.003De SteurHMehtaSGellynckXet alGM biofortified crops: potential effects on targeting the micronutrient intake gap in human populations20174418118828288329Open DOISearch in Google Scholar
Paine JA, Shipton CA, Chaggar S, et al. Improving the nutritional value of Golden Rice through increased pro-vitamin A content. Nature Biotechnology 2005; 23:482-487.10.1038/nbt108215793573PaineJAShiptonCAChaggarSet alImproving the nutritional value of Golden Rice through increased pro-vitamin A content20052348248715793573Open DOISearch in Google Scholar
Brooks S. Biofortification: Lessons from the Golden Rice Project. Food Chain 2013; 3: 77-88.10.3362/2046-1887.2013.007BrooksSBiofortification: Lessons from the Golden Rice Project201337788Open DOISearch in Google Scholar
Kava R. All I want for Christmas is Golden Rice. American Council for Science and Health News 2017; 08.12.2017. https://www.acsh.org/news/2017/12/08/all-i-want-christmas-golden-rice-12251KavaRAll I want for Christmas is Golden Rice201708.12.2017https://www.acsh.org/news/2017/12/08/all-i-want-christmas-golden-rice-12251Search in Google Scholar
World Health Organisation. Micronutrient deficiencies: Vitamin A deficiency 2017; http://www.who.int/nutrition/topics/vad/en/2017http://www.who.int/nutrition/topics/vad/en/Search in Google Scholar
UNICEF Data. East Asia and the Pacific achieved the highest twodose coverage with vitamin A supplements of all regions in 2015. December 2017; https://data.unicef.org/topic/nutrition/vitamin-a-deficiency/2017https://data.unicef.org/topic/nutrition/vitamin-a-deficiency/Search in Google Scholar
Kava R. Move over, Golden rice- Golden potatoes are on the way. American Council for Science and Health News 2017; 13.11.2017. https://www/acsh.org/news/2017/11/13/move-over-goldenrice-%2%80%94-golden-potatoes-are-way-12136KavaRMove over, Golden rice- Golden potatoes are on the way201713.11.2017https://www/acsh.org/news/2017/11/13/move-over-goldenrice-%2%80%94-golden-potatoes-are-way-12136Search in Google Scholar
Chitchumroonchokchai C, Diretto G, Parisi B et al. Potential of golden potatoes to improve vitamin a and vitamin E status in developing countries. PLoSONE 2017; 12 (11): e0187102. https://doi.org/10.1371/journal.pone.018710210.1371/journal.pone.0187102ChitchumroonchokchaiCDirettoGParisiBet alPotential of golden potatoes to improve vitamin a and vitamin E status in developing countries20171211e0187102https://doi.org/10.1371/journal.pone.0187102567887029117188Open DOISearch in Google Scholar
Che P, Zhao Z-Y, Glassman K et al. Elevated vitamin E content improves all-trans β-carotene accumulation and stability in biofortified sorghum. PNAS (USA) 2016; 113: 11040-1104510.1073/pnas.1605689113ChePZhaoZ-YGlassmanKet alElevated vitamin E content improves all-trans β-carotene accumulation and stability in biofortified sorghum20161131104011045504720127621466Open DOISearch in Google Scholar
Report G. Investing in the future- A united call to action on vitamin and mineral deficiencies. 2009; http://www.unitedcalltoaction.org/index.aspReportG2009http://www.unitedcalltoaction.org/index.aspSearch in Google Scholar
Blancquaert D, De Steur H, Gellynck X et al. Metabolic engineering of micronutrients in crop plants. Annals New York academy Sciences (2017) 1390: 59-73.10.1111/nyas.13274BlancquaertDDe SteurHGellynckXet alMetabolic engineering of micronutrients in crop plants20171390597327801945Open DOISearch in Google Scholar
Waltz E. Vitamin A Super Banana in human trials. Nature Biotechnology 2014; 32: 857.2520302510.1038/nbt0914-857WaltzEVitamin A Super Banana in human trials20143285725203025Search in Google Scholar
Paul J-Y, Khanna H, Kleidon J et al. Golden bananas in the field: elevated pro-vitamin A from the expression of a single banan transgene. Plant Biotech. J. 2017; 15: 520-532.10.1111/pbi.12650PaulJ-YKhannaHKleidonJet alGolden bananas in the field: elevated pro-vitamin A from the expression of a single banan transgene201715520532536268127734628Open DOISearch in Google Scholar
Mbabazi R. Molecular characterisation and carotenoid quantification of pro-vitamin A biofortified genetically modified bananas in Uganda. PhD Thesis. 2015; Queensland University of Technology.MbabaziRPhD Thesis2015Queensland University of TechnologySearch in Google Scholar
Buah S, Mlalazi B., Khanna H, Dale JL and Mortimer CL. The quest for golden bananas: investigating carotenoid regulation in a Fe’i group Musa cultivar. J. Agric. Food Chem. 2016; 64: 3176-3185.10.1021/acs.jafc.5b05740BuahSMlalaziB.KhannaHDaleJLMortimerCLThe quest for golden bananas: investigating carotenoid regulation in a Fe’i group Musa cultivar2016643176318527041343Open DOISearch in Google Scholar
Dhandapani R, Singh VP, Arora A et al. Differential accumulation of β-carotene and tissue specific expression of phytoene synthase (MaPSy) gene in banana (Musa sp.) cultivars. J Food Sci. technol. 2017; 54: 4416-4426.10.1007/s13197-017-2918-829184248DhandapaniRSinghVPAroraAet alDifferential accumulation of β-carotene and tissue specific expression of phytoene synthase (MaPSy) gene in banana (Musa sp.) cultivars20175444164426568602229184248Open DOISearch in Google Scholar
Water Efficient Maize for Africa. 2017; https://wema.aatf-africa.org/about-wema-project2017https://wema.aatf-africa.org/about-wema-projectSearch in Google Scholar
Xu J, Yuan Y, Xu Y et al. Identification of candidate genes for drought tolerance by whole-genome resequencing in maize. BMC Plant Biology 2014; 14: 83.2468480510.1186/1471-2229-14-83XuJYuanYXuYet alIdentification of candidate genes for drought tolerance by whole-genome resequencing in maize20141483402122224684805Search in Google Scholar
African Agricultural Technology Foundation. DroughtTEGO WE1101 Drought-tolerant maize hybrid. 2017; http://www.aatf-africa.org2017http://www.aatf-africa.orgSearch in Google Scholar
Morsy M. Microbial symbionts: a potential bio-boom. J. Investig. Genomics 2015; 2: 00015.MorsyMMicrobial symbionts: a potential bio-boom201520001510.15406/jig.2015.02.00015Search in Google Scholar
Castiglioni P, Warner D, Bensen RJ et al. Bacterial RNA chaperones confer abiotic stress tolerance. Plant Physiology. 2008; 147: 446-455.1852487610.1104/pp.108.118828CastiglioniPWarnerDBensenRJet alBacterial RNA chaperones confer abiotic stress tolerance2008147446455240902018524876Search in Google Scholar
Nuccio ML, Wu J, Mowers R et al. Expression of tehalose-6-phosphate phosphatase in maize ears improves yield in well-watered and drought conditions. Nature Biotechnology. 2015; 33: 862-869.10.1038/nbt.3277NuccioMLWuJMowersRet alExpression of tehalose-6-phosphate phosphatase in maize ears improves yield in well-watered and drought conditions20153386286926473199Open DOISearch in Google Scholar
Adee E. Drought-tolerant corn hybrids yield more in droughtstressed environments with no penalty in non-stressed environments. Frontiers in Plant Science. 2016; 13 Oct 2016.27790237AdeeEDrought-tolerant corn hybrids yield more in droughtstressed environments with no penalty in non-stressed environments201613 Oct 201610.3389/fpls.2016.01534506175327790237Search in Google Scholar
Rea-hybrids. Introducing Genuity DroughtGard hybrids. 2017; http://www.rea-hybrids.com2017http://www.rea-hybrids.comSearch in Google Scholar
Siegfried BD, Hellmich RL. Understanding successful resistance management: the European corn borer and Bt corn in the United States. GM Crops Food. 2012; 3:184-193.10.4161/gmcr.2071522688691SiegfriedBDHellmichRLUnderstanding successful resistance management: the European corn borer and Bt corn in the United States2012318419322688691Open DOISearch in Google Scholar
Ammann K The impact of agricultural biotechnology on biodiversity. (2004) Botanic gardens, University of Bern.AmmannK2004Botanic gardensUniversity of BernSearch in Google Scholar
Salt tolerance of plants. University of Alberta Agriculture and Forestry (2017). http://www1.agric.gov.ab.ca/$department/deptdocs.nsf/all/agdex33032017http://www1.agric.gov.ab.ca/$department/deptdocs.nsf/all/agdex3303Search in Google Scholar
Tilbrook J, Schilling RK, Berger B et al. Variation in shoot tolerance mechanisms not related to ion toxicity in barley. Functional Plant Biology (2017) 14: 1194-1206.TilbrookJSchillingRKBergerBet alVariation in shoot tolerance mechanisms not related to ion toxicity in barley2017141194120610.1071/FP1704932480644Search in Google Scholar
Zou C, Chen A, Xiao L et al. A high-quality genome assembly of quinoa provides insightsinto the molecular basis of salt bladder- based salinity tolerance and exceptional nutritional value. Cell Research (2017) DOI: 10.1038/cr.2017.124.ZouCChenAXiaoLet alA high-quality genome assembly of quinoa provides insightsinto the molecular basis of salt bladder- based salinity tolerance and exceptional nutritional value201710.1038/cr.2017.124567415828994416Open DOISearch in Google Scholar
Rakshit S. The Handbook of Plant Mutation Screening: Mining of natural and induced alleles. Wiley-VCH (2010) pp. 185-197.RakshitSThe Handbook of Plant Mutation Screening: Mining of natural and induced alleles2010185197Search in Google Scholar
Takagi H, Tamiru M, Abe A et al. MutMap accelerates breeding of a salt-tolerant rice cultivar. Nature Biotechnology (2015) 33: 445-449.2579893610.1038/nbt.3188TakagiHTamiruMAbeAet al MutMap accelerates breeding of a salt-tolerant rice cultivar20153344544925798936Search in Google Scholar
Trapnell C, Pachter L, Salzberg SL. TopHat: discovering splice junctions with RNA-seq. Bioinformatics (2009)25: 1105-1109.1928944510.1093/bioinformatics/btp120TrapnellCPachterLSalzbergSLTopHat: discovering splice junctions with RNA-seq20092511051109267262819289445Search in Google Scholar
Goswani K, Tripathi A, Sanan-Mishra N. Comparative miRomics of salt-tolerant and salt-sensitive rice. J Integrative bioinformatics (2017) 2017002.GoswaniKTripathiASanan-MishraNComparative miRomics of salt-tolerant and salt-sensitive rice201710.1515/jib-2017-0002604280428637931Search in Google Scholar
Tan GC, Chan E, Molnar A et al. 5’-isomiR variation is of functional and evolutionary importance. Nucleic Acids Research (2104) 42: 9424-9435.TanGCChanEMolnarAet al5’-isomiR variation is of functional and evolutionary importance2104429424943510.1093/nar/gku656413276025056318Search in Google Scholar
Morin RD, O’Connor MD, Griffith M et al. Application of massively parallel sequencing to microRNA profiling and discovery in human embryonic stem cells”. Genome Research (2008); 18: 610-621.1828550210.1101/gr.7179508MorinRDO’ConnorMDGriffithMet alApplication of massively parallel sequencing to microRNA profiling and discovery in human embryonic stem cells”200818610621227924818285502Search in Google Scholar
Regalado A. The next great GMO debate. MIT Technology Review (2015) https://www.technologyreview.com/s/540136/the-nextgreat-gmo-debateRegaladoAThe next great GMO debate2015https://www.technologyreview.com/s/540136/the-nextgreat-gmo-debateSearch in Google Scholar
Shew AM, Danforth DM, Nalley LL et al. New innovations in agricultural biotech: consumer acceptance of topical RNAi in rice production. Food Control (2017) 81: 189-195.10.1016/j.foodcont.2017.05.047ShewAMDanforthDMNalleyLLet alNew innovations in agricultural biotech: consumer acceptance of topical RNAi in rice production201781189195Open DOISearch in Google Scholar
Shan Q, Wang Y, Li j et al. Genome editing in rice and wheat using the CRISPR/Cas9 system. Nature Protocols (2014) 9: 2395-2410.10.1038/nprot.2014.157ShanQWangYLijet alGenome editing in rice and wheat using the CRISPR/Cas9 system201492395241025232936Open DOISearch in Google Scholar
Gartland KMA, Dundar M, Beccari T et al. Advances in biotechnology: genomics and genome editing. EuroBiotech Journal (2017) 1:1-8.GartlandKMADundarMBeccariTet alAdvances in biotechnology: genomics and genome editing201711810.24190/ISSN2564-615X/2017/01.02Search in Google Scholar
Ricroch A, Clairand P, Harwood W Use of CRISPR systems in plant genome editing: toward new opportunities in agriculture. Emerging Topics in Life Sciences (2017) 1: 169-182.10.1042/ETLS20170085RicrochAClairandPHarwoodWUse of CRISPR systems in plant genome editing: toward new opportunities in agriculture20171169182728899333525765Open DOISearch in Google Scholar
LeBlanc C, Zhang F, Mendez J et al. Increased efficiency of targeted mutagenesis by CRISPR/Cas9 in plants using heat stress. Plant Journal (2017) DOI: 10.1111/tpj.13782LeBlancCZhangFMendezJet alIncreased efficiency of targeted mutagenesis by CRISPR/Cas9 in plants using heat stress201710.1111/tpj.1378229161464Open DOISearch in Google Scholar
Shen H, Zhong X, Zhao F et al. Overexpression of receptor-like kinase ERECTA improves thermotolerance in rice and tomato. Nature Biotechnology (2015) 33: 996-1003.2628041310.1038/nbt.3321ShenHZhongXZhaoFet alOverexpression of receptor-like kinase ERECTA improves thermotolerance in rice and tomato201533996100326280413Search in Google Scholar
Nuccio ML, Wu J, Mowers R et al. Expression of trehalose-6-phosphate phosphatase in maize ears improves yields in well-watered and drought conditions. Nature Biotechnology (2015) 33: 862-869.2647319910.1038/nbt.3277NuccioMLWuJMowersRet alExpression of trehalose-6-phosphate phosphatase in maize ears improves yields in well-watered and drought conditions20153386286926473199Search in Google Scholar
Yang X, Hu R, Tuskan GA et al. The Kalanchoe genome provides insights into crassulacean acid metabolism. Nature Communications (2017) 8: 1899.10.1038/s41467-017-01491-729196618YangXHuRTuskanGAet alThe Kalanchoe genome provides insights into crassulacean acid metabolism201781899571193229196618Open DOISearch in Google Scholar