Abstract
One of the crucial challenges faced by the plant research community today is in understanding the myriad processes that orchestrate growth, which is paramount to produce sufficient biomass for food and non-food applications in the future. Plant photoreceptors play important regulatory roles in developmental processes that can consequently affect productivity. The UN Food and Agriculture Organization estimates that by 2030 the world population will reach 8.3 billion. Biological approaches that can increase productivity and lower postharvest losses are thus essential for future food security. Regulating the activity of genes that can affect plant architecture, development or yield could likely be the key to increasing plant productivity. Recent advances in plant research have identified several photoreceptor genes and gene networks that play pivotal roles in these responses. The knowledge arising from such research therefore needs to be translated to the field to support programs aimed at increasing crop productivity. Given the evidence for their role in determining agricultural traits, these genes are favorably placed to become the focus of targeted breeding approaches for enhancing the agronomic value of domesticated lines.
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References
Ahmad M, Jarillo JA, Cashmore AR (1998) Chimeric proteins between cry1 and cry2 Arabidopsis blue light photoreceptors indicate overlapping functions and varying protein stability. Plant Cell 10:197–207
Alba R, Cordonnier-Pratt MM, Pratt LH (2000a) Fruit-localized phytochromes regulate lycopene accumulation independently of ethylene production in tomato. Plant Physiol 123:363–370
Alba R, Kelmenson PM, Cordonnier-Pratt MM, Pratt LH (2000b) The phytochrome gene family in tomato and the rapid differential evolution of this family in angiosperms. Mol Biol Evol 17:362–373
Ammer C (2003) Growth and biomass partitioning of Fagus sylvatica L. and Quercus robur L. seedlings in response to shading and small changes in the R/FR-ratio of radiation. Ann For Sci 60:163–171
Appenroth KJ, Lenk G, Goldau L, Sharma R (2006) Tomato seed germination: regulation of different response modes by phytochrome B2 and phytochrome A. Plant, Cell Environ 29:701–709
Azari R, Reuveni M, Evenor D, Nahon S, Shlomo H, Chen L, Levin I (2010) Overexpression of UV-DAMAGED DNA BINDING PROTEIN 1 links plant development and phytonutrient accumulation in high pigment-1 tomato. J Exp Bot 61:3627–3637
Ballaré CL, Casal JJ (2000) Light signals perceived by crop and weed plants. Field Crops Res 67:149–160
Boccalandro HE, Ploschuk EL, Yanovsky MJ, Sanchez RA, Gatz C, Casal JJ (2003) Increased phytochrome B alleviates density effects on tuber yield of field potato crops. Plant Physiol 133:1539–1546
Boccalandro HE, Giordano CV, Ploschuk EL, Piccoli PN, Bottini Rn, Casal JJ (2012) Phototropins but not cryptochromes mediate the blue light-specific promotion of stomatal conductance, while both enhance photosynthesis and transpiration under full sunlight. Plant Physiol 158:1475–1484
Botto JF, Smith H (2002) Differential genetic variation in adaptive strategies to a common environmental signal in Arabidopsis accessions: phytochrome-mediated shade avoidance. Plant, Cell Environ 25:53–63
Boylan MT, Quail PH (1989) Oat phytochrome is biologically active in transgenic tomatoes. Plant Cell 1:765–773
Briggs WR, Christie JM (2002) Phototropins 1 and 2: versatile plant blue-light receptors. Trends Plant Sci 7:204–210
Causse M, Duffe P, Gomez MC, Buret M, Damidaux R, Zamir D, Gur A, Chevalier C, Lemaire-Chamley M, Rothan C (2004) A genetic map of candidate genes and QTLs involved in tomato fruit size and composition. J Exp Bot 55:1671–1685
Chary SN, Wormser DB, Watson JC (2002) Sequence of the PsPK4 gene encoding phototropin 1. http://www.ncbi.nlm.nih.gov/protein/AAM15725.1
Chen M, Chory J, Fankhauser C (2004) Light signal transduction in higher plants. Annu Rev Genet 38:87–117
Childs KL, Miller FR, Cordonnier-Pratt MM, Pratt LH, Morgan PW, Mullet JE (1997) The sorghum photoperiod sensitivity gene, Ma3, encodes a phytochrome B. Plant Physiol 113:611–619
Christie JM, Reymond P, Powell GK, Bernasconi P, Raibekas AA, Liscum E, Briggs WR (1998) Arabidopsis NPH1: a flavoprotein with the properties of a photoreceptor for phototropism. Science 82:1698–1701
Chung N-J, Paek N-C (2003) Photoblastism and ecophysiology of seed germination in weedy rice. Agron J 95:184–190
Clack T, Mathews S, Sharrock R (1994) The phytochrome apoprotein family in Arabidopsis is encoded by five genes: the sequences and expression of PHYD and PHYE. Plant Mol Biol 25:413–427
Davuluri GR, van Tuinen A, Fraser PD, Manfredonia A, Newman R, Burgess D, Brummell DA, King SR, Palys J, Uhlig J, Bramley PM, Pennings HM, Bowler C (2005) Fruit-specific RNAi-mediated suppression of DET1 enhances carotenoid and flavonoid content in tomatoes. Nat Biotechnol 23:890–895
Devlin PF (2002) Signs of the time: environmental input to the circadian clock. J Exp Bot 53:1535–1550
Devlin PF, Robson PR, Patel SR, Goosey L, Sharrock RA, Whitelam GC (1999) Phytochrome D acts in the shade-avoidance syndrome in Arabidopsis by controlling elongation growth and flowering time. Plant Physiol 119:909–915
Devlin PF, Yanovsky MJ, Kay SA (2003) A genomic analysis of the shade avoidance response in Arabidopsis. Plant Physiol 133:1617–1629
Devos K, Beales J, Ogihara Y, Doust A (2005) Comparative sequence analysis of the phytochrome C gene and its upstream region in allohexaploid wheat reveals new data on the evolution of its three constituent genomes. Plant Mol Biol 58:625–641
Doganlar S, Tanksley SD, Mutschler MA (2000) Identification and molecular mapping of loci controlling fruit ripening time in tomato. Theor Appl Genet 100:249–255
Donohue K, Heschel MS, Butler CM, Barua D, Sharrock RA, Whitelam GC, Chiang GCK (2008) Diversification of phytochrome contributions to germination as a function of seed-maturation environment. New Phytol 177:367–379
El-Din El-Assal S, Alonso-Blanco C, Peeters AJM, Raz V, Koornneef M (2001) A QTL for flowering time in Arabidopsis reveals a novel allele of CRY2. Nat Genet 29:435–440
Enfissi EMA, Barneche F, Ahmed I, Lichtlé C, Gerrish C, McQuinn RP, Giovannoni JJ, Lopez-Juez E, Bowler C, Bramley PM, Fraser PD (2010) Integrative transcript and metabolite analysis of nutritionally enhanced DE-ETIOLATED1 downregulated tomato fruit. Plant Cell 22:1190–1215
Exner V, Alexandre C, Rosenfeldt G, Alfarano P, Nater M, Caflisch A, Gruissem W, Batschauer A, Hennig L (2010) A gain-of-function mutation of Arabidopsis cryptochrome1 promotes flowering. Plant Physiol 154:1633–1645
Facella P, Lopez L, Chiappetta A, Bitonti MB, Giuliano G, Perrotta G (2006) CRY-DASH gene expression is under the control of the circadian clock machinery in tomato. FEBS Lett 580:4618–4624
Franklin KA (2008) Shade avoidance. New Phytol 179:930–944
Fridman E, Carrari F, Liu Y-S, Fernie AR, Zamir D (2004) Zooming in on a quantitative trait for tomato yield using interspecific introgressions. Science 305:1786–1789
Garg AK, Sawers RJ, Wang H, Kim JK, Walker JM, Brutnell TP, Parthasarathy MV, Vierstra RD, Wu RJ (2006) Light-regulated overexpression of an Arabidopsis phytochrome A gene in rice alters plant architecture and increases grain yield. Planta 223:627–636
Giliberto L, Perrotta G, Pallara P, Weller JL, Fraser PD, Bramley PM, Fiore A, Tavazza M, Giuliano G (2005) Manipulation of the blue light photoreceptor cryptochrome 2 in tomato affects vegetative development, flowering time, and fruit antioxidant content. Plant Physiol 137:199–208
González-Schain ND, Diaz-Mendoza M, Zurczak M, Suárez-López P (2012) Potato CONSTANS is involved in photoperiodic tuberization in a graft-transmissible manner. Plant J 70:678–690
Hahn T-R, Woo T-W, Seo H-S, Choi Y-D (1994) Nucleotide sequence of phytochrome B gene from Soybean (Glycine max L.). http://www.ncbi.nlm.nih.gov/protein/AAA34000
Heijde M, Ulm R (2012) UV-B photoreceptor-mediated signalling in plants. Trends Plant Sci 17:230–237
Hershey HP, Barker RF, Idler KB, Murray MG, Quail PH (1987) Nucleotide sequence and characterization of a gene encoding the phytochrome polypeptide from Avena. Gene 61:339–348
Heyer A, Gatz C (1992) Isolation and characterization of a cDNA-clone coding for potato type B phytochrome. Plant Mol Biol 20:589–600
Hirose F, Shinomura T, Tanabata T, Shimada H, Takano M (2006) Involvement of rice cryptochromes in de-etiolation responses and flowering. Plant Cell Physiol 47:915–925
Ito S, Song YH, Imaizumi T (2012) LOV domain-containing f-box proteins: light-dependent protein degradation modules in Arabidopsis. Mol Plant 5(3):573–582
Inagaki N, Xie X, Yuzurihara N, Ishizuka T, Nishimura M, Shinomura T, Takano M (2008) Isolation and characterization of rice phytochrome B mutants. http://www.ncbi.nlm.nih.gov/protein/BAD86669
Inoue S, Kinoshita T, Shimazaki K (2005) Possible involvement of phototropins in leaf movement of kidney bean in response to blue light. Plant Physiol 138:1994–2004
Ishibashi N, Setoguchi H (2012) Polymorphism of DNA sequences of cryptochrome genes is not associated with the photoperiodic flowering of wild soybean along a latitudinal cline. J Plant Res 125:483–488
Izawa T, Oikawa T, Tokutomi S, Okuno K, Shimamoto K (2000) Phytochromes confer the photoperiodic control of flowering in rice (a short-day plant). Plant J 22:391–399
Jackson SD, Heyer A, Dietze J, Prat S (1996) Phytochrome B mediates the photoperiodic control of tuber formation in potato. Plant J 9:159–166
Jarillo JA, Ahmad M, Cashmore AR (1998) NPL1 (accession no AF053941): a second member of the NPH1 serine/threonine kinase family of Arabidopsis. Plant Physiol 117:719
Jarillo JA, del Olmo I, Gómez-Zambrano A, Lázaro A, López-González L, Miguel E, Narro-Diego L, Sáez D, Piñeiro M (2008) Photoperiodic control of flowering time. Span J Agric Res 6:221–244
Kanegae H, Tahir M, Savazzini F, Yamamoto K, Yano M, Sasaki T, Kanegae T, Wada M, Takano M (2000) Rice NPH1 homologues, OsNPH1a and OsNPH1b, are differently photoregulated. Plant Cell Physiol 41:415–423
Kasahara M, Kagawa T, Sato Y, Kiyosue T, Wada M (2004) Phototropins mediate blue and red light-induced chloroplast movements in Physcomitrella patens. Plant Physiol 135:1388–1397
Kay SK, Keith B, Shinozaki B, Chua NH (1989) The sequence of the rice phytochrome gene. Nucleic Acid Res 17:2865–2866
Kinoshita T, Doi M, Suetsugu N, Kagawa T, Wada M, Shimazaki K (2001) Phot1 and phot2 mediate blue light regulation of stomatal opening. Nature 414:656–660
Kinoshita T, Emi T, Tominaga M, Sakamoto K, Shigenaga A, Doi M, Shimazaki K (2003) Blue-light and phosphorylation-dependent binding of a 14-3-3 protein to phototropins in stomatal guard cells of broad bean. Plant Physiol 133:1453–1463
Kleine T, Lockhart P, Batschauer A (2003) An Arabidopsis protein closely related to Synechocystis cryptochrome is targeted to organelles. Plant J 35:93–103
Kulshreshtha R, Khurana JP (2006) Nucleotide sequence and characterization of a gene encoding phytochrome A1 from wheat (Triticum aestivum). http://www.ncbi.nlm.nih.gov/protein/CAC85512
Li J, Lib G, Wang H, Deng XW (2011) Phytochrome signaling mechanisms. Arabidopsis Book 9:e0148
Li L, Ljung K, Breton G, Schmitz RJ, Pruneda-Paz J, Cowing-Zitron C, Cole BJ, Ivans LJ, Pedmale UV, Jung H-S, Ecker JR, Kay SA, Chory J (2012) Linking photoreceptor excitation to changes in plant architecture. Genes Dev 26:785–790
Lifschitz E, Eviatar T, Rozman A, Shalit A, Goldshmidt A, Amsellem Z, Alvarez JP, Eshed Y (2006) The tomato FT ortholog triggers systemic signals that regulate growth and flowering and substitute for diverse environmental stimuli. Proc Nat Acad Sci USA 103:6398–6403
Liu YS, Gur A, Ronen G, Causse M, Damidaux R, Buret M, Hirschberg J, Zamir D (2003) There is more to tomato fruit colour than candidate carotenoid genes. Plant Biotechnol J 1:195–207
Liu Y, Roof S, Ye Z, Barry C, van Tuinen A, Vrebalov J, Bowler C, Giovannoni J (2004) Manipulation of light signal transduction as a means of modifying fruit nutritional quality in tomato. Proc Nat Acad Sci USA 101:9897–9902
Lopez L, Carbone F, Bianco L, Giuliano G, Facella P, Perrotta G (2012) Tomato plants overexpressing cryptochrome 2 reveal altered expression of energy and stress-related gene products in response to diurnal cues. Plant, Cell Environ 35:994–1012
Lou P, Wu J, Cheng F, Cressman LG, Wang X, McClung CR (2012) Preferential retention of circadian clock genes during diploidization following whole genome triplication in Brassica rapa. Plant Cell 24:2415–2426
Markelz NH, Costich DE, Brutnell TP (2003) Photomorphogenic responses in maize seedling development. Plant Physiol 133:1578–1591
Mathews S, Tsai RC, Kellogg EA (2000) Phylogenetic structure in the grass family (Poaceae): evidence from the nuclear gene phytochrome B. Am J Bot 87:96–107
Mockler T, Yang H, Yu X, Parikh D, Cheng YC, Dolan S, Lin C (2003) Regulation of photoperiodic flowering by Arabidopsis photoreceptors. Proc Nat Acad Sci USA 100:2140–2145
Perrotta G, Ninu L, Flamma F, Weller J, Kendrick R, Nebuloso E, Giuliano G (2000) Tomato contains homologues of Arabidopsis cryptochromes 1 and 2. Plant Mol Biol 42:765–773
Perrotta G, Yahoubyan G, Nebuloso E, Renzi L, Giuliano G (2001) Tomato and barley contain duplicated copies of cryptochrome 1. Plant, Cell Environ 24:991–998
Platten JD, Foo E, Foucher F, Hecht Vr, Reid J, Weller J (2005) The cryptochrome gene family in pea includes two differentially expressed CRY2 genes. Plant Mol Biol 59:683–696
Rizzini L, Favory JJ, Cloix C, Faggionato D, O'Hara A, Kaiserli E, Baumeister R, Schäfer E, Nagy F, Jenkins GI, Ulm R (2011) Perception of UV-B by the Arabidopsis UVR8 protein. Science 332:103–106
Robson PRH, Smith H (1997) Fundamental and biotechnological applications of phytochrome transgenes. Plant, Cell Environ 20:831–839
Robson PR, McCormac AC, Irvine AS, Smith H (1996) Genetic engineering of harvest index in tobacco through overexpression of a phytochrome gene. Nat Biotechnol 14:995–998
Sasaki T, Matsumoto T, Katayose Y (2008) Oryza sativa nipponbare (GA3) genomic DNA, chromosome 2, BAC clone:B1215B07. http://www.ncbi.nlm.nih.gov/protein/BAD23780
Schnable PS, Ware D, Fulton RS, Stein JC, Wei F, Pasternak S, Liang C, Zhang J, Fulton L, Graves TA, Minx P, Reily AD, Courtney L, Kruchowski SS, Tomlinson C, Strong C, Delehaunty K, Fronick C, Courtney B, et al. (2009) The B73 maize genome: complexity, diversity, and dynamics. Science 326:1112–1115
Sharma S, Sharma R (2007) Phototropin-1 cDNA isolation using RACE PCR amplification. http://www.ncbi.nlm.nih.gov/nuccore/EF063359
Sharma R, Lopez-Juez E, Nagatani A, Furuya M (1993) Identification of photo-inactive phytochrome A in etiolated seedlings and photo-active phytochrome B in green leaves of the Aurea mutant of tomato. Plant J 4:1035–1042
Sheehan MJ, Farmer PR, Brutnell TP (2004) Structure and expression of maize phytochrome family homeologs. Genetics 167:1395–1405
Smith H (1995) Physiological and ecological function within the phytochrome family. Annu Rev Plant Physiol Plant Mol Biol 46:289–315
Smith H, Whitelam GC (1997) The shade avoidance syndrome: multiple responses mediated by multiple phytochromes. Plant, Cell Environ 20:840–844
Srinivas A, Behera RK, Kagawa T, Wada M, Sharma R (2004) High pigment1 mutation negatively regulates phototropic signal transduction in tomato seedlings. Plant Physiol 134:790–800
Steindler C, Matteucci A, Sessa G, Weimar T, Ohgishi M, Aoyama T, Morelli G, Ruberti I (1999) Shade avoidance responses are mediated by the ATHB-2 HD-zip protein, a negative regulator of gene expression. Development 126:4235–4245
Szücs P, Karsai I, Zitzewitz J, Mészáros K, Cooper LLD, Gu YQ, Chen THH, Hayes PM, Skinner JS (2006) Positional relationships between photoperiod response QTL and photoreceptor and vernalization genes in barley. Theor Appl Genet 112:1277–1285
Tadmor Y, Fridman E, Gur A, Larkov O, Lastochkin E, Ravid U, Zamir D, Lewinsohn E (2002) Identification of malodorous, a wild species allele affecting tomato aroma that was aelected against during domestication. J Agric Food Chem 50:2005–2009
Takase T, Nishiyama Y, Tanihigashi H, Ogura Y, Miyazaki Y, Yamada Y, Kiyosue T (2011) LOV KELCH PROTEIN2 and ZEITLUPE repress Arabidopsis photoperiodic flowering under non-inductive conditions, dependent on FLAVIN-BINDING KELCH REPEAT F-BOX1. Plant J 67:608–621
Takemiya A, Inoue S-i, Doi M, Kinoshita T, Shimazaki K-i (2005) Phototropins promote plant growth in response to blue light in low light environments. Plant Cell 17:1120–1127
Tieman DM, Zeigler M, Schmelz EA, Taylor MG, Bliss P, Kirst M, Klee HJ (2006) Identification of loci affecting flavour volatile emissions in tomato fruits. J Exp Bot 57:887–896
Wada M, Kagawa T, Sato Y (2003) Chloroplast movement. Annu Rev Plant Biol 54:455–468
Watanabe S, Hideshima R, Xia Z, Tsubokura Y, Sato S, Nakamoto Y, Yamanaka N, Takahashi R, Ishimoto M, Anai T, Tabata S, Harada K (2009) Map-based cloning of the gene associated with the soybean maturity locus E3. Genetics 182:1251–1262
Weller JL, Beauchamp N, Kerckhoffs LHJ, Platten JD, Reid JB (2001) Interaction of phytochromes A and B in the control of de-etiolation and flowering in pea. Plant J 26:283–294
Weller JL, Batge SL, Smith JJ, Kerckhoffs LHJ, Sineshchekov VA, Murfet IC, Reid JB (2004) A dominant mutation in the pea PHYA gene confers enhanced responses to light and impairs the light-dependent degradation of phytochrome A. Plant Physiol 135:2186–2195
White GM, Hamblin MT, Kresovich S (2004) Molecular evolution of the phytochrome gene family in sorghum: changing rates of synonymous and replacement evolution. Mol Biol Evol 21:716–723
Xie X, Chen Z, Wang X (2004) Cloning and sequence analysis of sorghum cryptochrome 2 genomic DNA. http://www.ncbi.nlm.nih.gov/protein/AAV97867
Xu P, Xiang Y, Zhu H, Xu H, Zhang Z, Zhang C, Zhang L, Ma Z (2009) Wheat cryptochromes: subcellular localization and involvement in photomorphogenesis and osmotic stress responses. Plant Physiol 149:760–774
Yanovsky MJ, Kay SA (2002) Molecular basis of seasonal time measurement in Arabidopsis. Nature 419:308–312
Yon F, Seo P-J, Ryu JY, Park C-M, Baldwin IT, Kim S-G (2012) Identification and characterization of circadian clock genes in a native tobacco, Nicotiana attenuate. BMC Plant Biol 12:172
Yu K, Niu X, Wang S (2006) Acquiring full length cDNA of tomato phototropin-2 by utilizing RACE PCR technology and construction of its overexpression vector. http://www.ncbi.nlm.nih.gov/nuccore/DQ886531
Yu X, Liu H, Klejnot J, Lin C (2010) The cryptochrome blue light receptors. Arabidopsis Book 8:e0135
Zacherl M, Huala E, Rudiger W, Briggs WR, Salomon M (1998) Isolation and characterization of cDNAs from oat encoding a serine/threonine kinase: an early component in signal transduction for phototropism (Accession Nos. AF033096 and AF033097). Plant Physiol 116:869
Zacherl M, Huala E, Ruediger W, Briggs WR, Salomon M (1997). http://www.ncbi.nlm.nih.gov/protein/AAC05083
Zhang Y, Yang Q (2005) The potato phyA gene. http://www.ncbi.nlm.nih.gov/protein/ABA46868
Zhang Q, Li H, Li R, Hu R, Fan C, Chen F, Wang Z, Liu X, Fu Y, Lin C (2008) Association of the circadian rhythmic expression of GmCRY1a with a latitudinal cline in photoperiodic flowering of soybean. Proc Nat Acad Sci 105:21028–21033
Acknowledgments
Financial support to E.K. from the Science and Engineering Research Board (Department of Science and Technology), New Delhi (Ref. No. SR/FT/LS-82/2011) and Italian National Agency for New Technologies, Energy, and Sustainable Development, Rome is acknowledged. Facilities provided by Prof. Giuliano Giovanni at Cassacia Research Centre, Italy to E.K. is greatly appreciated. The authors thank Soyaphi L.A.; Department of Botany, St. Edmund’s College for assisting with the artwork.
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Kharshiing, E., Sinha, S.P. Plant Productivity: Can Photoreceptors Light the Way?. J Plant Growth Regul 34, 206–214 (2015). https://doi.org/10.1007/s00344-014-9454-9
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DOI: https://doi.org/10.1007/s00344-014-9454-9