Abstract
Like in other angiosperms, the development of flowers in Arabidopsis starts right after the floral transition, when the shoot apical meristem (SAM) stops producing leaves and makes flowers instead. On the flanks of the SAM emerge the flower meristems (FM) that will soon differentiate into the four main floral organs, sepals, petals, stamens, and pistil, stereotypically arranged in concentric whorls. Each phase of flower development—floral transition, floral bud initiation, and floral organ development—is under the control of specific gene networks. In this chapter, we describe these different phases and the gene regulatory networks involved, from the floral transition to the floral termination.
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References
Quiroz S et al (2021) Beyond the genetic pathways, flowering regulation complexity in Arabidopsis thaliana. Int J Mol Sci 22:5716
Wigge PA et al (2005) Integration of spatial and temporal information during floral induction in Arabidopsis. Science 309:1056–1059
Jaeger KE, Wigge PA (2007) FT protein acts as a long-range signal in Arabidopsis. Curr Biol 17:1050–1054
Wigge PA, Thomas D (2011) FT, a mobile developmental signal in plants. Curr Biol 21:R374–R378
Denay G, Chahtane H, Tichtinsky G, Parcy F (2017) A flower is born: an update on Arabidopsis floral meristem formation. Curr Opin Plant Biol 35:15–22
Pin PA, Nilsson O (2012) The multifaceted roles of FLOWERING LOCUS T in plant development. Plant Cell Environ 35:1742–1755
Susila H, Nasim Z, Ahn JH (2018) Ambient temperature-responsive mechanisms coordinate regulation of flowering time. Int J Mol Sci 19:3196
Antoniou-Kourounioti RL, Zhao Y, Dean C, Howard M (2021) Feeling every bit of winter – distributed temperature sensitivity in vernalization. Front Plant Sci 12:628726
Jin S, Ahn JH (2021) Regulation of flowering time by ambient temperature: repressing the repressors and activating the activators. New Phytol 230:938–942
Brightbill CM, Sung S (2022) Temperature-mediated regulation of flowering time in Arabidopsis thaliana. aBIOTECH 3:78–84
Michaels SD, Amasino RM (1999) FLOWERING LOCUS C encodes a novel MADS domain protein that acts as a repressor of flowering. Plant Cell 11:949–956
Deng W et al (2011) FLOWERING LOCUS C (FLC) regulates development pathways throughout the life cycle of Arabidopsis. Proc Natl Acad Sci U S A 108:6680–6685
Li M et al (2016) DELLA proteins interact with FLC to repress flowering transition. J Integr Plant Biol 58:642–655
Sung S, Amasino RM (2004) Vernalization in Arabidopsis thaliana is mediated by the PHD finger protein VIN3. Nature 427:159–164
Whittaker C, Dean C (2017) The FLC locus: a platform for discoveries in epigenetics and adaptation. Annu Rev Cell Dev Biol 33:555–575
Hepworth J, Dean C (2015) Flowering locus C’s lessons: conserved chromatin switches underpinning developmental timing and adaptation. Plant Physiol 168:1237–1245
Swiezewski S, Liu F, Magusin A, Dean C (2009) Cold-induced silencing by long antisense transcripts of an Arabidopsis Polycomb target. Nature 462:799–802
Heo JB, Sung S (2011) Vernalization-mediated epigenetic silencing by a long intronic noncoding RNA. Science 331:76–79
Srikanth A, Schmid M (2011) Regulation of flowering time: all roads lead to Rome. Cell Mol Life Sci 68:2013–2037
Andres F, Coupland G (2012) The genetic basis of flowering responses to seasonal cues. Nat Rev Genet 13:627–639
Marquardt S et al (2014) Functional consequences of splicing of the antisense transcript COOLAIR on FLC transcription. Mol Cell 54:156–165
Susila H et al (2021) Florigen sequestration in cellular membranes modulates temperature-responsive flowering. Science 373:1137–1142
Jaillais Y, Parcy F (2021) Lipid-mediated regulation of flowering time. Science 373:1086–1087
Lee JH et al (2007) Role of SVP in the control of flowering time by ambient temperature in Arabidopsis. Genes Dev 21:397–402
Li D et al (2008) A repressor complex governs the integration of flowering signals in Arabidopsis. Dev Cell 15:110–120
Melzer R (2017) Regulation of flowering time: a splicy business. J Exp Bot 68:5017–5020
Pose D et al (2013) Temperature-dependent regulation of flowering by antagonistic FLM variants. Nature 503:414–417
Capovilla G, Symeonidi E, Wu R, Schmid M (2017) Contribution of major FLM isoforms to temperature-dependent flowering in Arabidopsis thaliana. J Exp Bot 68:5117–5127
Jin S et al (2022) FLOWERING LOCUS M isoforms differentially affect the subcellular localization and stability of SHORT VEGETATIVE PHASE to regulate temperature-responsive flowering in Arabidopsis. Mol Plant 15:1696–1709
Lee JH et al (2013) Regulation of temperature-responsive flowering by MADS-box transcription factor repressors. Science 342:628–632
Kumar SV et al (2012) Transcription factor PIF4 controls the thermosensory activation of flowering. Nature 484:242–245
Sakamoto T, Kimura S (2018) Plant temperature sensors. Sensors 18:4365
Han X et al (2019) Arabidopsis transcription factor TCP5 controls plant thermomorphogenesis by positively regulating PIF4 activity. iScience 15:611–622
Tasset C et al (2018) POWERDRESS-mediated histone deacetylation is essential for thermomorphogenesis in Arabidopsis thaliana. PLoS Genet 14:e1007280
Reed JW et al (2000) Independent action of ELF3 and phyB to control hypocotyl elongation and flowering time. Plant Physiol 122:1149–1160
Song YH et al (2018) Molecular basis of flowering under natural long-day conditions in Arabidopsis. Nat Plants 4:824–835
Box MS et al (2015) ELF3 controls thermoresponsive growth in Arabidopsis. Curr Biol 25:194–199
Ezer D et al (2017) The evening complex coordinates environmental and endogenous signals in Arabidopsis. Nat Plants 3:17087
Silva CS et al (2020) Molecular mechanisms of evening complex activity in Arabidopsis. Proc Natl Acad Sci U S A 117:6901–6909
Jung J-H et al (2020) A prion-like domain in ELF3 functions as a thermosensor in Arabidopsis. Nature 585:256–260
Shim JS, Kubota A, Imaizumi T (2017) Circadian clock and photoperiodic flowering in Arabidopsis: CONSTANS is a hub for signal integration. Plant Physiol 173:5–15
Valverde F et al (2004) Photoreceptor regulation of CONSTANS protein in photoperiodic flowering. Science 303:1003–1006
Jang S et al (2008) Arabidopsis COP1 shapes the temporal pattern of CO accumulation conferring a photoperiodic flowering response. EMBO J 27:1277–1288
Song YH, Ito S, Imaizumi T (2013) Flowering time regulation: photoperiod- and temperature-sensing in leaves. Trends Plant Sci 18:575–583
Yu J-W et al (2008) COP1 and ELF3 control circadian function and photoperiodic flowering by regulating GI stability. Mol Cell 32:617–630
Yin R, Ulm R (2017) How plants cope with UV-B: from perception to response. Curr Opin Plant Biol 37:42–48
Arongaus AB et al (2018) Arabidopsis RUP2 represses UVR8-mediated flowering in noninductive photoperiods. Genes Dev 32:1332–1343
Lunn JE et al (2006) Sugar-induced increases in trehalose 6-phosphate are correlated with redox activation of ADPglucose pyrophosphorylase and higher rates of starch synthesis in Arabidopsis thaliana. Biochem J 397:139–148
Gomez LD, Gilday A, Feil R, Lunn JE, Graham IA (2010) AtTPS1-mediated trehalose 6-phosphate synthesis is essential for embryogenic and vegetative growth and responsiveness to ABA in germinating seeds and stomatal guard cells. Plant J 64:1–13
Wahl V et al (2013) Regulation of flowering by trehalose-6-phosphate signaling in Arabidopsis thaliana. Science 339:704–707
Olas JJ et al (2019) Nitrate acts at the Arabidopsis thaliana shoot apical meristem to regulate flowering time. New Phytol 223:814–827
Huijser P, Schmid M (2011) The control of developmental phase transitions in plants. Development 138:4117–4129
Hyun Y, Richter R, Coupland G (2017) Competence to flower: age-controlled sensitivity to environmental cues. Plant Physiol 173:36–46
Xu M et al (2016) Developmental functions of miR156-regulated SQUAMOSA PROMOTER BINDING PROTEIN-LIKE (SPL) genes in Arabidopsis thaliana. PLoS Genet 12:e1006263
Wang J, Czech B, Weigel D (2009) miR156-regulated SPL transcription factors define an endogenous flowering pathway in Arabidopsis thaliana. Cell 138:738–749
Ó’Maoiléidigh DS et al (2021) Systematic analyses of the MIR172 family members of Arabidopsis define their distinct roles in regulation of APETALA2 during floral transition. PLoS Biol 19:e3001043
Zhang B, Wang L, Zeng L, Zhang C, Ma H (2015) Arabidopsis TOE proteins convey a photoperiodic signal to antagonize CONSTANS and regulate flowering time. Genes Dev 29:975–987
Yamaguchi A et al (2009) The microRNA-regulated SBP-Box transcription factor SPL3 is a direct upstream activator of LEAFY, FRUITFULL, and APETALA1. Dev Cell 17:268–278
Zhou C-M et al (2013) Molecular basis of age-dependent vernalization in Cardamine flexuosa. Science 340:1097–1100
Bergonzi S et al (2013) Mechanisms of age-dependent response to winter temperature in perennial flowering of Arabis alpina. Science 340:1094–1097
Collani S, Neumann M, Yant L, Schmid M (2019) FT modulates genome-wide DNA-binding of the bZIP transcription factor FD. Plant Physiol 180:367–380
Lee J, Oh M, Park H, Lee I (2008) SOC1 translocated to the nucleus by interaction with AGL24 directly regulates leafy. Plant J 55:832–843
Kaufmann K et al (2010) Orchestration of floral initiation by APETALA1. Science 328:85–89
Liljegren SJ, Gustafson-Brown C, Pinyopich A, Ditta GS, Yanofsky MF (1999) Interactions among APETALA1, LEAFY, and TERMINAL FLOWER1 specify meristem fate. Plant Cell 11:1007–1018
Abe M et al (2019) Transient activity of the florigen complex during the floral transition in Arabidopsis thaliana. Development 146:dev171504
Wang Y, Jiao Y (2018) Auxin and above-ground meristems. J Exp Bot 69:147–154
Okada K, Ueda J, Komaki MK, Bell CJ, Shimura Y (1991) Requirement of the auxin polar transport system in early stages of Arabidopsis floral bud formation. Plant Cell 3:677–684
Bennett SRM, Alvarez J, Bossinger G, Smyth DR (1995) Morphogenesis in pinoid mutants of Arabidopsis thaliana. Plant J 8:505–520
Reinhardt D, Mandel T, Kuhlemeier C (2000) Auxin regulates the initiation and radial position of plant lateral organs. Plant Cell 12:507–518
Reinhardt D et al (2003) Regulation of phyllotaxis by polar auxin transport. Nature 426:255–260
Jonsson H, Heisler MG, Shapiro BE, Meyerowitz EM, Mjolsness E (2006) An auxin-driven polarized transport model for phyllotaxis. Proc Natl Acad Sci U S A 103:1633–1638
Smith RS et al (2006) A plausible model of phyllotaxis. Proc Natl Acad Sci U S A 103:1301–1306
Truskina J, Vernoux T (2018) The growth of a stable stationary structure: coordinating cell behavior and patterning at the shoot apical meristem. Curr Opin Plant Biol 41:83–88
Besnard F et al (2014) Cytokinin signalling inhibitory fields provide robustness to phyllotaxis. Nature 505:417–421
Zhao Y (2018) Essential roles of local auxin biosynthesis in plant development and in adaptation to environmental changes. Annu Rev Plant Biol 69:417–435
Cheng Y, Dai X, Zhao Y (2006) Auxin biosynthesis by the YUCCA flavin monooxygenases controls the formation of floral organs and vascular tissues in Arabidopsis. Genes Dev 20:1790–1799
Petrasek J, Friml J (2009) Auxin transport routes in plant development. Development 136:2675–2688
Benkova E et al (2003) Local, efflux-dependent auxin gradients as a common module for plant organ formation. Cell 115:591–602
Christensen SK, Dagenais N, Chory J, Weigel D (2000) Regulation of auxin response by the protein kinase PINOID. Cell 100:469–478
Michniewicz M et al (2007) Antagonistic regulation of PIN phosphorylation by PP2A and PINOID directs auxin flux. Cell 130:1044–1056
Zourelidou M et al (2014) Auxin efflux by PIN-FORMED proteins is activated by two different protein kinases, D6 PROTEIN KINASE and PINOID. Elife 3:e02860
Furutani M, Nakano Y, Tasaka M (2014) MAB4-induced auxin sink generates local auxin gradients in Arabidopsis organ formation. Proc Natl Acad Sci U S A 111:1198–1203
Leyser O (2018) Auxin signaling. Plant Physiol 176:465–479
Przemeck GK, Mattsson J, Hardtke CS, Sung ZR, Berleth T (1996) Studies on the role of the Arabidopsis gene MONOPTEROS in vascular development and plant cell axialization. Planta 200:229–237
Cole M et al (2009) DORNROSCHEN is a direct target of the auxin response factor MONOPTEROS in the Arabidopsis embryo. Development 136:1643–1651
Bhatia N et al (2016) Auxin acts through MONOPTEROS to regulate plant cell polarity and pattern phyllotaxis. Curr Biol 26:3202–3208
Yamaguchi N et al (2013) A molecular framework for auxin-mediated initiation of flower primordia. Dev Cell 24:271–282
Blazquez MA, Soowal LN, Lee I, Weigel D (1997) LEAFY expression and flower initiation in Arabidopsis. Development 124:3835–3844
Krizek B (2009) AINTEGUMENTA and AINTEGUMENTA-LIKE6 act redundantly to regulate Arabidopsis floral growth and patterning. Plant Physiol 150:1916–1929
Long J, Barton MK (2000) Initiation of axillary and floral meristems in Arabidopsis. Dev Biol 218:341–353
Wu MF et al (2015) Auxin-regulated chromatin switch directs acquisition of flower primordium founder fate. Elife 4:e09269
Krizek BA (2011) Aintegumenta and Aintegumenta-Like6 regulate auxin-mediated flower development in Arabidopsis. BMC Res Notes 4:176
Ezhova TA, Soldatova OP, Kalinina AI, Medvedev SS (2000) Interaction of ABRUPTUS/PINOID and LEAFY genes during floral morphogenesis in Arabidopsis thaliana (L) Heynh. Genetika 36:1682–1687
Yamaguchi N, Wu M-F, Winter CM, Wagner D (2014) LEAFY and polar auxin transport coordinately regulate Arabidopsis flower development. Plants 3:251–265
Yamaguchi N, Jeong CW, Nole-Wilson S, Krizek BA, Wagner D (2016) AINTEGUMENTA and AINTEGUMENTA-LIKE6/PLETHORA3 induce LEAFY expression in response to auxin to promote the onset of flower formation in Arabidopsis. Plant Physiol 170:283–293
Krizek BA, Blakley IC, Ho Y-Y, Freese N, Loraine AE (2020) The Arabidopsis transcription factor AINTEGUMENTA orchestrates patterning genes and auxin signaling in the establishment of floral growth and form. Plant J 103:752–768
Stigliani A et al (2019) Capturing auxin response factors syntax using DNA binding models. Mol Plant 12:822–832
Talbert PB, Adler HT, Parks DW, Comai L (1995) The REVOLUTA gene is necessary for apical meristem development and for limiting cell divisions in the leaves and stems of Arabidopsis thaliana. Development 121:2723–2735
Chen Q et al (1999) The Arabidopsis FILAMENTOUS FLOWER gene is required for flower formation. Development 126:2715–2726
Sawa S et al (1999) FILAMENTOUS FLOWER, a meristem and organ identity gene of Arabidopsis, encodes a protein with a zinc finger and HMG-related domains. Genes Dev 13:1079–1088
Otsuga D, DeGuzman B, Prigge MJ, Drews GN, Clark SE (2001) REVOLUTA regulates meristem initiation at lateral positions. Plant J 25:223–236
Ram H et al (2020) An integrated analysis of cell-type specific gene expression reveals genes regulated by REVOLUTA and KANADI1 in the Arabidopsis shoot apical meristem. PLoS Genet 16:e1008661
Greb T et al (2003) Molecular analysis of the LATERAL SUPPRESSOR gene in Arabidopsis reveals a conserved control mechanism for axillary meristem formation. Genes Dev 17:1175–1187
Aida M, Ishida T, Fukaki H, Fujisawa H, Tasaka M (1997) Genes involved in organ separation in Arabidopsis: an analysis of the cup-shaped cotyledon mutant. Plant Cell 9:841–857
Hibara K et al (2006) Arabidopsis CUP-SHAPED COTYLEDON3 regulates postembryonic shoot meristem and organ boundary formation. Plant Cell 18:2946–2957
Keller T, Abbott J, Moritz T, Doerner P (2006) Arabidopsis REGULATOR OF AXILLARY MERISTEMS1 controls a leaf axil stem cell niche and modulates vegetative development. Plant Cell 18:598–611
Muller D, Schmitz G, Theres K (2006) Blind homologous R2R3 Myb genes control the pattern of lateral meristem initiation in Arabidopsis. Plant Cell 18:586–597
Chahtane H et al (2013) A variant of LEAFY reveals its capacity to stimulate meristem development by inducing RAX1. Plant J 74:678–689
Chung Y et al (2019) Auxin response factors promote organogenesis by chromatin-mediated repression of the pluripotency gene SHOOTMERISTEMLESS. Nat Commun 10:886
Brand U, Fletcher JC, Hobe M, Meyerowitz EM, Simon R (2000) Dependence of stem cell fate in Arabidopsis on a feedback loop regulated by CLV3 activity. Science 289:617–619
Yadav RK et al (2011) WUSCHEL protein movement mediates stem cell homeostasis in the Arabidopsis shoot apex. Genes Dev 25:2025–2030
Gruel J, Deichmann J, Landrein B, Hitchcock T, Jonsson H (2018) The interaction of transcription factors controls the spatial layout of plant aerial stem cell niches. NPJ Syst Biol Appl 4:36
Krizek BA et al (2016) RNA-Seq links the transcription factors AINTEGUMENTA and AINTEGUMENTA-LIKE6 to cell wall remodeling and plant defense pathways. Plant Physiol 171:2069–2084
Yang W et al (2016) Regulation of meristem morphogenesis by cell wall synthases in Arabidopsis. Curr Biol 26:1404–1415
Sampathkumar A et al (2019) Primary wall cellulose synthase regulates shoot apical meristem mechanics and growth. Development 146:dev179036
Traas J (2018) Organogenesis at the shoot apical meristem. Plants (Basel) 8(1):6
Sassi M et al (2014) An auxin-mediated shift toward growth isotropy promotes organ formation at the shoot meristem in Arabidopsis. Curr Biol 24:2335–2342
Landrein B et al (2015) Mechanical stress contributes to the expression of the STM homeobox gene in Arabidopsis shoot meristems. Elife 4:e07811
Huala E, Sussex IM (1992) LEAFY interacts with floral homeotic genes to regulate Arabidopsis floral development. Plant Cell 4:901–913
Pinyopich A et al (2003) Assessing the redundancy of MADS-box genes during carpel and ovule development. Nature 424:85–88
Parcy F, Nilsson O, Busch MA, Lee I, Weigel D (1998) A genetic framework for floral patterning. Nature 395:561–566
Wagner D, Sablowski RW, Meyerowitz EM (1999) Transcriptional activation of APETALA1 by LEAFY. Science 285:582–584
Pastore JJ et al (2011) LATE MERISTEM IDENTITY2 acts together with LEAFY to activate APETALA1. Development 138:3189–3198
Yamaguchi N et al (2014) Gibberellin acts positively then negatively to control onset of flower formation in Arabidopsis. Science 344:638–641
Chandler JW, Werr W (2017) DORNROSCHEN, DORNROSCHEN-LIKE, and PUCHI redundantly control floral meristem identity and organ initiation in Arabidopsis. J Exp Bot 68:3457–3472
Zhang B et al (2017) BLADE-ON-PETIOLE proteins act in an E3 ubiquitin ligase complex to regulate PHYTOCHROME INTERACTING FACTOR 4 abundance. Elife 6:e26759
Chahtane H et al (2018) LEAFY activity is post-transcriptionally regulated by BLADE ON PETIOLE2 and CULLIN3 in Arabidopsis. New Phytol 220:579–592
Ahn JH et al (2006) A divergent external loop confers antagonistic activity on floral regulators FT and TFL1. EMBO J 25:605–614
Ho WWH, Weigel D (2014) Structural features determining flower-promoting activity of Arabidopsis FLOWERING LOCUS T. Plant Cell 26:552–564
Périlleux C, Bouché F, Randoux M, Orman-ligeza B (2019) Turning meristems into fortresses. Trends Plant Sci 24:431–442
Hanano S, Goto K (2011) Arabidopsis TERMINAL FLOWER1 is involved in the regulation of flowering time and inflorescence development through transcriptional repression. Plant Cell 23:3172–3184
Goretti D et al (2020) TERMINAL FLOWER1 functions as a mobile transcriptional cofactor in the shoot apical meristem. Plant Physiol 182:2081–2095
Zhu Y et al (2020) TERMINAL FLOWER 1-FD complex target genes and competition with FLOWERING LOCUS T. Nat Commun 11:5118
Liu C et al (2007) Specification of Arabidopsis floral meristem identity by repression of flowering time genes. Development 134:1901–1910
Parcy F, Bomblies K, Weigel D (2002) Interaction of LEAFY, AGAMOUS and TERMINAL FLOWER1 in maintaining floral meristem identity in Arabidopsis. Development 129:2519–2527
Goslin K et al (2017) Transcription factor interplay between LEAFY and APETALA1/CAULIFLOWER during floral initiation. Plant Physiol 174:1097–1109
Serrano-Mislata A et al (2017) Regulatory interplay between LEAFY, APETALA1/CAULIFLOWER and TERMINAL FLOWER1: new insights into an old relationship. Plant Signal Behav 12:e1370164
Thomson B, Wellmer F (2019) Molecular regulation of flower development. In: Grossniklaus U (ed) Plant development and evolution, Current topics in developmental biology, vol 131. Elsevier, Amsterdam, pp 185–210
Azpeitia E et al (2021) Cauliflower fractal forms arise from perturbations of floral gene networks. Science 373:192–197
Winter CM, Yamaguchi N, Wu M, Wagner D (2015) Transcriptional programs regulated by both LEAFY and APETALA1 at the time of flower formation. Physiol Plant 155:55–73
Yan W, Chen D, Kaufmann K (2016) Molecular mechanisms of floral organ specification by MADS domain proteins. Curr Opin Plant Biol 29:154–162
Moyroud E et al (2011) Prediction of regulatory interactions from genome sequences using a biophysical model for the Arabidopsis LEAFY transcription factor. Plant Cell 23:1293–1306
Winter CM et al (2011) LEAFY target genes reveal floral regulatory logic, cis motifs, and a link to biotic stimulus response. Dev Cell 20:430–443
Pajoro A et al (2014) Dynamics of chromatin accessibility and gene regulation by MADS-domain transcription factors in flower development. Genome Biol 15:R41
Sayou C et al (2016) A SAM oligomerization domain shapes the genomic binding landscape of the LEAFY transcription factor. Nat Commun 7:11222
Lai X, Verhage L, Hugouvieux V, Zubieta C (2018) Pioneer factors in animals and plants-colonizing chromatin for gene regulation. Molecules 23:1914
Jin R et al (2021) LEAFY is a pioneer transcription factor and licenses cell reprogramming to floral fate. Nat Commun 12:626
Lai X et al (2021) The LEAFY floral regulator displays pioneer transcription factor properties. Mol Plant 14:829–837
Wu M-F et al (2012) SWI2/SNF2 chromatin remodeling ATPases overcome polycomb repression and control floral organ identity with the LEAFY and SEPALLATA3 transcription factors. Proc Natl Acad Sci U S A 109:3576–3581
Smaczniak C et al (2012) Characterization of MADS-domain transcription factor complexes in Arabidopsis flower development. Proc Natl Acad Sci U S A 109:1560–1565
Liu C, Xi W, Shen L, Tan C, Yu H (2009) Regulation of floral patterning by flowering time genes. Dev Cell 16:711–722
Chen D, Yan W, Fu L-Y, Kaufmann K (2018) Architecture of gene regulatory networks controlling flower development in Arabidopsis thaliana. Nat Commun 9:4534
Breuil-Broyer S et al (2004) High-resolution boundary analysis during Arabidopsis thaliana flower development. Plant J 38:182–192
Smith HMS, Campbell BC, Hake S (2004) Competence to respond to floral inductive signals requires the homeobox genes PENNYWISE and POUND-FOOLISH. Curr Biol 14:812–817
Ung N, Lal S, Smith HMS (2011) The role of PENNYWISE and POUND-FOOLISH in the maintenance of the shoot apical meristem in Arabidopsis. Plant Physiol 156:605–614
Hamant O, Pautot V (2010) Plant development: a TALE story. C R Biol 333:371–381
Aida M, Tasaka M (2006) Genetic control of shoot organ boundaries. Curr Opin Plant Biol 9:72–77
Yu H, Huang T (2016) Molecular mechanisms of floral boundary formation in Arabidopsis. Int J Mol Sci 17:317
Spinelli SV, Martin AP, Viola IL, Gonzalez DH, Palatnik JF (2011) A mechanistic link between STM and CUC1 during Arabidopsis development. Plant Physiol 156:1894–1904
Xu M et al (2010) Arabidopsis BLADE-ON-PETIOLE1 and 2 promote floral meristem fate and determinacy in a previously undefined pathway targeting APETALA1 and AGAMOUS-LIKE24. Plant J 63:974–989
Khan M et al (2015) Repression of lateral organ boundary genes by PENNYWISE and POUND-FOOLISH is essential for meristem maintenance and flowering in Arabidopsis. Plant Physiol 169:2166–2186
Wang Y et al (2019) Clade I TGACG-motif binding basic leucine zipper transcription factors mediate BLADE-ON-PETIOLE-dependent regulation of development. Plant Physiol 180:937–951
Khan M et al (2012) Antagonistic interaction of BLADE-ON-PETIOLE1 and 2 with BREVIPEDICELLUS and PENNYWISE regulates Arabidopsis inflorescence architecture. Plant Physiol 158:946–960
Khan M, Tabb P, Hepworth SR (2012) BLADE-ON-PETIOLE1 and 2 regulate Arabidopsis inflorescence architecture in conjunction with homeobox genes KNAT6 and ATH1. Plant Signal Behav 7:788–792
Zhao Y et al (2004) HANABA TARANU is a GATA transcription factor that regulates shoot apical meristem and flower development in Arabidopsis. Plant Cell 16:2586–2600
Ding L et al (2015) HANABA TARANU (HAN) bridges meristem and organ primordia boundaries through PINHEAD, JAGGED, BLADE-ON-PETIOLE2 and CYTOKININ OXIDASE 3 during flower development in Arabidopsis. PLoS Genet 11:e1005479
Ji L et al (2011) ARGONAUTE10 and ARGONAUTE1 regulate the termination of floral stem cells through two microRNAs in Arabidopsis. PLoS Genet 7:e1001358
Jasinski S et al (2005) KNOX action in Arabidopsis is mediated by coordinate regulation of cytokinin and gibberellin activities. Curr Biol 15:1560–1565
Cucinotta M et al (2018) CUP-SHAPED COTYLEDON1 (CUC1) and CUC2 regulate cytokinin homeostasis to determine ovule number in Arabidopsis. J Exp Bot 69:5169–5176
Pelaz S, Ditta GS, Baumann E, Wisman E, Yanofsky MF (2000) B and C floral organ identity functions require SEPALLATA MADS-box genes. Nature 405:200–203
Lohmann JU et al (2001) A molecular link between stem cell regulation and floral patterning in Arabidopsis. Cell 105:793–803
Rieu P et al (2022) The F-box cofactor UFO redirects the LEAFY floral regulator to novel cis-elements. bioRxiv. https://doi.org/10.1101/20220614495942
Theissen G, Melzer R, Rumpler F (2016) MADS-domain transcription factors and the floral quartet model of flower development: linking plant development and evolution. Development 143:3259–3271
Puranik S et al (2014) Structural basis for the oligomerization of the MADS domain transcription factor SEPALLATA3 in Arabidopsis. Plant Cell 26:3603–3615
Hugouvieux V, Zubieta C (2018) MADS transcription factors cooperate: complexities of complex formation. J Exp Bot 69:1821–1823
Hugouvieux V et al (2018) Tetramerization of MADS family transcription factors SEPALLATA3 and AGAMOUS is required for floral meristem determinacy in Arabidopsis. Nucleic Acids Res 46:4966–4977
Lai X et al (2020) Genome-wide binding of SEPALLATA3 and AGAMOUS complexes determined by sequential DNA-affinity purification sequencing. Nucleic Acids Res 48:9637–9648
Lai X et al (2021) The intervening domain is required for DNA-binding and functional identity of plant MADS transcription factors. Nat Commun 12:4760
Prunet N, Jack TP (2014) Flower development in Arabidopsis: there is more to it than learning your ABCs. Methods Mol Biol 1110:3–33
Kramer EM (2019) Plus ca change, plus c’est la meme chose: the developmental evolution of flowers. Curr Top Dev Biol 131:211–238
Bowman JL, Smyth DR, Meyerowitz EM (1989) Genes directing flower development in Arabidopsis. Plant Cell 1:37–52
Irish VF, Sussex IM (1990) Function of the apetala-1 gene during Arabidopsis floral development. Plant Cell 2:741–753
Morel P et al (2017) Divergence of the floral A-function between an asterid and a rosid species. Plant Cell 29:1605–1621
Monniaux M, Vandenbussche M (2018) How to evolve a perianth: a review of cadastral mechanisms for perianth identity. Front Plant Sci 9:1573
Ditta G, Pinyopich A, Robles P, Pelaz S, Yanofsky MF (2004) The SEP4 gene of Arabidopsis thaliana functions in floral organ and meristem identity. Curr Biol 14:1935–1940
Conner J, Liu Z (2000) LEUNIG, a putative transcriptional corepressor that regulates AGAMOUS expression during flower development. Proc Natl Acad Sci U S A 97:12902–12907
Franks RG, Wang C, Levin JZ, Liu Z (2002) SEUSS, a member of a novel family of plant regulatory proteins, represses floral homeotic gene expression with LEUNIG. Development 129:253–263
Sridhar VV, Surendrarao A, Liu Z (2006) APETALA1 and SEPALLATA3 interact with SEUSS to mediate transcription repression during flower development. Development 133:3159–3166
Bao X, Franks RG, Levin JZ, Liu Z (2004) Repression of AGAMOUS by BELLRINGER in floral and inflorescence meristems. Plant Cell 16:1478–1489
Krogan NT, Hogan K, Long JA (2012) APETALA2 negatively regulates multiple floral organ identity genes in Arabidopsis by recruiting the co-repressor TOPLESS and the histone deacetylase HDA19. Development 139:4180–4190
Chen X (2004) A microRNA as a translational repressor of APETALA2 in Arabidopsis flower development. Science 303:2022–2025
Wollmann H, Mica E, Todesco M, Long JA, Weigel D (2010) On reconciling the interactions between APETALA2, miR172 and AGAMOUS with the ABC model of flower development. Development 137:3633–3642
Roeder AHK, Cunha A, Ohno CK, Meyerowitz EM (2012) Cell cycle regulates cell type in the Arabidopsis sepal. Development 139:4416–4427
Robinson DO et al (2018) Ploidy and size at multiple scales in the Arabidopsis sepal. Plant Cell 30:2308–2329
Hervieux N et al (2016) A mechanical feedback restricts sepal growth and shape in Arabidopsis. Curr Biol 26:1019–1028
Kaufmann K et al (2009) Target genes of the MADS transcription factor SEPALLATA3: integration of developmental and hormonal pathways in the Arabidopsis flower. PLoS Biol 7:e1000090
Yant L et al (2010) Orchestration of the floral transition and floral development in Arabidopsis by the bifunctional transcription factor APETALA2. Plant Cell 22:2156–2170
Honma T, Goto K (2001) Complexes of MADS-box proteins are sufficient to convert leaves into floral organs. Nature 409:525–529
Wuest SE et al (2012) Molecular basis for the specification of floral organs by APETALA3 and PISTILLATA. Proc Natl Acad Sci U S A 109:13452–13457
Bowman JL, Smyth DR (1999) CRABS CLAW, a gene that regulates carpel and nectary development in Arabidopsis, encodes a novel protein with zinc finger and helix-loop-helix domains. Development 126:2387–2396
Sauret-Gueto S, Schiessl K, Bangham A, Sablowski R, Coen E (2013) JAGGED controls Arabidopsis petal growth and shape by interacting with a divergent polarity field. PLoS Biol 11:e1001550
Schiessl K, Muiño JM, Sablowski R (2014) Arabidopsis JAGGED links floral organ patterning to tissue growth by repressing Kip-related cell cycle inhibitors. Proc Natl Acad Sci U S A 111:2830–2835
OMaoileidigh DS et al (2013) Control of reproductive floral organ identity specification in Arabidopsis by the C function regulator AGAMOUS. Plant Cell 25:2482–2503
Norberg M, Holmlund M, Nilsson O (2005) The BLADE ON PETIOLE genes act redundantly to control the growth and development of lateral organs. Development 132:2203–2213
Nag A, King S, Jack T (2009) miR319a targeting of TCP4 is critical for petal growth and development in Arabidopsis. Proc Natl Acad Sci U S A 106:22534–22539
Huang T, Irish VF (2015) Temporal control of plant organ growth by TCP transcription factors. Curr Biol 25:1765–1770
Ito T et al (2004) The homeotic protein AGAMOUS controls microsporogenesis by regulation of SPOROCYTELESS. Nature 430:356–360
Wei B et al (2015) The molecular mechanism of sporocyteless/nozzle in controlling Arabidopsis ovule development. Cell Res 25:121–134
Li X, Lian H, Zhao Q, He Y (2019) microRNA166 monitors SPOROCYTELESS/NOZZLE (SPL/NZZ) for building of the anther internal boundary. Plant Physiol 181:208–220
Zhao F et al (2017) Phosphorylation of SPOROCYTELESS/NOZZLE by the MPK3/6 kinase is required for anther development. Plant Physiol 173:2265–2277
Liu X et al (2009) The SPOROCYTELESS/NOZZLE gene is involved in controlling stamen identity in Arabidopsis. Plant Physiol 151:1401–1411
Kram BW, Carter CJ (2009) Arabidopsis thaliana as a model for functional nectary analysis. Sex Plant Reprod 22:235–246
Alvarez-Buylla ER et al (2010) Flower development. Arabidopsis Book 8:e0127
Lee J-Y et al (2005) Recruitment of CRABS CLAW to promote nectary development within the eudicot clade. Development 132:5021–5032
Baum SF, Eshed Y, Bowman JL (2001) The Arabidopsis nectary is an ABC-independent floral structure. Development 128:4657–4667
Morel P et al (2018) The floral C-lineage genes trigger nectary development in petunia and Arabidopsis. Plant Cell 30:2020–2037
Yanofsky MF et al (1990) The protein encoded by the Arabidopsis homeotic gene agamous resembles transcription factors. Nature 346:35–39
O’Maoileidigh DS, Stewart D, Zheng B, Coupland G, Wellmer F (2018) Floral homeotic proteins modulate the genetic program for leaf development to suppress trichome formation in flowers. Development 145:dev157784
Favaro R et al (2003) MADS-box protein complexes control carpel and ovule development in Arabidopsis. Plant Cell 15:2603–2611
Rodriguez-Cazorla E et al (2015) K-homology nuclear ribonucleoproteins regulate floral organ identity and determinacy in arabidopsis. PLoS Genet 11:e1004983
Rodriguez-Cazorla E et al (2018) Ovule identity mediated by pre-mRNA processing in Arabidopsis. PLoS Genet 14:e1007182
Goncalves B et al (2015) A conserved role for CUP-SHAPED COTYLEDON genes during ovule development. Plant J 83:732–742
Muiño JM, Smaczniak C, Angenent GC, Kaufmann K, van Dijk ADJ (2014) Structural determinants of DNA recognition by plant MADS-domain transcription factors. Nucleic Acids Res 42:2138–2146
Smaczniak C, Muiño JM, Chen D, Angenent GC, Kaufmann K (2017) Differences in DNA binding specificity of floral homeotic protein complexes predict organ-specific target genes. Plant Cell 29:1822–1835
Kappel S, Melzer R, Rumpler F, Gafert C, Theissen G (2018) The floral homeotic protein SEPALLATA3 recognizes target DNA sequences by shape readout involving a conserved arginine residue in the MADS-domain. Plant J 95:341–357
Melzer R, Theissen G (2009) Reconstitution of “floral quartets” in vitro involving class B and class E floral homeotic proteins. Nucleic Acids Res 37:2723–2736
Melzer R, Verelst W, Theissen G (2009) The class E floral homeotic protein SEPALLATA3 is sufficient to loop DNA in ‘floral quartet’-like complexes in vitro. Nucleic Acids Res 37:144–157
Jetha K, Theissen G, Melzer R (2014) Arabidopsis SEPALLATA proteins differ in cooperative DNA-binding during the formation of floral quartet-like complexes. Nucleic Acids Res 42:10927–10942
Takeda S et al (2011) CUP-SHAPED COTYLEDON1 transcription factor activates the expression of LSH4 and LSH3, two members of the ALOG gene family, in shoot organ boundary cells. Plant J 66:1066–1077
Laufs P, Peaucelle A, Morin H, Traas J (2004) MicroRNA regulation of the CUC genes is required for boundary size control in Arabidopsis meristems. Development 131:4311–4322
Mallory AC, Dugas DV, Bartel DP, Bartel B (2004) MicroRNA regulation of NAC-domain targets is required for proper formation and separation of adjacent embryonic, vegetative, and floral organs. Curr Biol 14:1035–1046
Yamaguchi N, Wu M-F, Winter CM, Wagner D (2014) LEAFY and polar auxin transport coordinately regulate Arabidopsis flower development. Plants (Basel) 3:251–265
Griffith ME, da Silva Conceicao A, Smyth DR (1999) PETAL LOSS gene regulates initiation and orientation of second whorl organs in the Arabidopsis flower. Development 126:5635–5644
Brewer PB et al (2004) PETAL LOSS, a trihelix transcription factor gene, regulates perianth architecture in the Arabidopsis flower. Development 131:4035–4045
Lampugnani ER, Kilinc A, Smyth DR (2013) Auxin controls petal initiation in Arabidopsis. Development 140:185–194
Takeda S, Matsumoto N, Okada K (2004) RABBIT EARS, encoding a SUPERMAN-like zinc finger protein, regulates petal development in Arabidopsis thaliana. Development 131:425–434
Krizek BA, Lewis MW, Fletcher JC (2006) RABBIT EARS is a second-whorl repressor of AGAMOUS that maintains spatial boundaries in Arabidopsis flowers. Plant J 45:369–383
Huang T, Lopez-Giraldez F, Townsend JP, Irish VF (2012) RBE controls microRNA164 expression to effect floral organogenesis. Development 139:2161–2169
Levin JZ, Meyerowitz EM (1995) UFO: an Arabidopsis gene involved in both floral meristem and floral organ development. Plant Cell 7:529–548
Levin JZ, Fletcher JC, Chen X, Meyerowitz EM (1998) A genetic screen for modifiers of UFO meristem activity identifies three novel FUSED FLORAL ORGANS genes required for early flower development in Arabidopsis. Genetics 149:579–595
Gonzalez-Carranza ZH et al (2007) Hawaiian skirt: an F-box gene that regulates organ fusion and growth in Arabidopsis. Plant Physiol 144:1370–1382
Gonzalez-Carranza ZH et al (2017) HAWAIIAN SKIRT controls size and floral organ number by modulating CUC1 and CUC2 expression. PLoS One 12:e0185106
Zhang X et al (2017) The Arabidopsis thaliana F-box gene HAWAIIAN SKIRT is a new player in the microRNA pathway. PLoS One 12:e0189788
Sakai H, Medrano LJ, Meyerowitz EM (1995) Role of SUPERMAN in maintaining Arabidopsis floral whorl boundaries. Nature 378:199–203
Bowman JL et al (1992) SUPERMAN, a regulator of floral homeotic genes in Arabidopsis. Development 114:599–615
Prunet N, Yang W, Das P, Meyerowitz EM, Jack TP (2017) SUPERMAN prevents class B gene expression and promotes stem cell termination in the fourth whorl of Arabidopsis thaliana flowers. Proc Natl Acad Sci U S A 114:7166–7171
Xu Y et al (2018) SUPERMAN regulates floral whorl boundaries through control of auxin biosynthesis. EMBO J 37:e97499
Sun B, Ito T (2015) Regulation of floral stem cell termination in Arabidopsis. Front Plant Sci 6:17
Liu X et al (2011) AGAMOUS terminates floral stem cell maintenance in Arabidopsis by directly repressing WUSCHEL through recruitment of Polycomb Group proteins. Plant Cell 23:3654–3670
Sun B, Xu Y, Ng K-H, Ito T (2009) A timing mechanism for stem cell maintenance and differentiation in the Arabidopsis floral meristem. Genes Dev 23:1791–1804
Sun B et al (2019) Integration of transcriptional repression and Polycomb-mediated silencing of WUSCHEL in floral meristems. Plant Cell 31:1488–1505
Bollier N et al (2018) At-MINI ZINC FINGER2 and Sl-INHIBITOR OF MERISTEM ACTIVITY, a conserved missing link in the regulation of floral meristem termination in Arabidopsis and tomato. Plant Cell 30:83–100
Yamaguchi N, Huang J, Xu Y, Tanoi K, Ito T (2017) Fine-tuning of auxin homeostasis governs the transition from floral stem cell maintenance to gynoecium formation. Nat Commun 8:1125
Huang Z et al (2017) APETALA2 antagonizes the transcriptional activity of AGAMOUS in regulating floral stem cells in Arabidopsis thaliana. New Phytol 215:1197–1209
O’Malley RC et al (2016) Cistrome and epicistrome features shape the regulatory DNA landscape. Cell 166:1598
Bartlett A et al (2017) Mapping genome-wide transcription-factor binding sites using DAP-seq. Nat Protoc 12:1659–1672
Neumann M et al (2022) A 3D gene expression atlas of the floral meristem based on spatial reconstruction of single nucleus RNA sequencing data. Nat Commun 13:2838
Xu X, Smaczniak C, Muiño JC, Kaufmann K (2021) Cell identity specification in plants: lessons from flower development. J Exp Bot 72:4202–4217
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Chahtane, H. et al. (2023). Flower Development in Arabidopsis. In: Riechmann, J.L., Ferrándiz, C. (eds) Flower Development . Methods in Molecular Biology, vol 2686. Humana, New York, NY. https://doi.org/10.1007/978-1-0716-3299-4_1
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