1、SnapShot:Control of Flowering in ArabidopsisFabio Fornara,Amaury de Montaigu,and George CouplandMax Planck Institute for Plant Breeding Research,Kln 50829,GermanySee online version for legend and references.550 Cell 141,April 3,2010 2010 Elsevier Inc.DOI 10.1016/j.cell.2010.04.024SnapShot:Control of
2、 Flowering in ArabidopsisFabio Fornara,Amaury de Montaigu,and George CouplandMax Planck Institute for Plant Breeding Research,Kln 50829,Germany550.e1 Cell 141,April 3,2010 2010 Elsevier Inc.DOI 10.1016/j.cell.2010.04.024Plants initiate flowering after a period of vegetative development.During this p
3、rocess,called floral induction,the shoot apical meristem starts to produce flowers instead of leaves.The timing of floral induction is controlled by sophisticated regulatory networks that monitor changes in the environment,ensuring that flowering occurs under conditions most likely to maximize repro
4、ductive success and seed production.In the model plant species Arabidopsis thaliana?180 genes have been implicated in flowering-time control based on isolation of loss-of-function mutations or analysis of transgenic plants.This SnapShot presents a subset of these genes and proteins,each organized ac
5、cording to its spatial activity in the leaves or the shoot apical meristem of the plant.Strikingly,several genes act more than once and in several tissues during floral induction.Many of these genes occur in a network of six major pathways:the photoperiod and vernalization pathways control flowering
6、 in response to seasonal changes in day length and temperature;the ambient temperature pathway responds to daily growth temperatures;and the age,autonomous,and gibberellin pathways act more independently of environmental stimuli.The six pathways converge to regulate a small number of“floral integrat
7、or genes,”encoded by different classes of proteins,which govern flowering time by merging signals from multiple pathways.These integrator genes include FLOWERING LOCUS T(FT)and SUPPRESSOR OF OVEREXPRESSION OF CONSTANS 1(SOC1),which both rapidly promote floral development.In addition,responses to oth
8、er environmental stimuli,such as the balance of different wavelengths of light or nutrient availability,also influence flowering time,but how these processes interact with the pathways described here is not fully understood.All genes that we identified from the literature as being implicated in flow
9、ering-time control are listed at http:/www.mpiz-koeln.mpg.de/english/research/couplandGroup/coupland/floweringgenes/index.html.Vernalization and Autonomous PathwaysFLOWERING LOCUS C(FLC)is a MADS-box transcription factor that acts as a potent repressor of flowering.Its activity differs among varieti
10、es of Arabidopsis and is responsible for much of the variation in flowering time observed among these plants.The vernalization pathway activates flowering by silencing FLC in response to prolonged exposure to low temperatures.In certain varieties of Arabidopsis,cold temperatures trigger antisense tr
11、anscription at the FLC locus,leading to the production of COOLAIR RNA and sub-sequent silencing of FLC transcription.Maintenance of FLC repression,even when plants are returned to warmer temperatures,requires histone modifications at the chromatin of the FLC locus.These modifications involve the PHD
12、 finger protein VERNALIZATION INSENSITIVE 3(VIN3)and a POLYCOMB REPRESSIVE COMPLEX 2(PRC2)that includes VERNALIZATION 2(VRN2).Photoperiod Pathway and the Circadian ClockFlowering of Arabidopsis is promoted by exposure to long summer days and is repressed by short winter days.The photoperiod pathway
13、controls this response and acts in the leaves through a signaling cascade involving GIGANTEA(GI)and the transcriptional regulator CONSTANS(CO).CO promotes flowering by initiating transcription of the FT and TWIN SISTER OF FT(TSF)genes.During long days,light promotes the interaction between GI and a
14、family of F-box ubiquitin ligases,such as the FLAVIN-BINDING KELCH REPEAT F-BOX 1(FKF1)protein.These interactions stabilize the F-box proteins,allowing them to promote the degradation of a set of transcriptional repressors of CO,includ-ing numerous DOF transcription factors called CYCLING DOF FACTOR
15、s(CDFs).CDFs repress flowering by downregulating CO expression in leaves.At the posttranscriptional level,CO is degraded in the dark by the ubiquitin ligase CONSTITUTIVE PHOTOMORPHOGENIC 1(COP1)and in the morning by a pathway activated by the photoreceptor Phytochrome B(PHYB).These layers of transcr
16、iptional and posttranscriptional regulation ensure that CO activates transcription of FT and TSF transcription only during long days.Expression and translation of FT occur in the leaves,and the small FT protein then moves through the phloem to the meristem,where it activates the floral development p
17、rogram.Movement of TSF through the phloem may also occur.The circadian clock is a time-keeping mechanism with a periodicity of 24 hr.The circadian clock confers diurnal patterns of gene expression on?30%of the genes in Arabidopsis.The circadian clock comprises three interlocked feed-back loops.The c
18、entral loop comprises the partially redundant transcription factors CIRCADIAN CLOCK ASSOCIATED 1(CCA1)and LATE ELONGATED HYPOCOTYL(LHY),which repress transcription of TIMING OF CAB 1(TOC1).TOC1 encodes a pseudo-response regulator(PPR)and activates transcription of LHY and CCA1.Similar loops occur in
19、 the morning and evening,which include PRR7/PRR9 and GI,respectively.Many mutations that impair the circadian clock also alter flowering time.For example,the circadian clock ensures that CO transcription peaks late in the day,and GI enhances this peak under long-day conditions.In genotypes where CO
20、transcription shifts to earlier in the day,CO activation by light is no longer restricted to long days but also occurs during short days,leading to earlier FT transcription and flowering under short-day conditions.Gibberellin PathwayGibberellin(GA)is a growth regulator that promotes flowering in Ara
21、bidopsis.The GIBBERELLIN 20 OXIDASE(GA20ox)enzyme catalyzes several steps in the biosynthesis of GA by oxidizing a number of precursors.Mutations that reduce this biosynthetic pathway or increase the degradation of GA delay flowering,particularly under short-day conditions.The concentration of bioac
22、tive GA(GA4)increases at the meristem immediately prior to floral induction.This GA4 probably moves from other parts of the plant to the meristem because mRNAs encoding GA20ox and other GA-biosynthetic enzymes do not detectably accumulate at the meristem.However,such mRNAs do increase in the stalk o
23、f the leaves(i.e.,the petiole)in response to day length,suggesting that the petioles are one site of GA biosynthesis during floral induction.The GA 2-oxidase(GA2ox)enzyme deac-tivates GA by hydroxylating it.Ambient Temperature PathwayArabidopsis plants flower earlier when grown at higher temperature
24、s,such as 23C,than at lower temperatures,such as 16C.The MADS box transcription factor SHORT VEG-ETATIVE PHASE(SVP)appears to play a crucial role in this pathway because svp mutants are insensitive to changes in ambient temperature and flower early at both tempera-tures.SVP represses FT transcriptio
25、n(and thus flowering)at lower temperatures,but the levels of FT mRNA increase at higher temperatures.Age PathwayAs the plant ages,concentrations of the SQUAMOSA PROMOTER BINDING LIKE(SPL)transcription factors increase.SPLs promote flowering by initiating the expression of several other transcription
26、 factors,such as LEAFY(LFY),FRUITFULL(FUL),and SOC1.SPL proteins are negatively regulated by the microRNA miR-156,whose cellular levels are higher in younger versus older plants and progressively decrease as the plant ages.Meristem ResponsesDuring floral induction,the shoot apical meristem transform
27、s from a vegetative meristem,which forms leaves,to an inflorescence meristem,which forms flowers.During this process the meristem becomes taller and more domed.These morphological changes are associated with dramatic changes in gene expression,including increased expression of SOC1,which encodes a M
28、ADS box transcription factor.SOC1 activation occurs rapidly when plants are shifted from short days to long days,but SOC1 responds to other floral induction pathways as well.For example,it is activated by GA and aging but repressed by vernalization and ambient temperature pathways through direct inh
29、ibition by FLC and SVP.Activation of SOC1 during long days requires FT and may be a direct response to the arrival of FT at the meristem from the leaf.FT initiates flower development by interacting with the bZIP transcription factor FD and directly promoting transcription of the MADS box factor APET
30、ALA1(AP1).SOC1 activation leads to further changes in gene expression in the meristem as it changes shape and becomes an inflorescence meristem.These include the expression of transcription factors,such as LEAFY(LFY),SPLs,and AGAMOUS-LIKE 24(AGL24).In the inflorescence meristem,TFL1(TERMINAL FLOWER
31、1),a PEPB-like protein(Phosphati-dylethanolamine binding protein)that shares high sequence similarity with FT,prevents the upregulation of AP1 and LFY mRNA.This restricts AP1 and LFY expression to cells committed to becoming floral primordia and ensures the maintenance of a pool of undifferentiated
32、cells that sustain indeterminate growth of the inflorescence meristem.(continued on following page)550.e2 Cell 141,April 3,2010 2010 Elsevier Inc.DOI 10.1016/j.cell.2010.04.024SnapShot:Control of Flowering in ArabidopsisFabio Fornara,Amaury de Montaigu,and George CouplandMax Planck Institute for Pla
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34、Gissot,L.,Sauerbrunn,N.,Ruhl,M.,Jarillo,J.A.,and Coupland,G.(2009).Arabidopsis DOF transcription factors act redundantly to reduce CONSTANS expression and are essential for a photoperiodic flowering response.Dev.Cell 17,7586.He,Y.,and Amasino,R.M.(2005).Role of chromatin modification in flowering-ti
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