The indeterminate floral apex1 gene regulates meristem determinacy and identity in the maize inflorescence

Meristems may be determinate or indeterminate. In maize, the indeterminate inflorescence meristem produces three types of determinate meristems: spikelet pair, spikelet and floral meristems. These meristems are defined by their position and their products. We have discovered a gene in maize, indeterminate floral apex1 (ifa1) that regulates meristem determinacy. The defect found in ifa1 mutants is specific to meristems and does not affect lateral organs. In ifa1 mutants, the determinate meristems become less determinate. The spikelet pair meristem initiates more than a pair of spikelets and the spikelet meristem initiates more than the normal two flowers. The floral meristem initiates all organs correctly, but the ovule primordium, the terminal product of the floral meristem, enlarges and proliferates, expressing both meristem and ovule marker genes. A role for ifa1 in meristem identity in addition to meristem determinacy was revealed by double mutant analysis. In zea agamous1 (zag1) ifa1 double mutants, the female floral meristem converts to a branch meristem whereas the male floral meristem converts to a spikelet meristem. In indeterminate spikelet1 (ids1) ifa1 double mutants, female spikelet meristems convert to branch meristems and male spikelet meristems convert to spikelet pair meristems. The double mutant phenotypes suggest that the specification of meristems in the maize inflorescence involves distinct steps in an integrated process.     

Conservation and divergence of APETALA1/FRUITFULL-like gene function in grasses: evidence from gene expression analyses

Duplicated APETALA1/FRUITFULL (AP1/FUL) genes show distinct but overlapping patterns of expression within rice (Oryza sativa) and within ryegrass (Lolium temulentum), suggesting discrete functional roles in the transition to flowering, specification of spikelet meristem identity, and specification of floral organ identity. In this study, we analyzed the expression of the AP1/FUL paralogues FUL1 and FUL2 across phylogenetically disparate grasses to test hypotheses of gene function. In combination with other studies, our data support similar roles for both genes in spikelet meristem identity, a general role for FUL1 in floral organ identity, and a more specific role for FUL2 in outer floral whorl identity. In contrast to Arabidopsis AP1/FUL genes, expression of FUL1 and FUL2 is consistent with an early role in the transition to flowering. In general, FUL1 has a wider expression pattern in all spikelet organs than FUL2, but both genes are expressed in all spikelet organs in some cereals. FUL1 and FUL2 appear to have multiple redundant functions in early inflorescence development. We hypothesize that sub-functionalization of FUL2 and interaction of FUL2 with LHS1 could specify lemma and palea identity in the grass floret.     

ABERRANT PANICLE ORGANIZATION 1 temporally regulates meristem identity in rice

We report a recessive mutation of rice, aberrant panicle organization 1 (apo1), which severely affects inflorescence architecture, floral organ identity, and leaf production rate. In the wild-type inflorescence, the main-axis meristem aborts after forming 10-12 primary branch primordia. However, in apo1, the main-axis meristem was converted to a spikelet meristem after producing a small number of branch primordia. In addition, the branch meristems in apo1 became spikelet meristems earlier than in wild type. Therefore, in the inflorescence, the apo1 mutation caused the precocious conversion of the meristem identity. In the apo1 flower, lodicules were increased at the expense of stamens, and carpels were formed indeterminately by the loss of meristem determinacy. Vegetative development is also affected in the apo1. Leaves were formed rapidly throughout the vegetative phase, indicating that APO1 is also involved in temporal regulation of leaf production. These phenotypes suggest that the APO1 plays an important role in the temporal regulation of both vegetative and reproductive development.     

AGAMOUS-LIKE24 and SHORT VEGETATIVE PHASE determine floral meristem identity in Arabidopsis

The formation of flowers starts when floral meristems develop on the flanks of the inflorescence meristem. In Arabidopsis the identity of floral meristems is promoted and maintained by APETALA1 (AP1) and CAULIFLOWER (CAL). In the ap1 cal double mutant the meristems that develop on the flanks of the inflorescence meristem are unable to establish floral meristem identity and develop as inflorescence meristems on which new inflorescence meristems subsequently proliferate. We demonstrate in contrast to previous models that AGAMOUS-LIKE 24 (AGL24) and SHORT VEGETATIVE PHASE (SVP) are also floral meristem identity genes since the ap1-10 agl24-2 svp-41 triple mutant continuously produces inflorescence meristems in place of flowers. Furthermore, our results explain how AP1 switches from a floral meristem identity factor to a component that controls floral organ identity.     

Genetic Interactions That Regulate Inflorescence Development in Arabidopsis

In Arabidopsis, floral meristems arise in continuous succession directly on the flanks of the inflorescence meristem. Thus, the pathways that regulate inflorescence and floral meristem identity must operate both simultaneously and in close spatial proximity. The TERMINAL FLOWER 1 (TFL1) gene of Arabidopsis is required for normal inflorescence meristem function, and the LEAFY (LFY), APETALA 1 (AP1), and APETALA 2 (AP2) genes are required for normal floral meristem function. We present evidence that inflorescence meristem identity is promoted by TFL1 and that floral meristem identity is promoted by parallel developmental pathways, one defined by LFY and the other defined by AP1/AP2. Our analysis suggests that the acquisition of meristem identity during inflorescence development is mediated by antagonistic interactions between TFL1 and LFY and between TFL1 and AP1/AP2. Based on this study, we propose a simple model for the genetic regulation of inflorescence development in Arabidopsis. This model is discussed in relation to the proposed interactions between the inflorescence and the floral meristem identity genes and in regard to other genes that are likely to be part of the genetic hierarchy regulating the establishment and maintenance of inflorescence and floral meristems.     

barren inflorescence2 regulates axillary meristem development in the maize inflorescence

Organogenesis in plants is controlled by meristems. Shoot apical meristems form at the apex of the plant and produce leaf primordia on their flanks. Axillary meristems, which form in the axils of leaf primordia, give rise to branches and flowers and therefore play a critical role in plant architecture and reproduction. To understand how axillary meristems are initiated and maintained, we characterized the barren inflorescence2 mutant, which affects axillary meristems in the maize inflorescence. Scanning electron microscopy, histology and RNA in situ hybridization using knotted1 as a marker for meristematic tissue show that barren inflorescence2 mutants make fewer branches owing to a defect in branch meristem initiation. The construction of the double mutant between barren inflorescence2 and tasselsheath reveals that the function of barren inflorescence2 is specific to the formation of branch meristems rather than bract leaf primordia. Normal maize inflorescences sequentially produce three types of axillary meristem: branch meristem, spikelet meristem and floral meristem. Introgression of the barren inflorescence2 mutant into genetic backgrounds in which the phenotype was weaker illustrates additional roles of barren inflorescence2 in these axillary meristems. Branch, spikelet and floral meristems that form in these lines are defective, resulting in the production of fewer floral structures. Because the defects involve the number of organs produced at each stage of development, we conclude that barren inflorescence2 is required for maintenance of all types of axillary meristem in the inflorescence. This defect allows us to infer the sequence of events that takes place during maize inflorescence development. Furthermore, the defect in branch meristem formation provides insight into the role of knotted1 and barren inflorescence2 in axillary meristem initiation.     

Heterogeneous expression patterns and separate roles of the SEPALLATA gene LEAFY HULL STERILE1 in grasses

SEPALLATA (SEP) genes exhibit distinct patterns of expression and function in the grass species rice (Oryza sativa) and maize (Zea mays), suggesting that the role of the genes has changed during the evolution of the family. Here, we examine expression of the SEP-like gene LEAFY HULL STERILE1 (LHS1) in phylogenetically disparate grasses, reconstruct the pattern of gene expression evolution within the family, and then use the expression patterns to test hypotheses of gene function. Our data support a general role for LHS1 in specifying determinacy of the spikelet meristem and also in determining the identity of lemmas and paleas; these two functions are separable, as is the role of the gene in specifying floret meristems. We find no evidence that LHS1 determines flower number; it is strongly expressed in all spikelet meristems even as they are producing flowers, and expression is not correlated with eventual flower number. LHS1 expression in only the upper flowers of the spikelet appears to be the ancestral state; expression in all flowers is derived in subfamily Pooideae. LHS1 expression in pistils, stamens, and lodicules varies among the cereals. We hypothesize that LHS1 may have affected morphological diversification of grass inflorescences by mediating the expression of different floral identity genes in different regions of the floret and spikelet.     

MULTI-FLORET SPIKELET1, Which Encodes an AP2/ERF Protein,Determines Spikelet Meristem Fate and Sterile Lemma Identity in Rice

The spikelet is a unique inflorescence structure of grass. The molecular mechanism that controls the development of the spikelet remains unclear. In this study, we identified a rice (Oryza sativa) spikelet mutant, multi-floret spikelet1 (mfs1), that showed delayed transformation of spikelet meristems to floral meristems, which resulted in an extra hull-like organ and an elongated rachilla. In addition, the sterile lemma was homeotically converted to the rudimentary glume and the body of the palea was degenerated in mfs1. These results suggest that the MULTI-FLORET SPIKELET1 (MFS1) gene plays an important role in the regulation of spikelet meristem determinacy and floral organ identity. MFS1 belongs to an unknown function clade in the APETALA2/ethylene-responsive factor (AP2/ERF) family. The MFS1-green fluorescent protein fusion protein is localized in the nucleus. MFS1 messenger RNA is expressed in various tissues, especially in the spikelet and floral meristems. Furthermore, our findings suggest that MFS1 positively regulates the expression of LONG STERILE LEMMA and the INDETERMINATE SPIKELET1 (IDS1)-like genes SUPERNUMERARY BRACT and OsIDS1.In the reproductive phase of angiosperms, the shoot meristem is transformed into an inflorescence meristem, which then produces a floral meristem from which floral organs begin to develop, according to the mechanism known as the ABCDE model (Coen and Meyerowitz, 1991; Coen and Nugent, 1994; Dreni et al., 2007; Ohmori et al., 2009). An inflorescence can be classified as determinate or indeterminate based on whether its apical meristem is transformed into a terminal floral meristem. In an indeterminate inflorescence, the lateral meristem is permanently differentiated from the apical meristem, which is not converted into the terminal floral meristem, as occurs during the development of the inflorescences of Arabidopsis (Arabidopsis thaliana) and snapdragon (Antirrhinum majus). In contrast, in a determinate inflorescence, the apical meristem is transformed into the terminal floral meristem after the production of a fixed number of lateral meristems, as occurs during the development of the inflorescences of tobacco (Nicotiana tabacum) and tomato (Solanum lycopersicum; Bradley et al., 1997; Ratcliffe et al., 1999; Sussex and Kerk, 2001; Chuck et al., 2008).In general, inflorescences in grasses consist of branches and spikelets (Coen and Nugent, 1994; Itoh et al., 2005; Kobayashi et al., 2010). In these organisms, the branch meristem is determinate. It produces several lateral spikelet meristems, followed by the final production of a terminal spikelet meristem. The spikelet, the specific unit of the grass inflorescence, comprises a pair of bracts and one to 40 florets; it shows determinacy or indeterminacy depending on the species (Clifford, 1987; Malcomber et al., 2006). In species with a determinate spikelet, such as rice (Oryza sativa), after the production of fixed lateral floral meristems, the spikelet meristems are converted into terminal floral meristems, resulting in termination of the spikelet meristem fate. In contrast, in species with an indeterminate spikelet, such as wheat (Triticum aestivum), the spikelet meristem fate is maintained continuously and produces a variable number of lateral floral meristems.In Arabidopsis, the gene TERMINAL FLOWER1 (TFL1) was shown to maintain indeterminacy in the fate of the inflorescence. In the tfl1 mutant, the inflorescence meristems were converted into floral meristems earlier than in the wild type, but the ectopic expression of TFL1 resulted in the transformation of floral meristems at a later stage of development to secondary inflorescence meristems (Bradley et al., 1997; Ratcliffe et al., 1999; Mimida et al., 2001). In rice, overexpression of either of the TFL1-like genes, RICE CENTRORADIALIS1 (RCN1) or RCN2, delayed the transition of branch meristems to spikelet meristems and finally resulted in the production of a greater number of branches and spikelets than in the wild type (Nakagawa et al., 2002; Rao et al., 2008).To date, no gene that acts to maintain the indeterminacy of the spikelet meristem has been reported. However, two classes of genes have been shown to be involved in termination of the indeterminacy of spikelet meristems. One of these is the group of terminal floral meristem identity genes. A grass-specific LEAFY HULL STERILE1 (LHS1) clade in the SEPALLATA (SEP) subfamily belongs to this class. LHS1-like genes were found to be expressed only in the terminal floral meristem in species with spikelet determinacy, which suggested that they exclusively determine the production of the terminal floral meristem, by which the spikelet meristem acquires determinacy (Cacharroón et al., 1999; Malcomber and Kellogg, 2004; Zahn et al., 2005). The other class comprises the INDETERMINATE SPIKELET1 (IDS1)-like genes, which belong to the APETALA2/ethylene-responsive factor (AP2/ERF) family. Unlike LHS1-like genes, this class of genes regulates the correct timing of the transition of the spikelet meristem to the floral meristem but does not specify the identity of the terminal floral meristem. In maize (Zea mays), loss of IDS1 function produces extra florets (Chuck et al., 1998). In addition, mutation of SISTER OF IDS1 (SID1), a paralog of IDS1 in maize, resulted in no defects in terms of spikelet development. However, the ids1+sid1 double mutant failed to generate floral organs and instead developed more bract-like structures than are found in wild-type plants (Chuck et al., 2008). The rice genome contains two IDS1-like genes, SUPERNUMERARY BRACT (SNB) and OsIDS1. Loss of activity of SNB or OsIDS1 produced extra rudimentary glumes, and snb+osids1 double mutant plants developed more rudimentary glumes than either of its parental mutants (Lee et al., 2007; Lee and An, 2012). These results revealed that the mutated IDS1-like genes prolonged the activity of the spikelet meristem.In most members of Oryzeae, the spikelet is distinct from those of other grasses, in that it comprises a pair of rudimentary glumes, a pair of sterile lemmas (empty glumes), and one floret (Schmidt and Ambrose, 1998; Ambrose et al., 2000; Kellogg, 2009; Hong et al., 2010). The rudimentary glumes are generally regarded as severely reduced bract organs, but the origin of sterile lemmas has been widely debated. Recent studies suggested that the sterile lemmas are the vestigial lemmas of two lateral florets. The gene LONG STERILE LEMMA (G1)/ELONGATED EMPTY GLUME1 (ELE1) is a member of a plant-specific gene family. In the g1/ele1 mutant, sterile lemmas were found to be homeotically transformed into lemmas (Yoshida et al., 2009; Hong et al., 2010). The OsMADS34 and EXTRA GLUME1 (EG1) genes were also shown to determine the identities of sterile lemmas. In the osmads34 and eg1 mutants, the sterile lemmas were enlarged and acquired the identities of lemmas (Li et al., 2009; Gao et al., 2010; Kobayashi et al., 2010). Additionally, the SEP-like gene LHS1/OsMADS1, which specifies the identities of both the lemma and the palea, was not expressed in sterile lemmas, and ectopic expression in sterile lemmas resulted in the transformation of sterile lemmas to lemmas (Jeon et al., 2000; Li et al., 2009; Tanaka et al., 2012). These findings suggest that the sterile lemma may be homologous to the lemma. Nevertheless, some researchers still considered that the sterile lemmas are instead vestigial bract-like structures similar to the rudimentary glumes (Schmidt and Ambrose, 1998; Kellogg, 2009; Hong et al., 2010).In this study, we isolated the rice MULTI-FLORET SPIKELET1 (MFS1) gene, which belongs to a clade of unknown function in the AP2/ERF gene family. The mutation of MFS1 was shown to delay the transformation of the spikelet meristem to the floral meristem and to result in degeneration of the sterile lemma and palea. These results suggest that MFS1 plays an important role in the regulation of spikelet determinacy and organ identity. Our findings also reveal that MFS1 positively regulates the expression of G1 and the IDS1-like genes SNB and OsIDS1.     

APETALA 2‐like genes AP2L2 and Q specify lemma identity and axillary floral meristem development in wheat

The spikelet is the basic unit of the grass inflorescence. In tetraploid (Triticum turgidum) and hexaploid wheat (Triticum aestivum), the spikelet is a short indeterminate branch with two proximal sterile bracts (glumes) followed by a variable number of florets, each including a bract (lemma) with an axillary flower. Varying levels of miR172 and/or its target gene Q (AP2L5) result in gradual transitions of glumes to lemmas, and vice versa. Here, we show that AP2L5 and its related paralog AP2L2 play critical and redundant roles in the specification of axillary floral meristems and lemma identity. AP2L2, also targeted by miR172, displayed similar expression profiles to AP2L5 during spikelet development. Loss‐of‐function mutants in both homeologs of AP2L2 (henceforth ap2l2) developed normal spikelets, but ap2l2 ap2l5 double mutants generated spikelets with multiple empty bracts before transitioning to florets. The coordinated nature of these changes suggest an early role of these genes in floret development. Moreover, the flowers of ap2l2 ap2l5 mutants showed organ defects in paleas and lodicules, including the homeotic conversion of lodicules into carpels. Mutations in the miR172 target site of AP2L2 were associated with reduced plant height, more compact spikes, promotion of lemma‐like characters in glumes and smaller lodicules. Taken together, our results show that the balance in the expression of miR172 and AP2‐like genes is crucial for the correct development of spikelets and florets, and that this balance has been altered during the process of wheat and barley (Hordeum vulgare) domestication. The manipulation of this regulatory module provides an opportunity to modify spikelet architecture and improve grain yield.     

Interactions among APETALA1, LEAFY, and TERMINAL FLOWER1 specify meristem fate.

Upon floral induction, the primary shoot meristem of an Arabidopsis plant begins to produce flower meristems rather than leaf primordia on its flanks. Assignment of floral fate to lateral meristems is primarily due to the cooperative activity of the flower meristem identity genes LEAFY (LFY), APETALA1 (AP1), and CAULIFLOWER. We present evidence here that AP1 expression in lateral meristems is activated by at least two independent pathways, one of which is regulated by LFY. In lfy mutants, the onset of AP1 expression is delayed, indicating that LFY is formally a positive regulator of AP1. We have found that AP1, in turn, can positively regulate LFY, because LFY is expressed prematurely in the converted floral meristems of plants constitutively expressing AP1. Shoot meristems maintain an identity distinct from that of flower meristems, in part through the action of genes such as TERMINAL FLOWER1 (TFL1), which bars AP1 and LFY expression from the influorescence shoot meristem. We show here that this negative regulation can be mutual because TFL1 expression is downregulated in plants constitutively expressing AP1. Therefore, the normally sharp phase transition between the production of leaves with associated shoots and formation of the flowers, which occurs upon floral induction, is promoted by positive feedback interactions between LFY and AP1, together with negative interactions of these two genes with TFL1.     

Evolution of floral meristem identity genes. Analysis of Lolium temulentum genes related to APETALA1 and LEAFY of Arabidopsis

Flowering (inflorescence formation) of the grass Lolium temulentum is strictly regulated, occurring rapidly on exposure to a single long day (LD). During floral induction, L. temulentum differs significantly from dicot species such as Arabidopsis in the expression, at the shoot apex, of two APETALA1 (AP1)-like genes, LtMADS1 and LtMADS2, and of L. temulentum LEAFY (LtLFY). As shown by in situ hybridization, LtMADS1 and LtMADS2 are expressed in the vegetative shoot apical meristem, but expression increases strongly within 30 h of LD floral induction. Later in floral development, LtMADS1 and LtMADS2 are expressed within spikelet and floret meristems and in the glume and lemma primordia. It is interesting that LtLFY is detected quite late (about 12 d after LD induction) within the spikelet meristems, glumes, and lemma primordia. These patterns contrast with Arabidopsis, where LFY and AP1 are consecutively activated early during flower formation. LtMADS2, when expressed in transgenic Arabidopsis plants under the control of the AP1 promoter, could partially complement the organ number defect of the severe ap1-15 mutant allele, confirming a close relationship between LtMADS2 and AP1.     

Analysis of PEAM4, the pea AP1 functional homologue, supports a model for AP1-like genes controlling both floral meristem and floral organ identity in different plant species

APETALA1 (AP1) and its homologue SQUAMOSA (SQUA) are key regulatory genes specifying floral meristem identity in the model plants Arabidopsis and Antirrhinum. Despite many similarities in their sequence, expression and functions, only AP1 appears to have the additional role of specifying sepal and petal identity. No true AP1/SQUA-functional homologues from any other plant species have been functionally studied in detail, therefore the question of how the different functions of AP1-like genes are conserved between species has not been addressed. We have isolated and characterized PEAM4, the AP1/SQUA-functional homologue from pea, a plant with a different floral morphology and inflorescence architecture to that of Arabidopsis or Antirrhinum. PEAM4 encodes for a polypeptide 76% identical to AP1, but lacks the C-terminal prenylation motif, common to AP1 and SQUA, that has been suggested to control the activity of AP1. Nevertheless, constitutive expression of PEAM4 caused early flowering in tobacco and Arabidopsis. In Arabidopsis, PEAM4 also caused inflorescence-to-flower transformations similar to constitutive AP1 expression, and was able to rescue the floral organ defects of the strong ap1-1 mutant. Our results suggest that the control of both floral meristem and floral organ identity by AP1 is not restricted to Arabidopsis, but is extended to species with diverse floral morphologies, such as pea.     

花序分生组织特性基因TFL1的系统发育及其功能分析

TFL1同源基因在维持植物营养生长和花序分生组织特性方面起着非常重要的作用,其功能的丧失常导致植物提早开花,花序的正常发育受到抑制,最终茎端形成顶花。至今已经有28种植物的TFL1基因被克隆到,其中包括拟南芥、金鱼草和番茄等模式植物。TFL1 蛋白的系统发育树基本符合物种的亲缘关系。作为花序分生组织特性基因的TFL1与花分生组织特性基因LFY 和AP1相互作用,抑制花序分生组织向花分生组织的转变。TFL1和LFY等基因可用来培育早花新品种,也可用于培育无果的新品种,减少悬铃木、杨、柳等果毛的污染。