ELE restrains empty glumes from developing into lemmas

Although there is evident homology among reproductive organs when comparing Poaceae (grass) and eudicots, the identity of grass specific organs, such as lodicules, palea, lemma, and glumes has been the subject of a vast and largely inconclusive discussion. Here we provide some direct evidence to support the idea that the empty glumes of rice (Oryza sativa) are counterparts of lemmas. We show that the development of empty glumes is regulated by ELE (elongated empty glume), which belongs to a plant ...     

ELE restrains empty glumes from developing into lemmas

Although there is evident homology among reproductive organs when comparing Poaceae(grass)and eudicots,the identity of grass specific organs,such as lodicules,palea,lemma,and glumes has been the subject of a vast and largely inconclusive discussion.Here we provide some direct evidence to support the idea that the empty glumes of rice(Oryza sativa)are counterparts of lemmas.We show that the development of empty glumes is regulated by ELE(elongated empty glume),which belongs to a plant specific novel gene family.Mutations at the ELE locus cause elongated empty glumes,which mimic the lemmas and have the epidermal morphology of lemmas with four or five vascular bundles.As a nuclear-localized gene,ELE is specifically expressed at the empty glumes of immature spikelets,and its ectopic expression causes many floral development defects,including lemma-like palea,extra palea-like structures,elongated lodicules,extra stamens and stigmas.Our result suggests that empty glumes are lemmas of the sterile florets located at the lateral side of the rice spikelet,and ELE acts as a regulator restraining its growth to maintain its small size in wild-type plants.     

The Effect on Wheat Grain Growth of the Removal or ABA Treatment of Glumes and Lemmas

When the glumes and lemmas were removed from wheat spikeletsduring the main grain filling period the uptake of sucrose intothe subtended grains was reduced in a few hours, but the abilityto synthesize starch was not affected for several days, by whichtime a marked loss of water content had occurred. When the deglumedears were covered to maintain high humidity, the grains hada weight and water content similar to those from unprotecteddeglumed ears. The application of ABA to the glumes occasionallyhad a small short-term effect on the uptake of sucrose intothe grain, but there were no long-term effects on dry matteraccumulation despite increased glume senescence. When the glume and lemma were removed shortly after anthesisthe subtended grain grew much less than grains from intact florets,with fewer and smaller aleurone cells. The removal of the lemmafrom the third floret of the spikelet had a similar effect onthe third grain, which could be partly reversed by removal ofthe grains in the lower florets. The role of the glumes andlemmas in grain development is discussed in the light of theseresults.     

对小麦顶生小穗的初步研究

1.顶生小穗的护颖具有特殊的形态,第二护颖常为小花外稃状,腋内有时还保留着雌雄蕊或内稃残余。说明其不稳定和可变的本质。2.顶生小穗具特殊的坐落位置,其小穗轴与主穗轴一致。顶生小穗原始体发生在穗生长锥顶端,其下无苞原始体,长成后也无小穗领。其护颖和小花外稃与侧生小穗下的小穗领呈严格连续互生状态。说明其一次轴的渊源。3.顶生小穗护颖腋内可长出小穗,小花也可代之以小穗,护颖和小花外稃有时以苞片的形式保留于新侧生小穗外侧。新顶生小穗的护颖来自小花外稃。说明顶生小穗护颖腋内的退化花芽、外稃腋内的小花与侧生小穗都是花序一次轴上的二次轴分枝。4.顶生小穗产生小穗的变异严格按自下而上的顺序进行,与原侧生小穗有严格的连续性。5.事实证明,顶生小穗是一次轴花序,它属于穗状花序顶端的可变部分。     

水稻小穗轴维管系统网络结构探讨

对籼型、粳型或其不育系与保持系代表品种小穗解剖观察表明：水稻小穗轴维管系统网络由中央维管束和各分枝维管束复合而成。来自小穗柄的１条大的中央主束和几条边围维管束经数次分枝、联结,不断产生新的分枝维管束进入相应的结构。一般颖片中维管束１－２条,第一稃片中１－３条,第二稃片中１－４条,第二朵退化小花残余结构中０－３条,顶生可孕小花的外稃中５条,内稃中３条,浆片中各２条,雄蕊中各１条,雌蕊中３条,主束与支     

Evidence for distinct roles of the SEPALLATA gene LEAFY HULL STERILE1 in Eleusine indica and Megathyrsus maximus (Poaceae)

LEAFY HULL STERILE1 (LHS1) is an MIKC-type MADS-box gene in the SEPALLATA class. Expression patterns of LHS1 homologs vary among species of grasses, and may be involved in determining palea and lemma morphology, specifying the terminal floret of the spikelet, and sex determination. Here we present LHS1 expression data from Eleusine indica (subfamily Chloridoideae) and Megathyrsus maximus (subfamily Panicoideae) to provide further insights into the hypothesized roles of the gene. E. indica has spikelets with three to eight florets that mature acropetally; E. indica LHS1 (EiLHS1) is expressed in the palea and lemma of all florets. In contrast, M. maximus has spikelets with two florets that mature basipetally; M. maximus LHS1 (MmLHS1) is expressed in the palea and lemma of the distal floret only. These data are consistent with the hypothesis that LHS1 plays a role in determining palea and lemma morphology and specifies the terminal floret of basipetally maturing grass spikelets. However, LHS1 expression does not correlate with floret sex expression; MmLHS1 is restricted to the bisexual distal floret, whereas EiLHS1 is expressed in both sterile and bisexual floret meristems. Phylogenetic analyses reconstruct a complex pattern of LHS1 expression evolution in grasses. LHS1 expression within the gynoecium has apparently been lost twice, once before diversification of a major clade within tribe Paniceae, and once in subfamily Chloridoideae. These data suggest that LHS1 has multiple roles during spikelet development and may have played a role in the diversification of spikelet morphology.     

糖蜜草（Melinis minutiflora Beauv．）幼穗分化发育．及花和果实形态的研究

本文对糖密草（ＭｅｌｉｎｉｓｍｉｎｕｔｉｆｌｏｒａＢｅａｕｖ．）的幼穗分化发育及花和果实的形态作了研究,将幼穗分化发育过程划分为以下九个时期：第一苞原基形成期;第一次枝梗原基形成期;第二、三次枝梗原基形成期;小穗及颖花原基形成期;雌、雄蕊原基形成期;花粉母细胞形成期;花粉母细胞减数分裂期;花粉充实期;花粉成熟期。全过程历时约需４２ｄ．从抽穗到颖果成熟约需５０ｄ。糖蜜草的花序为圆锥花序。每花序有可育花２０００—３０００朵．小穗是由小穗轴、内外颖片、不育花外稃和小花构成。小花包括有内外稃各一片、一鳞被、雄蕊三枚和一枚雌蕊,颖果千粒重为９１ｍｇ。     

Developmental analysis of teosinte glume architecture1: A key locus in the evolution of maize (Poaceae)

A key event in the evolution of maize from teosinte was a reduction in the cupulate fruitcase and softening of the glumes, which increased the accessibility of kernels for harvest. The teosinte glume architecture1 (tga1) locus largely controls this difference between maize and teosinte, and thus may have played a pivotal role in maize evolution. The teosinte allele (tga1+teosinte) lengthens inflorescence internodes, shortens rachillae, and makes glumes longer, thicker, and harder. Developmental characterization of morphometric traits reveals that differences among genotypes are apparent early in female inflorescence development. Increased hardening in glumes homozygous for tga1+teosinte is correlated with a thicker abaxial mesoderm of lignified cells. Silica deposition in the abaxial epidermal cells of the glumes is also affected. In the maize background, glumes homozygous for tga1+teosinte deposit silica in both the short and long cells of the glume epidermis, whereas glumes homozygous for the maize allele (Tga1+Maize) concentrate silica only in the short cells. Silica deposition also appears to be affected by genetic background. The effects of tga1 appear largely to explain the differences in glume induration between maize and teosinte. The diverse pleiotropic effects of tga1 suggest that it is regulatory in nature.     

Inflorescence, spikelet, and floral development in Panicum maximum and Urochloa plantaginea (Poaceae)

Inflorescence development in Panicum maximum and Urochloa plantaginea was comparatively studied with scanning electron and light microscopy to test the transfer of P. maximum to Urochloa and to look for developmental features applicable to future cladistic studies of the phosphoenol pyruvate carboxykinase (PCK) subtype of C(4) photosynthesis clade (P. maximum and some species of Brachiaria, Chaetium, Eriochloa, Melinis, and Urochloa). Eleven developmental features not discernable in the mature inflorescence were found: direction of branch differentiation; origins of primary branches; apical vs. intercalary development of the main axis; direction of spikelet differentiation; direction of glume, lemma and palea differentiation; position of the lower glume (in some cases); size of the floret meristem; pattern of distal floret development; pattern of gynoecium abortion; differential pollen development between proximal and distal floret; and glume elongation. Inflorescence homologies between P. maximum and U. plantaginea are also clarified. Panicum maximum and U. plantaginea differ not only in their mature inflorescence structure but also in eight fundamental developmental features that exclude P. maximum from Urochloa. The following developmental events are related to sex expression: size of floret meristem, gynoecium abortion, pollen development delay in the proximal floret, glume elongation and basipetal floret maturation at anthesis.     

Inheritance of glume length and grain length in hybridisation of Triticum polonicum with hard wheat

Inheritance of glume length and grain length in the hybrids Triticum polonicum with T. durum cv. Kharkivs'ka 19 has been studied. The results show that the "polonicumity" complex inherits as unfully recessive and monogene trait. Positive correlation between glume length and grain length has been shown. It has been revealed that more exact plant distribution to segregation classes is observed for the glume at the second floret than at the first one.     

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.     

Senescence-induced expression of cytokinin reverses pistil abortion during maize flower development

Maize is a monoecious species that produces imperfect (unisexual), highly derived flowers called florets. Within the spikelet, the basic repeating unit of the maize inflorescence, the spikelet meristem gives rise to an upper and a lower floret. Although initially bisexual, floret unisexuality is established through selective organ elimination. In addition, the lower floret of each ear spikelet is aborted early in its development, leaving the upper floret to mature as the only pistillate floret. Expression from the cytokinin-synthesizing isopentenyl transferase (IPT) enzyme under the control of the Arabidopsis senescence-inducible promoter SAG (senescence associated gene)12 was observed during early maize floret development. Moreover, the lower floret was rescued from abortion, resulting in two functional florets per spikelet. The pistil in each floret was fertile, but the spikelet produced just one kernel composed of a fused endosperm with two viable embryos. The two embryos were genetically distinct, indicating that they had arisen from independent fertilization events. These results suggest that cytokinin can determine pistil cell fate during maize floret development.     

Developmental Events Associated with the Critical Stage for Sex Determination in Wild-Rice Florets

The developmental events of florets and a critical stage for sex determination in two wild-rice populations (Zizania palustris cv. Franklin and Zizania palustris cv. K-2Pi) have been identified. Formation of bisexual florets precedes the development of both male and female florets. Developmental indicators, established by measuring the length of florets and panicles, indicate that the critical stage for sex determination occurs when floret and panicle lengths are 1-2 mm and 3 cm, respectively. The stage of floret development at which sex determination occurs is the same in the two investigated wild-rice populations. Organ suppression in bisexual florets is an essential step for sex determination during the formation of unisexual florets. Histological examination of suppressed stamens or pistils in unisexual florets of wild-rice indicates that cell death does not occur during sex determination. In addition, the length of anthers and pistils in bisexual florets indicates that floral development in the transition zone is normal when compared with the male florets in the male spikelets and female florets in the female spikelets.     

Infection Process of Burkholderia glumae in Rice Spikelets

Burkholderia glumae, which causes bacterial panicle blight of rice (BPBR), is a well‐known pathogen. The pathogen‐induced symptoms include seedling rot, grain rot and leaf‐sheath browning in rice plants. B. glumae can incubate in rice plants as endophytes before booting stage of rice. In this study, we constructed a gfp‐labelled system of B. glumae LMG 2196 and used SEM to clarify the colonization course of B. glumae at the heading stage. New locations of B. glumae were found. The pathogens initially distributed on the surface of the glumes and colonized in the glume hairs and cells of the edge of sterile lemma, palea and lemma. The base of glume hairs was the initial position for colonization. Bacterial population raised around glume hairs, penetrated into the inner surface of the palea and lemma, and spread on the gynoecium and stamens through contact. The spreading of B. glumae among the panicles mainly occurred through the contact or friction among glumes or leaf sheaths, but the inner spread of the stamens mainly occurred through the connective tissue of anther. We also detected the differences of bacterial content in stamens, gynoecia and glumes. The growing stage of B. glumae in spikelets could be divided into two sections. The biomass of all parts continued to increase to nearly 10⁸ CFU/g at 10 DAI. This caused wilt symptoms and stopped the pollination. This work showed that glume hairs played an important role in the initial colonization of B. glumae, and provides a foundation for further studies of the infection manner of B. glumae and other pathogenic bacteria.     

Wheat nitrogen metabolism during grain filling: comparative role of glumes and the flag leaf

The mobilization of nitrogen (N) compounds and the roles played by glumes and the flag leaf during grain filling were studied in bread wheat (Triticum aestivum L. cv. Florida) grown under field conditions. Glumes lost twice as much of their total N content as that lost by the flag leaf between the milk and early dough stages. In the flag leaf, glumes and grains, Glu, Asp, Ser and Ala accounted for 85% of all the reductions in the free amino acid pool. Principal component analysis of free amino acid pools separated grains from the glumes and the flag leaf, suggesting grain specific regulations in the use of free amino acids in protein synthesis. In all three organs, no decrease in Gln was detected, probably due to steady glutamine synthetase (GS; EC 6.3.1.2) activities per soluble protein in both the flag leaf and glumes. Compared with the flag leaf, glumes presented relatively smaller amounts of the chloroplast GS associated isoform. This we show is due to a lower relative number of mesophyll cells in glumes as supported by the different anatomy and the cellular pattern of the GS immunolocalization. We argue that cellular distribution plays a key role in supporting metabolism to enable the various functions undertaken by glume tissue.     

Map-based analysis of genetic loci on chromosome 2D that affect glume tenacity and threshability,components of the free-threshing habit in common wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

During the domestication of bread wheat (Triticum aestivum L.), evolutionary modifications that took place in seed dispersal mechanisms enhanced its suitability for agricultural production. One of these modifications involved the evolution of the free-threshing or hulless characteristic. In this study, we studied quantitative trait loci (QTL) affecting components of the free-threshing habit (threshability and glume tenacity) on chromosome 2D in a recombinant inbred line (RIL) population developed by the International Triticeae Mapping Initiative (ITMI) as well as the tenacious glumes 1 (Tg1) gene in F₂ progeny (CS/CS2D F₂) of a cross between Chinese Spring and the 2D2 substitution line [Chinese Spring (Ae. tauschii 2D)]. In the ITMI population, two QTL affected threshability (QFt.orst-2D.1 and QFt.orst-2D.2) and their location coincided with QTL affecting glume tenacity (QGt.orst-2D.1 and QGt.orst-2D.2). In the CS/CS2D F₂ population, the location of QTL that affected glume tenacity (QGt.orst-2D.1), the size of a glume base scar after detachment (QGba.orst-2D), and Tg1 (12-cM interval between Xwmc112 and Xbarc168) also coincided. Map comparisons suggest that QFt-orst-2D.1, QGt.orst-2D.1, and QGba.orst-2D correspond to Tg1 whereas QFt.orst-2D.2 and QGt.orst-2D.2 appear to represent separate loci. The observation of coincident QTL for threshability and glume tenacity suggests that threshability is a function of glume adherence. In addition, the observation of the coincident locations of Tg1 and QTL for the force required to detach a glume and the size of a glume base scar after detachment suggests that Tg1’s effect on both glume tenacity and threshability resides on its ability to alter the level of physical attachment of glumes to the rachilla of a spikelet.