Gibberellin Acts through Jasmonate to Control the Expression of MYB21, MYB24, and MYB57 to Promote Stamen Filament Growth in Arabidopsis

Precise coordination between stamen and pistil development is essential to make a fertile flower. Mutations impairing stamen filament elongation, pollen maturation, or anther dehiscence will cause male sterility. Deficiency in plant hormone gibberellin (GA) causes male sterility due to accumulation of DELLA proteins, and GA triggers DELLA degradation to promote stamen development. Deficiency in plant hormone jasmonate (JA) also causes male sterility. However, little is known about the relationship between GA and JA in controlling stamen development. Here, we show that MYB21, MYB24, and MYB57 are GA-dependent stamen-enriched genes. Loss-of-function of two DELLAs RGA and RGL2 restores the expression of these three MYB genes together with restoration of stamen filament growth in GA-deficient plants. Genetic analysis showed that the myb21-t1 myb24-t1 myb57-t1 triple mutant confers a short stamen phenotype leading to male sterility. Further genetic and molecular studies demonstrate that GA suppresses DELLAs to mobilize the expression of the key JA biosynthesis gene DAD1, and this is consistent with the observation that the JA content in the young flower buds of the GA-deficient quadruple mutant ga1-3 gai-t6 rga-t2 rgl1-1 is much lower than that in the WT. We conclude that GA promotes JA biosynthesis to control the expression of MYB21, MYB24, and MYB57. Therefore, we have established a hierarchical relationship between GA and JA in that modulation of JA pathway by GA is one of the prerequisites for GA to regulate the normal stamen development in Arabidopsis.     

短命植物甘新念珠芥（Neotorularia korolkovii）和宽翅菘蓝（Isatis violascens）的物候与性表达特征

甘新念珠芥（Neotorularia korolkovii）和宽翅菘蓝（Isatis violascens）是两种广泛分布于新疆准噶尔荒漠的十字花科早春短命植物。对其物候与性表达特征研究结果表明：(1) 二者种子均在3月下旬萌发,5月下旬和6月上旬果实完全成熟,生活周期分别为62d和71d,其中营养生长期约占1/3、生殖生长期约占2/3。(2) 花均为两性,四强雄蕊,单花开放时间较短,长雄蕊的花药开裂早于短雄蕊,但短雄蕊花药中的花粉数较长雄蕊的多。(3) 长、短雄蕊花药中花粉可育率均达90%以上,花粉活力的变化曲线基本相同,柱头可授期分别为9.0h和4.5h,花粉寿命及柱头可授期均短于单花花期,花粉活力最高的时期正是其柱头的最佳授粉期。柱头可授期与花粉活力及寿命在时间上的高度吻合,增加了在不可预测环境中授粉的机会与效率,从而保障生殖成功。(4) 二者的P/O（花粉/胚珠）值分别为108.07±17.17、992.10±272.16,属于自交繁育系统;对其传粉过程、套袋实验及荧光显微观察的结果也证明它们主要以自花传粉的方式来进行交配。(5) 两种植物从物候、花部性表达以及交配式样上均存在与其严酷荒漠环境相适应的特点,是长期适应准噶尔荒漠特殊生态环境的结果,对于保证繁殖成功并扩大种群具有重要的意义。     

Auxin regulates Arabidopsis anther dehiscence, pollen maturation, and filament elongation

We provide evidence on the localization, synthesis, transport, and effects of auxin on the processes occurring late in Arabidopsis thaliana stamen development: anther dehiscence, pollen maturation, and preanthesis filament elongation. Expression of auxin-sensitive reporter constructs suggests that auxin effects begin in anthers between the end of meiosis and the bilocular stage in the somatic tissues involved in the first step of dehiscence as well as in the microspores and in the junction region between anther and filament. In situ hybridizations of the auxin biosynthetic genes YUC2 and YUC6 suggest that auxin is synthesized in anthers. In agreement with the timing of auxin effects, the TIR1, AFB1, AFB2, and AFB3 auxin receptor-encoding genes are transcribed in anthers only during late stages of development starting at the end of meiosis. We found that in tir1 afb triple and quadruple mutants, anther dehiscence and pollen maturation occur earlier than in the wild type, causing the release of mature pollen grains before the completion of filament elongation. We also assessed the contribution of auxin transport to late stamen developmental processes. Our results suggest that auxin synthesized in anthers plays a major role in coordinating anther dehiscence and pollen maturation, while auxin transport contributes to the independent regulation of preanthesis filament elongation.     

ABCB1 and ABCB19 auxin transporters have synergistic effects on early and late Arabidopsis anther development

Arabidopsis abcb1 abcb19 double mutants defective in the auxin transporters ABCB1/PGP1 and ABCB19/PGP19 are altered in stamen elongation, anther dehiscence and pollen maturation. To assess the contribution of these transporters to stamen development we performed phenotypic, histological analyses, and in situ hybridizations on abcb1 and abcb19 single mutant fl owers. We found that pollen maturation and anther dehiscence are precocious in the abcb1 but not in the abcb19 mutant. Accordingly, endothecium ligni fication is altered only in abcb1 anthers. Both abcb1 and abcb1 abcb19 stamens also show altered early development, with asynchronous anther locules and a multilayer tapetum. DAPI staining showed that the timing of meiosis is asynchronous in abcb1 abcb19 anther locules, while only a small percentage of pollen grains are nonviable according to Alexander's staining. In agreement, TAM(TARDY ASYNCHRONOUS MEIOSIS), as well as BAM2(BARELY ANY MERISTEM)—involved in tapetal cell development—are overexpressed in abcb1 abcb19 young fl ower buds. Corre spondingly, ABCB1 and ABCB19 mRNA localization supports the observed phenotypes of abcb1 and abcb1 abcb19 mutant anthers. In conclusion, we provide evidence that auxin transport plays a signi ficant role both in early and late stamen development: ABCB1 plays a major role during anther development, while ABCB19 has a synergistic role.     

<Emphasis Type="Italic">Multiple impairments in male reproduction 1 (mimr1)</Emphasis>, a novel male-sterile mutant of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>, shows several defects in male reproductive development

We have characterized a new male-sterile mutant in Arabidopsis that exhibits conditional sterility but has restored fertility when drought-stressed. This mutant, multiple impairments in male reproduction 1 (mimr1), shows pleiotropic defects in both vegetative and reproductive development. Examination with dissecting and scanning electron microscopes revealed that its pollen grains are not effectively released from the anther locule after dehiscence, and anther differentiation is defective. Growth of the style and stamen filaments are also abnormal. Histological analysis demonstrated that these phenomena are due not only to a noticeably reduced extension of the stamen but also greater elongation of the pistil. Genetic analysis indicated that mimr1 is a single locus recessive nuclear mutant. The mutation can be mapped to a locus strongly linked to a 1200-kb region on Chromosome 3. Meta-analysis of expression patterning presented several candidate genes in that region. No mutants with similar phenotypes have previously been reported, suggesting that mimr1 is a novel male-sterile locus. Characterization of MIMR1 will provide further insights into the molecular basis for the development of plant reproductive organs.     

Activation tagging of an Arabidopsis SHI-RELATED SEQUENCE gene produces abnormal anther dehiscence and floral development

The tapetum is a layer of cells covering the inner surface of pollen sac wall. It contributes to anther development by providing enzymes and materials for pollen coat biosynthesis and nutrients for pollen development. At the end of anther development, the tapetum is degenerated, and the anther is dehisced, releasing mature pollen grains. In Arabidopsis, several genes are known to regulate tapetum formation and pollen development. However, little is known about how tapetum degeneration and anther dehiscence are regulated. Here, we show that an activation-tagged mutant of the S HI-R ELATED S EQUENCE 7 (SRS7) gene exhibits disrupted anther dehiscence and abnormal floral organ development in addition to its dwarfed growth with small, curled leaves. In the mutant hypocotyls, cell elongation was reduced, and gibberellic acid sensitivity was diminished. Whereas anther development was normal, its dehiscence was suppressed in the dominant srs7-1D mutant. In wild-type anthers, the tapetum disappeared at anther development stages 11 and 12. In contrast, tapetum degeneration was not completed at these stages, and anther dehiscence was inhibited, causing male sterility in the mutant. The SRS7 gene was expressed mainly in the filaments of flowers, where the DEFECTIVE-IN-ANTHER-DEHISCENCE 1 (DAD1) enzyme catalyzing jasmonic acid (JA) biosynthesis is accumulated immediately before flower opening. The DAD1 gene was induced in the srs7-1D floral buds. In fully open flowers, the SRS7 gene was also expressed in pollen grains. It is therefore possible that the abnormal anther dehiscence and floral development of the srs7-1D mutant would be related with JA.     

A RING‐type E3 ligase controls anther dehiscence by activating the jasmonate biosynthetic pathway gene DEFECTIVE IN ANTHER DEHISCENCE1 in Arabidopsis

Suppression of expression of DAF [DEFECTIVE IN ANTHER DEHISCENCE1 (DAD1)‐Activating Factor], a gene that encodes a putative RING‐finger E3 ligase protein, causes non‐dehiscence of the anthers, alters pollen development and causes sterility in 35S:DAF RNAi/antisense Arabidopsis plants. This mutant phenotype correlates with the suppression of DAF but not with expression of the two most closely related genes, DAFL1/2. The expression of DAD1 was significantly reduced in 35S:DAF RNAi/antisense plants, and complementation with 35S:DAF did not rescue the dad1 mutant, indicating that DAF acts upstream of DAD1 in jasmonic acid biosynthesis. This assumption is supported by the finding that 35S:DAF RNAi/antisense plants showed a similar cellular basis for anther dehiscence to that found in dad1 mutants, and that external application of jasmonic acid rescued the anther non‐dehiscence and pollen defects in 35S:DAF antisense flowers. We further demonstrate that DAF is an E3 ubiquitin ligase and that its activity is abolished by C132S and H137Y mutations in its RING motif. Furthermore, ectopic expression of the dominant‐negative C132S or H137Y mutations causes similar indehiscence of anthers and reduction in DAD1 expression in transgenic Arabidopsis. This result not only confirms that DAF controls anther dehiscence by positively regulating the expression of DAD1 in the jasmonic acid biosynthesis pathway, but also supports the notion that DAF functions as an E3 ubiquitin ligase, and that the conserved RING‐finger region is required for its activity.     

The DEFECTIVE IN ANTHER DEHISCENCE1 Gene Encodes a Novel Phospholipase A1 Catalyzing the Initial Step of Jasmonic Acid Biosynthesis, Which Synchronizes Pollen Maturation, Anther Dehiscence, and Flower Opening in Arabidopsis

The Arabidopsis mutant defective in anther dehiscence1 (dad1) shows defects in anther dehiscence, pollen maturation, and flower opening. The defects were rescued by the exogenous application of jasmonic acid (JA) or linolenic acid, which is consistent with the reduced accumulation of JA in the dad1 flower buds. We identified the DAD1 gene by T-DNA tagging, which is characteristic to a putative N-terminal transit peptide and a conserved motif found in lipase active sites. DAD1 protein expressed in Escherichia coli hydrolyzed phospholipids in an sn-1–specific manner, and DAD1–green fluorescent protein fusion protein expressed in leaf epidermal cells localized predominantly in chloroplasts. These results indicate that the DAD1 protein is a chloroplastic phospholipase A1 that catalyzes the initial step of JA biosynthesis. DAD1 promoter::β-glucuronidase analysis revealed that the expression of DAD1 is restricted in the stamen filaments. A model is presented in which JA synthesized in the filaments regulates the water transport in stamens and petals.     

The DEFECTIVE IN ANTHER DEHISCIENCE gene encodes a novel phospholipase A1 catalyzing the initial step of jasmonic acid biosynthesis, which synchronizes pollen maturation, anther dehiscence, and flower opening in Arabidopsis

The Arabidopsis mutant defective in anther dehiscence1 (dad1) shows defects in anther dehiscence, pollen maturation, and flower opening. The defects were rescued by the exogenous application of jasmonic acid (JA) or linolenic acid, which is consistent with the reduced accumulation of JA in the dad1 flower buds. We identified the DAD1 gene by T-DNA tagging, which is characteristic to a putative N-terminal transit peptide and a conserved motif found in lipase active sites. DAD1 protein expressed in Escherichia coli hydrolyzed phospholipids in an sn-1-specific manner, and DAD1-green fluorescent protein fusion protein expressed in leaf epidermal cells localized predominantly in chloroplasts. These results indicate that the DAD1 protein is a chloroplastic phospholipase A1 that catalyzes the initial step of JA biosynthesis. DAD1 promoter::beta-glucuronidase analysis revealed that the expression of DAD1 is restricted in the stamen filaments. A model is presented in which JA synthesized in the filaments regulates the water transport in stamens and petals.     

New Clothes for the Jasmonic Acid Receptor COI1: Delayed Abscission,Meristem Arrest and Apical Dominance

In a screen for delayed floral organ abscission in Arabidopsis, we have identified a novel mutant of CORONATINE INSENSITIVE 1 (COI1), the F-box protein that has been shown to be the jasmonic acid (JA) co-receptor. While JA has been shown to have an important role in senescence, root development, pollen dehiscence and defense responses, there has been little focus on its critical role in floral organ abscission. Abscission, or the detachment of organs from the main body of a plant, is an essential process during plant development and a unique type of cell separation regulated by endogenous and exogenous signals. Previous studies have indicated that auxin and ethylene are major plant hormones regulating abscission; and here we show that regulation of floral organ abscission is also controlled by jasmonic acid in Arabidopsis thaliana. Our characterization of coi1-1 and a novel allele (coi1-37) has also revealed an essential role in apical dominance and floral meristem arrest. In this study we provide genetic evidence indicating that delayed abscission 4 (dab4-1) is allelic to coi1-1 and that meristem arrest and apical dominance appear to be evolutionarily divergent functions for COI1 that are governed in an ecotype-dependent manner. Further characterizations of ethylene and JA responses of dab4-1/coi1-37 also provide new information suggesting separate pathways for ethylene and JA that control both floral organ abscission and hypocotyl growth in young seedlings. Our study opens the door revealing new roles for JA and its interaction with other hormones during plant development.     

Amino acid substitutions of GLY98, LEU245 and GLU543 in COI1 distinctively affect jasmonate-regulated male fertility in Arabidopsis

Jasmonate (JA) regulates various plant defense and developmental processes. The F-box protein CORONATINE INSENSITIVE 1 (COI1) perceives JA signals to mediate diverse plant responses including male fertility, root growth, anthocyanin accumulation, and defense against abiotic and biotic stresses. In this study, we carried out genetic, physiological and biochemical analysis on a series of coi1 mutant alleles, and found that different amino acid mutations in COI1 distinctively affect JA-regulated male fertility in Arabidopsis. All the JA responses are disrupted by the COI1 mutations W467* in coi1-1, Q343* (coi1-6), G369E (coi1-4), G98D (coi1-5), G155E (coi1-7), D452A (coi1-9) and L490A (coi1-10), though the coi1-5 mutant (COI1_G98D) contains adequate COI1 protein (～60% of wild-type). Interestingly, the low basal level of COI1^E543K in the coi1-8 mutant (～10% of wild-type COI1 level) is sufficient for maintaining male fertility (～50% of wild-type fertility); the coi1-2 mutant with low level of COI1^L245F (～10% of wild-type) is male sterile under normal growth condition (22°C) but male fertile (～80% of wild-type fertility) at low temperature (16°C); however, both coi1-2 and coi1-8 are defective in the other JA responses (root growth, anthocyanin accumulation, and plant response to the pathogen Pst DC3000 infection).     

Jasmonic acid perception by COI1 involves inositol polyphosphates in Arabidopsis thaliana

Plant responses to wounding are part of their defense responses against insects, and are tightly regulated. The isoleucin conjugate of jasmonic acid (JA‐Ile) is a major regulatory molecule. We have previously shown that inositol polyphosphate signals are required for defense responses in Arabidopsis; however, the way in which inositol polyphosphates contribute to plant responses to wounding has so far remained unclear. Arabidopsis F‐box proteins involved in the perception of JA‐Ile (COI1) and auxin (TIR1) are structurally similar. Because TIR1 has recently been shown to contain inositol hexakisphosphate (InsP₆) as a co‐factor of unknown function, here we explored the possibility that InsP₆ or another inositol polyphosphate is required for COI1 function. In support of this hypothesis, COI1 variants with changes in putative inositol polyphosphate coordinating residues exhibited a reduced interaction with the COI1 target, JAZ9, in yeast two‐hybrid tests. The equivalent COI1 variants displayed a reduced capability to rescue jasmonate‐mediated root growth inhibition or silique development in Arabidopsis coi1 mutants. Yeast two‐hybrid tests using wild‐type COI1 in an ipk1Δ yeast strain exhibiting increased levels of inositol pentakisphosphate (InsP₅) and reduced levels of InsP₆ indicate an enhanced COI1/JAZ9 interaction. Consistent with these findings, Arabidopsis ipk1‐1 mutants, also with increased InsP₅ and reduced InsP₆ levels, showed increased defensive capabilities via COI1‐mediated processes, including wound‐induced gene expression, defense against caterpillars or root growth inhibition by jasmonate. The combined data from experiments using mutated COI1 variants, as well as yeast and Arabidopsis backgrounds altered in inositol polyphosphate metabolism, indicate that an inositol polyphosphate, and probably InsP₅, contributes to COI1 function.     

The intragenic suppressor mutation Leu59Phe compensates for the effect of detrimental mutations in the jasmonate receptor COI1

The phytohormones jasmonates (JAs) control plant development, growth, and defense against insects and pathogens. The Arabidopsis JA receptor Coronatine Insensitive 1 (COI1) interacts with ARABIDOPSIS SKP-LIKE1 (ASK1)/ASK2 to form the SCF^COI1 E3 ligase and mediate JA responses. Here, we performed a genetic suppressor screen using the leaky coi1-2 (COI1^Leu245Phe) mutant for restored sensitivity to JA, and identified the intragenic suppressor mutation Leu59Phe, which was in the region connecting the F-box and leucine-rich repeats domains of COI1. The L59F substitution not only restores the COI1^L245F function, but also the COI1^Gly434Glu (coi1-22^rsp) function in JA responses, through recovering their interactions with ASK1 or ASK2 and their protein levels. The L59F change itself could not enhance the interactions between COI1 and ASK1/2, nor affect JA responses. The present study reveals that the Leu59Phe substitution compensates for the effect of some deleterious mutations in the JA receptor COI1.     

Staggered arrangement and sequential dehiscence of anthers in didynamous stamens facilitate reproductive fitness of Brandisia hancei

Didynamous stamens are separated into two pairs of different length, and the implication of this arrangement has not been well understood. The functional advantages of didynamous stamens were investigated in Brandisia hancei. Change of stamens during floral aging was recorded; the quantity, viability, and siring ability of pollen grains were tested; the anther arrangement was manipulated into four types based on stamen category and number, and fruit set and number of seeds per fruit were measured. Didynamous stamens exhibited staggered anther arrangement, and pollen sacs dehisced gradually. There was no difference for quantity, viability, and siring ability of pollen grains between the two pairs of anthers. Seed production after the removal of one long and one short stamen was higher than that of two long or two short stamens. Through prolonging pollen presentation and promoting delayed self-pollination, staggered arrangement and sequential dehiscence of anthers in didynamous stamens facilitate reproductive fitness of B. hancei.     

花内雄蕊分化及其适应意义

对花内雄蕊存在显著分化的现象进行了分析与归纳, 总结了花内雄蕊分化的各种主要形式及其繁殖适应意义。“花内雄蕊分化”是指花内雄蕊与雄蕊之间存在显著分化的现象, 这一概念可以把二强雄蕊、四强雄蕊和异型雄蕊等以往单独进行研究的相关性状结合起来, 并明确区分了几种新的花内雄蕊分化形式, 以期更准确全面地认识这些相关性状的适应意义与进化。该文将花内雄蕊分化区别为花丝的分化、花药的分化、雄蕊合生的分化、雄蕊运动的分化、退化雄蕊5大类。花丝的分化主要是花丝长度的分化, 如四强雄蕊、二强雄蕊和单强雄蕊; 花药分化主要指花药颜色、花药与花粉粒大小和花药开裂时间等的分化; 雄蕊合生的分化主要体现为花内部分雄蕊合生而部分雄蕊离生; 雄蕊运动的分化指的是花内雄蕊在运动时间或方式上存在差异, 造成雄蕊处于不同的成熟阶段和位于不同的空间位置; 退化雄蕊则是花内部分雄蕊失去了生产花粉的繁殖功能, 通常也发生了花药形态上的巨大改变。异型雄蕊不仅存在花丝和花药的形态分化, 还存在着明显的功能分化, 是分化程度很高的一类特殊的花内雄蕊分化形式。一些特殊的繁育系统, 如异长花柱和镜像花柱等在种内不同个体上存在着不同形式的花内雄蕊分化。花内雄蕊分化在花内造成了多个不同的花药位置, 在很大程度上影响了雌雄异位程度, 对植物自交与异交水平、花内雌雄功能干扰等有着潜在作用; 花内雄蕊分化形成的多个不同空间位置的雄蕊还增加了对多种访花者的吸引与适应潜力, 有可能影响到访花者的类型与访花行为, 得以适应多种传粉者。此外, 花内雄蕊分化可将花粉逐渐分批次分发给访花者, 提高花粉散布效率, 可看成是“花粉呈现理论”所指的花粉装配与分发机制之一。现有的实验研究发现, 花内雄蕊分化能够吸引传粉者、保护正常花药和花粉、促进花粉散发(降低花粉竞争)、实行延迟自交和降低花内雌雄功能干扰等。花内雄蕊分化还缺少系统研究, 有些雄蕊分化形式如单强雄蕊和雄蕊运动的分化还没有针对性的实验揭示其适应意义, 鸭跖草科和某些豆科植物的雄蕊三型分化等现象也缺少进化适应意义的研究。花内雄蕊分化对植物雌性和雄性适合度可能不同的影响、如何与访花者相互作用、如何与其它花部特征一起影响植物繁殖过程等, 可能是这一领域值得今后优先研究的课题。     

Gibberellin regulates Arabidopsis floral development via suppression of DELLA protein function

The phytohormone gibberellin (GA) regulates the development and fertility of Arabidopsis flowers. The mature flowers of GA-deficient mutant plants typically exhibit reduced elongation growth of petals and stamens. In addition, GA-deficiency blocks anther development, resulting in male sterility. Previous analyses have shown that GA promotes the elongation of plant organs by opposing the function of the DELLA proteins, a family of nuclear growth repressors. However, it was not clear that the DELLA proteins are involved in the GA-regulation of stamen and anther development. We show that GA regulates cell elongation rather than cell division during Arabidopsis stamen filament elongation. In addition, GA regulates the cellular developmental pathway of anthers leading from microspore to mature pollen grain. Genetic analysis shows that the Arabidopsis DELLA proteins RGA and RGL2 jointly repress petal, stamen and anther development in GA-deficient plants, and that this function is enhanced by RGL1 activity. GA thus promotes Arabidopsis petal, stamen and anther development by opposing the function of the DELLA proteins RGA, RGL1 and RGL2.