Project description:miR167 limits anther growth to potentiate anther dehiscence

Project description:The aim of this study was to examine the contribution of ARF6 and ARF8 to flower gene expression. Flowers from arf6 arf8 plants undergo a developmental arrest at approximately stage 12, just prior to flower opening. Flowers from wild-type, ARF6/arf6 arf8/arf8, and arf6 arf8 plants were separated into stage 1-10 flowers, stage 11+12 flowers, and stage 13-14 flowers to define the developmental stages at which ARF6 and ARF8 are required for gene expression. Keywords: comparison of wild type and arf6 arf8 mutants

Project description:The aim of this study was to examine the contribution of ARF6 and ARF8 to flower gene expression. Flowers from arf6 arf8 plants undergo a developmental arrest at approximately stage 12, just prior to flower opening. Flowers from wild-type, arf6/arf6 ARF8/arf8, and arf6 arf8 plants were separated into stage 1-10 flowers, stage 11+12 flowers, and stage 13-14 flowers to define the developmental stages at which ARF6 and ARF8 are required for gene expression.

Project description:The aim of this study was to examine the roles of Auxin Response Factors (ARFs) in flower gene expression. Flowers from arf6 arf8 plants undergo a developmental arrest at approximately stage 12, just prior to flower opening. Wild-type, ARF6/arf6 arf8/arf8, and arf6 arf8 plants were treated with 10 uM indole-3-acetic acid for thirty minutes to identify genes that respond rapidly to auxin in an ARF6/ARF8-dependent manner. Keywords: auxin response; comparison of wild type and arf6 arf8 mutants

Project description:The aim of this study was to examine the roles of Auxin Response Factors (ARFs) in flower gene expression. Flowers from arf6 arf8 plants undergo a developmental arrest at approximately stage 12, just prior to flower opening. Wild-type, ARF6/arf6 arf8/arf8, and arf6 arf8 plants were treated with 10 uM indole-3-acetic acid for thirty minutes to identify genes that respond rapidly to auxin in an ARF6/ARF8-dependent manner. Experiment Overall Design: Wild-type, ARF6/arf6 arf8/arf8, and arf6 arf8 plants were sprayed with 10 mM indole-3-acetic acid in 1% methanol, 0.05% Tween-20. Thirty minutes after treatment, flowers (stage 1-14) were collected, frozen in liquid nitrogen, and used for RNA extraction.

Project description:The coordination of pollen viability, stamen filament elongation and anther dehiscence is essential for the successful pollination and reproduction in angiosperms. The hormone jasmonic acid (JA) are crucial for these processes. However, the tight regulation of JA biosynthesis during stamen development is still largely unknown. Here, we demonstrate that the rice (Oryza sativa) ERF-associated amphiphilic repression (EAR) motif-containing protein TCP INTERACTOR CONTAINING EAR MOTIF PROTEIN1 (OsTIE1) tightly regulates JA biosynthesis by repressing TEOSINTE BRANCHED1/CYCLOIDEA/PROLIFERATINGCELLFACTORS (TCP) transcription factor OsTCP1/PCF5 during stamen development. The loss of OsTIE1 function in ostie1 mutants causes male sterility. The ostie1 mutants display inviable pollen, the early stamen filament elongation and the precocious anther dehiscence. JA biosynthesis is activated earlier and JA level is precociously increased in anthers of ostie1. The expression of OsTIE1 is developmentally regulated during stamen development. OsTIE1 is localized in nuclei and has transcriptional repression activity. We further show that OsTIE1 directly interacts with OsTCP1, and overexpression of OsTCP1 caused early anther dehiscence resembling that of ostie1. The expression of genes encoding key enzymes of JA biosynthesis including Oryza sativa lipoxygenase (OsLOX) genes is regulated by the OsTIE1-OsTCP1 complex. Our findings discover that the OsTIE1-OsTCP1 module plays critical roles in stamen development by finely tuning JA biosynthesis, and provides a new foundation to create male sterile plants for hybrid seed production.

Project description:MALE STERILITY 35 (MS35/ MYB26) is a R2R3-type MYB transcription factor (Steiner-Large et al., 2003). MS35 is suggested to be a key regulator in the process of lignified secondary thickening in the anther endothecium which provides mechanical force for anther dehiscence (Dawson et al., 1999). The ms35 mutant bears non-dehiscent anthers and thus exhibits a male sterile phenotype. This microarray experiment aims to identify genes controlled by MS35 and thus establish the precise role MS35 plays during anther development. We have demonstrated that MS35 is expressed in the anther during pollen mitotic divisions. Comparisons of gene expression will be carried out between anthers from the Ler.gl (wild-type control) and ms35.gl (mutant) to identify genes with altered expression due to the ms35 mutation. The use of the gl marker will enable a prompt identification of the ms35 mutant amongst the segregating population. The wild-type control line was chosen to be Ler.gl which ensures that the changes of gene expression are not due to the gl mutation. Plants were grown in growth chambers at 22h of daylight (167 umol.m2.sec-1) at 24 C and 2h of night at 24 C. Developmental stages of anthers were defined by bud position and DAPI staining. As soon as the plants showed three fertile or sterile siliques, anther and filaments were collected from both lines at Pollen Mitosis I (PM I), bicellular, and PM II stage, separately. RNA was extracted using RNeasy Mini Kit (Qiagen, USA) and digested with DNase to eliminate genomic DNA contamination. The identified genes will be further analysed using bioinformatics and genomic (knockout) resources that are available for Arabidopsis. 12 samples were used in this experiment.

Project description:MALE STERILITY 35 (MS35/ MYB26) is a R2R3-type MYB transcription factor (Steiner-Large et al., 2003). MS35 is suggested to be a key regulator in the process of lignified secondary thickening in the anther endothecium which provides mechanical force for anther dehiscence (Dawson et al., 1999). The ms35 mutant bears non-dehiscent anthers and thus exhibits a male sterile phenotype. This microarray experiment aims to identify genes controlled by MS35 and thus establish the precise role MS35 plays during anther development. We have demonstrated that MS35 is expressed in the anther during pollen mitotic divisions. Comparisons of gene expression will be carried out between anthers from the Ler.gl (wild-type control) and ms35.gl (mutant) to identify genes with altered expression due to the ms35 mutation. The use of the gl marker will enable a prompt identification of the ms35 mutant amongst the segregating population. The wild-type control line was chosen to be Ler.gl which ensures that the changes of gene expression are not due to the gl mutation. Plants were grown in growth chambers at 22h of daylight (167 umol.m2.sec-1) at 24 C and 2h of night at 24 C. Developmental stages of anthers were defined by bud position and DAPI staining. As soon as the plants showed three fertile or sterile siliques, anther and filaments were collected from both lines at Pollen Mitosis I (PM I), bicellular, and PM II stage, separately. RNA was extracted using RNeasy Mini Kit (Qiagen, USA) and digested with DNase to eliminate genomic DNA contamination. The identified genes will be further analysed using bioinformatics and genomic (knockout) resources that are available for Arabidopsis.

Project description:Transcriptomes from multiple pre-meiotic stages of wild type, mac1, and msca1 maize anthers were characterized by microarray hybridization. The goal was to characterize the developmental progression as the anther specifies five cell types and grows rapidly precedeing meiotic entry. The stages characterized were immature anther primordia (0.15 mm long in maize) containing just stem cells, through somatic and germinal cell fate specification (0.20 and 0.25 mm), mitotic proliferation (0.4 mm), and finally the birth of the middle layer and tapetum (0.7 mm). To obtain cell-type specific markers, at 0.7 mm we also compared whole anthers to collections of laser-microdissected anther cell types including the archesporial cells (pre-meiotic germinal cells), nutritive layers (middle layer and tapetum) and structural layers (endothecium and epidemis) of the anther lobe. keyword: anther development, maize, male-sterile Three loop designs covered the early stages (up to 0.7 mm) with two replicates for each comparison. The first loop had 0.2 mm long anthers and compared wild type versus mac1 mutant versus msca1 mutant in a three vertex loop design. The second loop had four vertices and compared 0.15 mm WT anther primordia, 0.25 mm WT anthers, 0.4 mm WT anthers and finally 0.4 mm mac1 mutant anthers. The third had 0.7 mm anthers in a three vertex loop with the nutritive layers (middle layer and tapetum) at one vertex, the germinal pre-meiotic cells at another vertex, and whole anthers at a third vertex. The whole anther samples were also, separately and outside of the loop, compared in four replicates to the structural layers (endothecium and epidermis).

Project description:Our results show that ICE1 controls plant male fertility via impacting anther dehydration. The loss-of-function mutation in ICE1 gene in Arabidopsis caused anther indehiscence and decreased pollen viability as well as germination rate. Further analysis revealed that the anthers in the mutant of ICE1 (ice1-2) had the structure of stomium, though the epidermis did not shrink to dehisce. The anther indehiscence and influenced pollen viability as well as germination in ice1-2 were due to abnormal anther dehydration, for most of anthers dehisced with drought treatment and pollen grains from those dehydrated anthers had similar viability and germination rates compared with wild type. Accordingly, the sterility of ice1-2 could be rescued by ambient dehydration treatments. Likewise, the stomatal differentiation of ice1-2 anther epidermis was disrupted in a different manner compared with that in leaves. ICE1 specifically bound to MYC-recognition elements in the promoter of FAMA, a key regulator of guard cell differentiation, to activate FAMA expression. Transcriptome profiling in the anther tissues further exhibited ICE1-modulated genes associated with water transport and ion exchange in the anther. Together, this work reveals the key role of ICE1 in male fertility control and establishes a regulatory network mediated by ICE1 for stomata development and water movement in the anther.