The REproductive Meristem (REM) gene family encodes for transcription factors belonging to the B3 DNA binding domain superfamily. In Arabidopsis thaliana, the REM gene family is composed of 45 members, preferentially expressed during flower, ovule, and seed developments. Only a few members of this family have been functionally characterized: VERNALIZATION1 (VRN1) and, most recently, TARGET OF FLC AND SVP1 (TFS1) regulate flowering time and VERDANDI (VDD), together with VALKYRIE (VAL) that control the death of the receptive synergid cell in the female gametophyte. We investigated the role of REM34, REM35, and REM36, three closely related and linked genes similarly expressed in both female and male gametophytes. Simultaneous silencing by RNA interference (RNAi) caused about 50% of the ovules to remain unfertilized. Careful evaluation of both ovule and pollen developments showed that this partial sterility of the transgenic RNAi lines was due to a postmeiotic block in both female and male gametophytes. Furthermore, protein interaction assays revealed that REM34 and REM35 interact, which suggests that they work together during the first stages of gametogenesis.
Super-radiant Rayleigh scattering from a Bose-Einstein condensate, driven by a single far-detuned laser beam, is strongly limited by dephasing due to inhomogeneous broadening. We demonstrate that the dephasing can be reversed applying a Bragg pulse of area pi after the first superradiant scattering, stimulating a superradiant echo and inducing a further transfer of atoms from the initial condensate to a condensate with relative momentum 2hk in the direction of the laser
SUMMARY The architecture of the rice inflorescence is an important determinant of crop yield. The length of the inflorescence and the number of branches are among the key factors determining the number of spikelets, and thus grains, that a plant will develop. In particular, the timing of the identity transition from indeterminate branch meristem to determinate spikelet meristem governs the complexity of the inflorescence. In this context, the ALOG gene TAWAWA1 (TAW1) has been shown to delay the transition to determinate spikelet development in Oryza sativa (rice). Recently, by combining precise laser microdissection of inflorescence meristems with RNA‐seq, we observed that two ALOG genes, OsG1‐like 1 (OsG1L1) and OsG1L2, have expression profiles similar to that of TAW1. Here, we report that osg1l1 and osg1l2 loss‐of‐function CRISPR mutants have similar phenotypes to the phenotype of the previously published taw1 mutant, suggesting that these genes might act on related pathways during inflorescence development. Transcriptome analysis of the osg1l2 mutant suggested interactions of OsG1L2 with other known inflorescence architecture regulators and the data sets were used for the construction of a gene regulatory network (GRN), proposing interactions among genes potentially involved in controlling inflorescence development in rice. In this GRN, we selected the homeodomain‐leucine zipper transcription factor encoding the gene OsHOX14 for further characterization. The spatiotemporal expression profiling and phenotypical analysis of CRISPR loss‐of‐function mutants of OsHOX14 suggests that the proposed GRN indeed serves as a valuable resource for the identification of new proteins involved in rice inflorescence development.
The ALOGs (ArabidopsisLIGHT-DEPENDENT SHORT HYPOCOTYLS 1and OryzaG1) are Transcription Factors (TFs) from an evolutionarily conserved plant-specific family shown to play critical roles in meristem identity, inflorescence architecture and organ boundaries in diverse species from mosses to higher flowering plants. However, the DNA binding-specificity and molecular determinants of protein-DNA interactions of this family were uncharacterized. Usingin vitrogenome-wide studies, we identified the conserved DNA motif bound by ALOG proteins from the liverwortMarchantia polymorphaand the flowering plants Arabidopsis, tomato and rice. In order to determine the amino acids responsible for DNA-binding specificity, we solved the 2.1Å structure of the ALOG DNA binding domain in complex with its cognate DNA. The ALOG DBD is an all-alpha helical domain with a structural zinc ribbon insertion and an N-terminal disordered NLS. The NLS sequence forms an integral part of the DNA binding domain and contributes to direct base read-out. To define the function of a group of redundant ALOG proteins in the model plant Arabidopsis thaliana, we generated a series ofalogmutants and uncovered their participation in a gene regulatory network involving the other floral regulators LEAFY, BLADE-ON-PETIOLE and PUCHI, all active in defining boundary regions between reproductive meristems and repressing bracts development. Taken together, this work provides the biochemical and structural basis for DNA-binding specificity of an evolutionarily conserved TF family and reveals its role as a key player in defining organ boundaries in Arabidopsis.Significance StatementTranscription Factors (TFs) are key proteins that bind specific regions in the genome and regulate the expression of associated genes. Not all organisms possess the same set of TFs and some, like the ALOGs, are specific to the plant kingdom. These TFs have been shown to play important roles from mosses to flowering plants. However, it was not known what DNA motif they recognize and how they bind DNA. Here we identify this motif, we show it is widely conserved in evolution and we understand how this new type of DNA binding domain works at the structural level. In addition, we also show that severalALOGgenes from Arabidopsis share a redundant function within the genetic network underlying correct floral meristem development.
The architecture of the rice inflorescence is an important determinant of seed yield. The length of the inflorescence and the number of branches are among the key factors determining the amount of spikelets, and thus seeds, that will develop. Especially the timing of the identity transition from indeterminate branch meristem to determinate spikelet meristem regulates the complexity of the inflorescence. In this context, the ALOG gene TAWAWA1 (TAW1) has been shown to delay the transition to determinate spikelet development in rice. Recently, by combining precise laser microdissection of inflorescence meristems with RNA-seq we observed that two ALOG genes, Oryza sativa OsG1-like 1 (OsG1L1) and OsG1L2, have an expression profile similar to TAW1. Here we report that osg1l1 and osg1l2 loss-of-function CRISPR mutants have similar phenotypes as the taw1 mutant, suggesting that these genes might act on related pathways during inflorescence development. Transcriptome analysis of the osg1l2 mutant suggested interactions of OsG1L2 with other known inflorescence architecture regulators and the datasets were also used for the construction of a gene regulatory network (GRN) proposing interactions between genes potentially involved in controlling inflorescence development in rice. The spatio-temporal expression profiling and phenotypical analysis of CRISPR loss-of-function mutants of the homeodomain-leucine zipper transcription factor gene OsHOX14 suggest that the proposed GRN indeed serves as a valuable resource for the identification of new players involved in rice inflorescence development.
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