Molecular basis for the specification of floral organs by APETALA3 and PISTILLATA
How different organs are formed from small sets of undifferentiated precursor cells is a key question in developmental biology. To understand the molecular mechanisms underlying organ specification in plants, we studied the function of the homeotic selector genes APETALA3 (AP3) and PISTILLATA (PI), which control the formation of petals and stamens during Arabidopsis flower development. To this end, we characterized the activities of the transcription factors that AP3 and PI encode throughout flower development by using perturbation assays as well as transcript profiling and genomewide localization studies, in combination with a floral induction system that allows a stage-specific analysis of flower development by genomic technologies. We discovered considerable spatial and temporal differences in the requirement for AP3/PI activity during flower formation and show that they control different sets of genes at distinct phases of flower development. The genomewide identification of target genes revealed that AP3/PI act as bifunctional transcription factors: they activate genes involved in the control of numerous developmental processes required for organogenesis and repress key regulators of carpel formation. Our results imply considerable changes in the composition and topology of the gene network controlled by AP3/PI during the course of flower development. We discuss our results in light of a model for the mechanism underlying sex-determination in seed plants, in which AP3/PI orthologues might act as a switch between the activation of male and the repression of female development.F lowers are typically composed of four organ types, which are disposed in four floral whorls. From the outside of the flower to the center, they are sepals, petals, stamens, and carpels (the subunits of the gynoecium). The developmental fate of these different types of organs is specified by a small number of floral organ identity genes. The pivotal role of these genes was uncovered through the analysis of mutants that form flowers with homeotic transformations, i.e., the replacement of one type of organ with another (1-4). Based on the morphological defects of the individual mutants and their genetic interactions, it was proposed that the floral organ identity genes act in a combinatorial manner and have distinct functions during flower development, with the so-called A function genes being required for the formation of sepals and petals, B function genes for petal and stamen development, and C function genes for the formation of stamens and carpels. This well-established ABC model of floral organ identity specification (5) has provided, since its introduction more than 20 y ago, an invaluable framework for the analysis of the genetic mechanisms underlying the formation and evolution of flowers.Molecular characterization of the floral organ identity genes in different species revealed that they encode transcription factors and belong, with few exceptions, to the family of MADS domain proteins (1-3). The floral organ identity factors w...
The floral organ identity factor AGAMOUS (AG) is a key regulator of Arabidopsis thaliana flower development, where it is involved in the formation of the reproductive floral organs as well as in the control of meristem determinacy. To obtain insights into how AG specifies organ fate, we determined the genes and processes acting downstream of this C function regulator during early flower development and distinguished between direct and indirect effects. To this end, we combined genome-wide localization studies, gene perturbation experiments, and computational analyses. Our results demonstrate that AG controls flower development to a large extent by controlling the expression of other genes with regulatory functions, which are involved in mediating a plethora of different developmental processes. One aspect of this function is the suppression of the leaf development program in emerging floral primordia. Using trichome initiation as an example, we demonstrate that AG inhibits an important aspect of leaf development through the direct control of key regulatory genes. A comparison of the gene expression programs controlled by AG and the B function regulators APETALA3 and PISTILLATA, respectively, showed that while they control many developmental processes in conjunction, they also have marked antagonistic, as well as independent activities. INTRODUCTIONHow different types of organs are formed from undifferentiated stem cells is a central question in biology. It is known that in both plants and animals, organogenesis is controlled to a large extent by master regulatory genes, which typically encode transcription factors. While it is currently not well understood how these regulators act at the molecular level, the recent development of experimental approaches that allow the characterization of protein-DNA interactions and transcriptional profiles on a genome-wide scale has led to detailed insights into the function of some of these transcription factors (Wellmer and Riechmann, 2005;Hueber and Lohmann, 2008).In flowering plants, the different types of floral organs (i.e., sepals, petals, stamens, and carpels) are specified by the activities of a small set of master regulators, termed floral organ identity genes Coen and Meyerowitz, 1991). The pivotal role of these genes in flower development was uncovered through the identification of mutants that exhibit homeotic transformations (i.e., the replacement of one organ type by another) . Based on the phenotypes of these mutants, it was proposed that the floral organ identity genes control organ fate in a combinatorial manner (Coen and Meyerowitz, 1991). According to this socalled ABC model, sepals are specified by A function genes, petals by a combination of A and B function activities, stamens by B and C function genes, and carpels by C function gene activity alone. The molecular characterization of the genes affected in floral homeotic mutants in different species showed that they encode transcription factors and belong, with few exceptions, to the family of MADS domain ...
Gene network analysis of Arabidopsis thaliana flower development through dynamic gene perturbations
SUMMARYUnderstanding how flowers develop from undifferentiated stem cells has occupied developmental biologists for decades. Key to unraveling this process is a detailed knowledge of the global regulatory hierarchies that control developmental transitions, cell differentiation and organ growth. These hierarchies may be deduced from gene perturbation experiments, which determine the effects on gene expression after specific disruption of a regulatory gene. Here, we tested experimental strategies for gene perturbation experiments during Arabidopsis thaliana flower development. We used artificial miRNAs (amiRNAs) to disrupt the functions of key floral regulators, and expressed them under the control of various inducible promoter systems that are widely used in the plant research community. To be able to perform genome-wide experiments with stage-specific resolution using the various inducible promoter systems for gene perturbation experiments, we also generated a series of floral induction systems that allow collection of hundreds of synchronized floral buds from a single plant. Based on our results, we propose strategies for performing dynamic gene perturbation experiments in flowers, and outline how they may be combined with versions of the floral induction system to dissect the gene regulatory network underlying flower development.
In the last few years, the idea of food and nutrition has undergone radical changes. The paradigm defining food as a simple source of energy and body mass has evolved in a novel concept, in which nutrients can exert specific functions directly linked to human health. Several edibles contain biological active compounds that influence cellular, metabolic and physiologic processes. A variety of dietary compounds have been associated with specific effects and mechanisms of action, often involving epigenetic modifications and gene expression changes. DNA methylation, histone modifications and the activity of non-coding RNAs control chromatin condensation state, allowing the interaction of DNA with transcription factors required for transcriptional activation. Some metabolites act as substrates of key chromatin remodeling factors or compete with other substrates, influencing their catalytic activity. The quantity and quality of macronutrients assumed by diet offers a possible mechanism of interaction between the body and its environment. A number of biological compounds are known to interact with the epigenome. Folic acid, methionine, choline and other B group vitamins are an important source of one-carbon groups required for methylation of histone proteins and non-histone chromatin remodeling factors. Other compounds like polyphenols, including resveratrol, curcumin and quercetin exert a multitude of biological activities. Furthermore, these compounds can influence DNA methyltransferases, the enzymes responsible for DNA methylation. Dietary interventions aimed to maximize potential health benefits derived from nutrition have shown that dietary regimens can be very effective for prevention and treatment of several diseases. Calorie restriction, protein restriction, fast mimicking diets or time restricted feeding have shown to have significant effects on health. Food quality is crucial for the activity of biological compounds and their potential health benefits. Diets rich in animal-derived proteins are associated with higher rates of mortality compared to diets based on plant-derived proteins.
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