Abstract
All aspects of plant and animal development are controlled by complex networks of transcription factors. Transcription factors are essential for converting signaling inputs, such as changes in daylength, into complex gene regulatory outputs. While some transcription factors control gene expression by binding to cis-regulatory elements as individual subunits, others function in a combinatorial fashion. How individual subunits of combinatorial transcription factors are spatially and temporally deployed (e.g. expression-level, posttranslational modifications and subcellular localization) has profound effects on their control of gene expression. In the model plant Arabidopsis (Arabidopsis thaliana), we have identified 36 Nuclear Factor Y (NF-Y) transcription factor subunits (10 NF-YA, 13 NF-YB, and 13 NF-YC subunits) that can theoretically combine to form 1,690 unique complexes. Individual plant subunits have functions in flowering time, embryo maturation, and meristem development, but how they combine to control these processes is unknown. To assist in the process of defining unique NF-Y complexes, we have created promoter:beta-glucuronidase fusion lines for all 36 Arabidopsis genes. Here, we show NF-Y expression patterns inferred from these promoter:beta-glucuronidase lines for roots, light- versus dark-grown seedlings, rosettes, and flowers. Additionally, we review the phylogenetic relationships and examine protein alignments for each NF-Y subunit family. The results are discussed with a special emphasis on potential roles for NF-Y subunits in photoperiod-controlled flowering time.
Highlights
All aspects of plant and animal development are controlled by complex networks of transcription factors
Because there are still relatively few Arabidopsis Nuclear Factor Y (NF-Y) papers and we provide information on all 36 genes, we discussed nomenclature options with curators from The Arabidopsis Information Resource (TAIR)
When plant NF-Y proteins have been associated with specific functions, identifying their interacting partners has been complicated by the numbers of possible NF-YA/ B/C combinations
Summary
All aspects of plant and animal development are controlled by complex networks of transcription factors. While some transcription factors control gene expression by binding to cis-regulatory elements as individual subunits, others function in a combinatorial fashion. Combinatorial transcription factors are multiprotein complexes that derive their gene regulatory capacity from both intrinsic properties and the properties of their trans-acting partners (Singh, 1998) Participation in such higher order complexes allows an organism to use single transcription factors to control multiple genes with different temporal and spatial expression patterns. NF-Y transcription factors are likely found in all eukaryotes and have roles in the regulation of diverse genes (McNabb et al, 1995; Edwards et al, 1998; Maity and de Crombrugghe, 1998; Mantovani, 1999) In mammals, where their biochemistry is well described, the NF-Y transcription factor complex is composed of three unique subunits: NF-YA, NF-YB, and NF-YC. NF-Y function is essential for mammalian development (Hu and Maity, 2000; Bhattacharya et al, 2003)
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