Phylogenetic and expression analysis of sucrose phosphate synthase isozymes in plants
Autor: | Nanfei Xu, James A. Morrell, Philip W. Miller, Robert L. D'ordine, Linda L. Lutfiyya, Stephen M.G. Duff |
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Rok vydání: | 2006 |
Předmět: |
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Physiology education Molecular Sequence Data Arabidopsis Plant Science Isozyme Zea mays fluids and secretions Phylogenetics Gene Expression Regulation Plant Sequence Analysis Protein Gene duplication Botany Databases Genetic Amino Acid Sequence Gene Phylogeny Gene Library Plant Proteins Genetics Expressed Sequence Tags biology Phylogenetic tree cDNA library fungi food and beverages Oryza equipment and supplies biology.organism_classification Circadian Rhythm Cold Temperature Isoenzymes Glucosyltransferases Fertilization Agronomy and Crop Science Sequence Alignment Phylogenetic nomenclature |
Zdroj: | Journal of plant physiology. 164(7) |
ISSN: | 0176-1617 |
Popis: | Summary In plants and microbes, sucrose phosphate synthase (SPS) is an important enzyme in sucrose biosynthesis. Several different isozymes of SPS exist in plants. Genomic and EST sequence data from Arabidopsis, rice and maize has been analyzed. This analysis has revealed that the Arabidopsis genome contains four unique SPS genes. The rice databases (Monsanto proprietary, and public databases) contain five unique full-length SPS genes. Using the Monsanto maize EST and genomic sequence databases, we have identified five full length and two partial SPS sequences, bringing the total number of presently known maize SPS genes to at least seven. Phylogenetic analysis of all known SPS sequences revealed several putative evolutionary branches of SPS. We have classified SPS genes into three major groups in higher plants, all with distinct features from the known microbial SPS genes. Furthermore, this analysis suggests evolutionary divergence of monocotyledonous (monocot) and dicotyledonous (dicot) SPS sequences. The evidence suggests that several gene duplication events occurred at various points during evolution, both before and after the monocot/dicot split. It appears that at least one of the major forms of SPS genes may have evolved after the divergence of monocots and dicots. In addition, several more recent gene duplication events may have occurred after maize/rice speciation, giving rise to additional SPS genes in maize. Some of the variants lack one or more of the presently known regulatory sites, implying that this evolutionary divergence may have given rise to enzymes with functional differences. We present evidence from transcript distribution studies using cDNA libraries as well as transcriptional profiling experiments and propose that specific SPS genes have diverse patterns of expression that are sometimes responsive to environmental signals. Our data suggests that higher plant SPS isozymes differ with respect to their patterns of expression and regulation and that our proposed phylogenetic classification reflects specific functional categories for higher plant SPS isozymes. |
Databáze: | OpenAIRE |
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