1. Monosaccharide transporters in plants: structure, function and physiology
- Author
-
Norbert Sauer and Michael Büttner
- Subjects
Models, Molecular ,DNA, Complementary ,Monosaccharide Transport Proteins ,Protein domain ,Molecular Sequence Data ,Biophysics ,Saccharomyces cerevisiae ,Biology ,Genes, Plant ,Biochemistry ,Substrate Specificity ,Structure-Activity Relationship ,Monosaccharide transport ,Sugar sensing ,Gene Expression Regulation, Plant ,Escherichia coli ,Monosaccharide ,Animals ,Cloning, Molecular ,Integral membrane protein ,Phylogeny ,Plant Proteins ,chemistry.chemical_classification ,Reporter gene ,Cell Membrane ,Transporter ,Sink development ,Cell Biology ,Transport protein ,Transmembrane domain ,Kinetics ,chemistry ,Plasma membrane - Abstract
Monosaccharide transport across the plant plasma membrane plays an important role both in lower and higher plants. Algae can switch between phototrophic and heterotrophic growth and utilize organic compounds, such as monosaccharides as additional or sole carbon sources. Higher plants represent complex mosaics of phototrophic and heterotrophic cells and tissues and depend on the activity of numerous transporters for the correct partitioning of assimilated carbon between their different organs. The cloning of monosaccharide transporter genes and cDNAs identified closely related integral membrane proteins with 12 transmembrane helices exhibiting significant homology to monosaccharide transporters from yeast, bacteria and mammals. Structural analyses performed with several members of this transporter superfamily identified protein domains or even specific amino acid residues putatively involved in substrate binding and specificity. Expression of plant monosaccharide transporter cDNAs in yeast cells and frog oocytes allowed the characterization of substrate specificities and kinetic parameters. Immunohistochemical studies, in situ hybridization analyses and studies performed with transgenic plants expressing reporter genes under the control of promoters from specific monosaccharide transporter genes allowed the localization of the transport proteins or revealed the sites of gene expression. Higher plants possess large families of monosaccharide transporter genes and each of the encoded proteins seems to have a specific function often confined to a limited number of cells and regulated both developmentally and by environmental stimuli.
- Published
- 2000
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