Plastid ultrastructure defines the protein import pathway in dinoflagellates

doi:10.1242/jcs.00517

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JCS ePress online publication date 27 May 2003
doi: 10.1242/jcs.00517

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Research Article

Plastid ultrastructure defines the protein import pathway in dinoflagellates

Nasha Nassoury, Mario Cappadocia, and David Morse^*
^* Author for correspondence (e-mail: david.morse{at}umontreal.ca)

Eukaryotic cells contain a variety of different compartmentsthat are distinguished by their own particular function andcharacteristic set of proteins. Protein targeting mechanismsto organelles have an additional layer of complexity in algae,where plastids may be surrounded by three or four membranesinstead of two as in higher plants. The mechanism of proteinimport into dinoflagellates plastids, however, has not beenpreviously described despite the importance of plastid targetingin a group of algae responsible for roughly half the ocean'snet primary production. Here, we show how nuclear-encoded proteinsenter the triple membrane-bound plastids of the dinoflagellateGonyaulax. These proteins all contain an N-terminal leader sequencewith two distinct hydrophobic regions flanking a region richin hydroxylated amino acids (S/T). We demonstrate that plastidproteins transit through the Golgi in vivo, that the first hydrophobicregion in the leader acts as a typical signal peptide in vitro,and that the S/T-rich region acts as a typical plastid transitsequence in transgenic plants. We also show that the secondhydrophobic region acts as a stop transfer sequence so thatplastid proteins in Golgi-derived vesicles are integral membraneproteins with a predominant cytoplasmic component. The dinoflagellatemechanism is thus different from that used by the phylogeneticallyrelated apicomplexans, and instead, is similar to that of thephylogenetically distant Euglena, whose plastids are also boundby three membranes. We conclude that the protein import mechanismis dictated by plastid ultrastructure rather than by the evolutionaryhistory of the cell.

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