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    <ns5:pria35u3i xml:lang="en">Lam Patricia</ns5:pria35u3i>
    <ns5:pria35u9i xml:lang="en">2008 Sep</ns5:pria35u9i>
    <ns5:pria35u13i xml:lang="en">Identification of the wax ester synthase/acyl-coenzyme A: diacylglycerol acyltransferase WSD1 required for stem wax ester biosynthesis in Arabidopsis.</ns5:pria35u13i>
    <ns5:pria35u3i xml:lang="en">Wu Xuemin</ns5:pria35u3i>
    <ns5:pria35u8i xml:lang="en">18621978</ns5:pria35u8i>
    <ns5:pria35s10i xml:lang="en">Wax esters are neutral lipids composed of aliphatic alcohols and acids, with both moieties usually long-chain (C(16) and C(18)) or very-long-chain (C(20) and longer) carbon structures. They have diverse biological functions in bacteria, insects, mammals, and terrestrial plants and are also important substrates for a variety of industrial applications. In plants, wax esters are mostly found in the cuticles coating the primary shoot surfaces, but they also accumulate to high concentrations in the seed oils of a few plant species, including jojoba (Simmondsia chinensis), a desert shrub that is the major commercial source of these compounds. Here, we report the identification and characterization of WSD1, a member of the bifunctional wax ester synthase/diacylglycerol acyltransferase gene family, which plays a key role in wax ester synthesis in Arabidopsis (Arabidopsis thaliana) stems, as first evidenced by severely reduced wax ester levels of in the stem wax of wsd1 mutants. In vitro assays using protein extracts from Escherichia coli expressing WSD1 showed that this enzyme has a high level of wax synthase activity and approximately 10-fold lower level of diacylglycerol acyltransferase activity. Expression of the WSD1 gene in Saccharomyces cerevisiae resulted in the accumulation of wax esters, but not triacylglycerol, indicating that WSD1 predominantly functions as a wax synthase. Analyses of WSD1 expression revealed that this gene is transcribed in flowers, top parts of stems, and leaves. Fully functional yellow fluorescent protein-tagged WSD1 protein was localized to the endoplasmic reticulum, demonstrating that biosynthesis of wax esters, the final products of the alcohol-forming pathway, occurs in this subcellular compartment.</ns5:pria35s10i>
    <ns5:pria35u7i xml:lang="en">97-107</ns5:pria35u7i>
    <ns5:pria35u3i xml:lang="en">Kunst Ljerka</ns5:pria35u3i>
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    <ns5:pria35u3i xml:lang="en">Jetter Reinhard</ns5:pria35u3i>
    <rdfs:label xml:lang="en">Li Fengling et al. 2008 Sep. Plant Physiol. 148(1):97-107.</rdfs:label>
    <ns5:pria35u6i xml:lang="en">1</ns5:pria35u6i>
    <ns5:pria35u3i xml:lang="en">Bird David</ns5:pria35u3i>
    <ns5:pria35u3i xml:lang="en">Zheng Huanquan</ns5:pria35u3i>
    <ns4:attributionURL rdf:resource="http://www.ncbi.nlm.nih.gov/pubmed/18621978"/>
    <ns5:pria35u5i xml:lang="en">148</ns5:pria35u5i>
    <rdfs:seeAlso rdf:resource="http://database.riken.jp/sw/item/cria224u4ria224u18621978i"/>
    <ns5:pria35u3i xml:lang="en">Samuels Lacey</ns5:pria35u3i>
    <ns5:pria35u3i xml:lang="en">Li Fengling</ns5:pria35u3i>
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