Abstract
BackgroundAccurate import of thousands of nuclear-encoded proteins is an important step in plastid biogenesis. However, the import machinery of cytosolic precursor proteins to plastids relies on the Toc and Tic (translocons on the outer envelope and inner envelope membrane of chloroplasts) complexes. Toc159 protein was identified in pea (Pisum sativum) as a major receptor for the precursor proteins. In Arabidopsis thaliana, four psToc159 homologs are identified, termed atToc159, atToc132, atToc120 and atToc90. The expression of these protein-encoding genes has to be properly regulated, because their gene products must be correctly integrated to appropriate apparatus to perform their functions.ResultsIn order to elucidate the regulatory mechanisms of atTOC159 homologous gene expression, transgenes containing various lengths of the upstream regulatory sequences of atTOC159/atTOC132/atTOC120/atTOC90 and GUS coding sequence were transferred to wild type Arabidopsis. In accordance with the analysis of GUS activity in these transgenic plants at various developmental stages, these homologous genes had distinct expression patterns. AtTOC159 and atTOC90 are preferentially expressed in above-ground tissues, such as cotyledons and leaves. In mature roots, atTOC159 and atTOC132 are expressed at higher levels, while atTOC120 and atTOC90 are expressed at the basal level. All four genes have increased expression level during flower and fruit development, particularly a remarkably high expression level of atTOC159 in later stage of fruit development. Furthermore, leader intron in the 5′ UTR induces the expression level of atTOC159 members in a tissue-specific manner. This is able to up-regulate the atTOC120 expression in roots/leaves/flowers, and the atTOC90 expression in cotyledons/leaves/anthers.ConclusionsThe differential expression of atTOC159 gene members is essential during plastid development, because proper atToc159 isoforms are required to import distinct proteins to the plastids of different tissues.Electronic supplementary materialThe online version of this article (doi:10.1186/1999-3110-54-40) contains supplementary material, which is available to authorized users.
Highlights
Accurate import of thousands of nuclear-encoded proteins is an important step in plastid biogenesis
Our results suggest that atTOC159 and atTOC90 are preferentially expressed in 1-and 2-week-old leaves, whereas atTOC159 and atTOC132 have relative higher expression levels in 21-day-old roots
Our results show that the expression yield of atTOC120 is dramatically up-regulated in root tip and flowers by its leader intron sequence, while that of atTOC90 is significantly up-regulated in cotyledons and anthers
Summary
Accurate import of thousands of nuclear-encoded proteins is an important step in plastid biogenesis. In Arabidopsis thaliana, four psToc159 homologs are identified, termed atToc159, atToc132, atToc120 and atToc90 The expression of these protein-encoding genes has to be properly regulated, because their gene products must be correctly integrated to appropriate apparatus to perform their functions. Chromoplasts appear in the cells of leaves, flowers and fruits, and are Except for a few outer membrane proteins, most of the nuclear-encoded plastid proteins are imported into plastids via a set of translocon components located at the outer/inner envelope membrane of chloroplasts (Toc and Tic; Inaba and Schnell, 2008). Toc and Toc159 are Toc core-complex components, and identified as GTPases They are in charge of recognizing preprotein, and are regarded as receptors for the preprotein (Jarvis, 2008). AtToc and atToc132/atToc120 are prone to recognize non-photosynthetic proteins and import them into plastids (Ivanova et al, 2004; Kubis et al, 2004)
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