The structure of precursor mRNAs and of excised intron RNAs in chloroplasts of Euglena gracilis

Partially spliced precursor mRNAs (pre-mRNAs) in the steady-state population of RNA from chloroplasts of Euglena gracilis were found by electron microscopy. The structure and the frequency of the pre-mRNAs of the psbA gene (the gene for the 32-kd protein of photosystem II), which is split by four introns in Euglena chloroplasts was analysed by electron microscopy. A chloroplast DNA (cpDNA) fragment containing the psbA gene from Euglena, was cloned into a pEMBL vector. The single-stranded recombinant phage DNA of the coding strand was prepared and hybridized with cpRNA. The majority of hybrids were formed with mature mRNA, but approximately 8% of the hybrids were formed with pre-mRNAs. The pre-mRNAs were either unspliced or incompletely spliced. A detailed analysis of the structure and the frequency of the pre-mRNAs of the psbA gene showed that the four introns are neither spliced out in a strictly random way, nor in a 5'-3' or 3'-5' direction. Introns 2 and 3 are preferentially spliced out first, intron 1 intermediately and intron 4 is generally spliced out last. However, this sequence is not a strict rule. We conclude that the introns can be spliced independently, each one at a different rate. The coding strand from a fragment of the psbA gene was separated and annealed with low mol. wt. cpRNA, which was isolated from an agarose gel. Small circular hybrids were found at the positions of the four introns, demonstrating for the first time covalently closed circular excised intron RNAs (iRNAs) in chloroplasts.     

Light regulated translational activators: identification of chloroplast gene specific mRNA binding proteins.

Genetic analysis has revealed a set of nuclear-encoded factors that regulate chloroplast mRNA translation by interacting with the 5' leaders of chloroplastic mRNAs. We have identified and isolated proteins that bind specifically to the 5' leader of the chloroplastic psbA mRNA, encoding the photosystem II reaction center protein D1. Binding of these proteins protects a 36 base RNA fragment containing a stem-loop located upstream of the ribosome binding site. Binding of these proteins to the psbA mRNA correlates with the level of translation of psbA mRNA observed in light- and dark-grown wild type cells and in a mutant that lacks D1 synthesis in the dark. The accumulation of at least one of these psbA mRNA-binding proteins is dependent upon chloroplast development, while its mRNA-binding activity appears to be light modulated in developed chloroplasts. These nuclear encoded proteins are prime candidates for regulators of chloroplast protein synthesis and may play an important role in coordinating nuclear-chloroplast gene expression as well as provide a mechanism for regulating chloroplast gene expression during development in higher plants.     

Development of a luciferase reporter gene, luxCt, for Chlamydomonas reinhardtii chloroplast

Luciferase reporter genes have been successfully used in a variety of organisms to examine gene expression in living cells, but are yet to be successfully developed for use in chloroplast. Green fluorescent protein (gfp) has been used as a reporter of chloroplast gene expression, but because of high auto-fluorescence, very high levels of GFP accumulation are required for visualization in vivo. We have developed a luciferase reporter for chloroplast by synthesizing the two-subunit bacterial luciferase (lux)AB, as a single fusion protein in Chlamydomonas reinhardtii chloroplast codon bias. We expressed a chloroplast luciferase gene, luxCt, in C. reinhardtii chloroplasts under the control of the ATPase alpha subunit (atpA) or psbA promoter and 5' untranslated regions (UTRs) and the rubisco large subunit (rbcL) 3' UTR. We show that luxCt is a sensitive reporter of chloroplast gene expression, and that luciferase activity can be measured in vivo using a charge coupled device (CCD) camera or in vitro using a luminometer. We further demonstrate that luxCt protein accumulation, as measured by Western blot analysis, is proportional to luminescence, as determined both in vivo and in vitro, and that luxCt is capable of reporting changes in chloroplast gene expression during a dark to light shift. These data demonstrate the utility of the luxCt gene as a versatile and sensitive reporter of chloroplast gene expression in living cells.