Molecular factors affecting the accumulation of recombinant proteins in the Chlamydomonas reinhardtii chloroplast.

In an effort to develop microalgae as a robust system for the production of valuable proteins, we analyzed some of the factors affecting recombinant protein expression in the chloroplast of the green alga Chlamydomonas reinhardtii. We monitored mRNA accumulation, protein synthesis, and protein turnover for three codon-optimized transgenes including GFP, bacterial luciferase, and a large single chain antibody. GFP and luciferase proteins were quite stable, while the antibody was less so. Measurements of protein synthesis, in contrast, clearly showed that translation of the three chimeric mRNAs was greatly reduced when compared to endogenous mRNAs under control of the same atpA promoter/UTR. Only in a few conditions this could be explained by limited mRNA availability since, in most cases, recombinant mRNAs accumulated quite well when compared to the atpA mRNA. In vitro toeprint and in vivo polysome analyses suggest that reduced ribosome association might contribute to limited translational efficiency. However, when recombinant polysome levels and protein synthesis are analyzed as a whole, it becomes clear that other steps, such as inefficient protein elongation, are likely to have a considerable impact. Taken together, our results point to translation as the main step limiting the expression of heterologous proteins in the C. reinhardtii chloroplast.

Contribution of 5'- and 3'-untranslated regions of plastid mRNAs to the expression of Chlamydomonas reinhardtii chloroplast genes.

Expression of chloroplast genes is primarily regulated posttranscriptionally, and a number of RNA elements, found in either the 5'- or 3'-untranslated regions (UTRs) of plastid mRNAs, that impact gene expression have been identified. Complex regulatory and feedback mechanisms influence both translation and protein accumulation, making assignment of roles for specific RNA elements difficult. To identify specific contributions made by various UTRs on translation of plastid mRNAs, we used a heterologous gfp reporter gene that is fused combinatorially to chloroplast 5'- and 3'-UTRs. In general, the 5'-UTR, including the promoter, of the plastid atpA and psbD genes produced the highest levels of chimeric mRNA and protein accumulation, while the 5'-UTR of the rbcL and psbA genes produced less mRNA and protein. Varying the 3'-UTR had little impact on mRNA and protein accumulation, as long as a 3'-UTR was present. Overall, accumulation of chimeric mRNAs was proportional to protein accumulation, with a few notable exceptions. Light-regulated translation continues to operate in chimeric mRNAs containing the 5'-UTR of either the psbA or psbD mRNAs, despite translation of these two chimeric mRNAs at very different efficiencies, suggesting that translational efficiency and light-regulated translation are separate events. Translation of some chimeric mRNAs was much more efficient than others, suggesting that interactions between the untranslated and coding sequences can dramatically impact translational efficiency.