The Nac2 gene of Chlamydomonas encodes a chloroplast TPR-like protein involved in psbD mRNA stability

The psbD mRNA, which encodes the D2 reaction center polypeptide of photosystem II, is one of the most abundant chloroplast mRNAs. We have used genomic complementation to isolate the nuclear Nac2 gene, which is required for the stable accumulation of the psbD mRNA in Chlamydomonas reinhardtii. Nac2 encodes a hydrophilic polypeptide of 1385 amino acids with nine tetratricopeptide-like repeats (TPRs) in its C-terminal half. Cell fractionation studies indicate that the Nac2 protein is localized in the stromal compartment of the chloroplast. It is part of a high molecular weight complex that is associated with non-polysomal RNA. Change of a conserved alanine residue of the fourth TPR motif by site-directed mutagenesis leads to aggregation of Nac2 protein and completely abrogates its function, indicating that this TPR is important for proper folding of the protein and for psbD mRNA stability, processing and/or translation.     

Determinants for stability of the chloroplast psbD RNA are located within its short leader region in Chlamydomonas reinhardtii.

Stability of the chloroplast psbD mRNA encoding the D2 protein of the photosystem II reaction center is drastically decreased in the nuclear photosynthetic mutant nac2-26 of Chlamydomonas reinhardtii. Using biolistic transformation and genetic crosses we have introduced chimeric genes consisting of the psbD leader fused to a reporter gene into the chloroplast in both wild-type and mutant nuclear backgrounds. The chimeric message is destabilized in the latter, but not in the former case, indicating that the 74 nt psbD leader includes one of the target sites for psbD RNA degradation in the absence of wild-type NAC2 function. Increased instability of the psbD leader in mutant versus wild-type chloroplast lysates is also demonstrated in vitro and the primary cleavage sites have been mapped. The instability of the psbD RNA in the mutant correlates with the loss of binding of a 47 kDa protein to the psbD leader RNA, suggesting that this factor acts as message stabilizer in wild-type.     

The 5'' leader of a chloroplast mRNA mediates the translational requirements for two nucleus-encoded functions in Chlamydomonas reinhardtii.

In the green alga Chlamydomonas reinhardtii, the nuclear mutations F34 and F64 have been previously shown to abolish the synthesis of the photosystem II core polypeptide subunit P6, which is encoded by the chloroplast psbC gene. In this report the functions encoded by F34 and F64 are shown to be required for translation of the psbC mRNA, on the basis of the finding that the expression of a heterologous reporter gene fused to the psbC 5' nontranslated leader sequence requires wild-type F34 and F64 alleles in vivo. Moreover, a point mutation in the psbC 5' nontranslated leader sequence suppresses this requirement for wild-type F34 function. In vitro RNA-protein cross-linking studies reveal that chloroplast protein extracts from strains carrying the F64 mutation contain an approximately 46-kDa RNA-binding protein. The absence of the RNA-binding activity of this protein in chloroplast extracts of wild-type strains suggests that it is related to the role of the F64-encoded function for psbC mRNA translation. The binding specificity of this protein appears to be for an AU-rich RNA sequence motif.     

Translation of the chloroplast psbC mRNA is controlled by interactions between its 5' leader and the nuclear loci TBC1 and TBC3 in Chlamydomonas reinhardtii.

Translation of the chloroplast psbC mRNA in Chlamydomonas reinhardtii has been shown previously to require interactions between its 5' untranslated region (5' UTR) and the functions encoded by two nuclear loci, which we name here TBC1 and TBC2. We show that a 97-nucleotide (nt) region located in the middle of the psbC 5' UTR is required for translation initiation. Unlike most procaryotic cis-acting translational control elements, this region has a translational activation function and is located 236 nt upstream from the GUG translation initiation codon. In vivo pulse-labeling of chloroplast-encoded proteins and analyses of the expression of chimeric reporter genes in vivo reveal that a mutation of a newly described locus, TBC3, restores translation from the psbC 5' UTR in the absence of either this cis-acting element or the wild-type trans-acting TBC1 function. These data demonstrate that sequences located in the middle of the psbC 5' UTR, TBC1, and TBC3 functionally interact to control the translation of the psbC mRNA.     

Translation of the psbA mRNA of Chlamydomonas reinhardtii requires a structured RNA element contained within the 5' untranslated region

Translational regulation is a key modulator of gene expression in chloroplasts of higher plants and algae. Genetic analysis has shown that translation of chloroplast mRNAs requires nuclear-encoded factors that interact with chloroplastic mRNAs in a message-specific manner. Using site-specific mutations of the chloroplastic psbA mRNA, we show that RNA elements contained within the 5' untranslated region of the mRNA are required for translation. One of these elements is a Shine- Dalgarno consensus sequence, which is necessary for ribosome association and psbA translation. A second element required for high levels of psbA translation is located adjacent to and upstream of the Shine-Dalgarno sequence, and maps to the location on the RNA previously identified as the site of message-specific protein binding. This second element appears to act as a translational attenuator that must be overcome to activate translation. Mutations that affect the secondary structure of these RNA elements greatly reduce the level of psbA translation, suggesting that secondary structure of these RNA elements plays a role in psbA translation. These data suggest a mechanism for translational activation of the chloroplast psbA mRNA in which an RNA element containing the ribosome-binding site is bound by message- specific RNA binding proteins allowing for increased ribosome association and translation initiation. These elements may be involved in the light-regulated translation of the psbA mRNA.     

In vitro mutational analysis of cis-acting RNA translational elements within the poliovirus type 2 5'' untranslated region.

Initiation of translation on poliovirus RNA occurs by internal binding of ribosomes to a region within the 5' untranslated region (UTR) of the mRNA. This region has been previously roughly mapped between nucleotides 140 and 631 of the 5' UTR and termed the ribosome landing pad. To identify cis-acting elements in the 5' UTR of poliovirus type 2 (Lansing strain) RNA that confer cap-independent internal initiation, we determined the in vitro translational efficiencies of a series of deletion and point mutations within the 5' UTR of the mRNA. The results demonstrate that the 3' border of the core poliovirus ribosome landing pad is located between nucleotides 556 and 585, whereas a region extending between nucleotides 585 and 612 confers enhanced translation. We studied two cis-acting elements within this region of the 5' UTR: a pyrimidine stretch which is critical for translation and an AUG (number 7 from the 5' end) that is located approximately 20 nucleotides downstream from the pyrimidine stretch and augments translation. We also show that the stem-loop structure which contains this AUG is not required for translation.     

Translation of poliovirus RNA: role of an essential cis-acting oligopyrimidine element within the 5'' nontranslated region and involvement of a cellular 57-kilodalton protein.

Translation of poliovirus RNA is initiated by cap-independent internal entry of ribosomes into the 5' nontranslated region. This process is dependent on elements within the 5' nontranslated region (the internal ribosomal entry site) and may involve novel translation factors. Systematic mutation of a conserved oligopyrimidine tract has revealed a cis-acting element that is essential for translation in vitro. The function of this element is related to its position relative to other cis-acting domains. This element is part of a more complex structure that interacts with several cellular factors, but changes in protein binding after mutation of this element were not detected in a UV cross-linking assay. A 57-kDa protein from the ribosomal salt wash fraction of HeLa cells was identified that binds upstream of the oligopyrimidine tract. Translation of poliovirus mRNA in vitro was strongly and specifically inhibited by competition with the p57-binding domain (nucleotides 260 to 488) of the 5' nontranslated region of encephalomyocarditis virus, indicating a probable role for p57 in poliovirus translation. p57 is likely to be identical to the ribosome-associated factor that binds to and is necessary for the function of the internal ribosomal entry site of encephalomyocarditis virus RNA.     

Translation of chloroplast psbA mRNA is modulated in the light by counteracting oxidizing and reducing activities

Light has been proposed to stimulate the translation of Chlamydomonas reinhardtii chloroplast psbA mRNA by activating a protein complex associated with the 5' untranslated region of this mRNA. The protein complex contains a redox-active regulatory site responsive to thioredoxin. We identified RB60, a protein disulfide isomerase-like member of the protein complex, as carrying the redox-active regulatory site composed of vicinal dithiol. We assayed in parallel the redox state of RB60 and translation of psbA mRNA in intact chloroplasts. Light activated the specific oxidation of RB60, on the one hand, and reduced RB60, probably via the ferredoxin-thioredoxin system, on the other. Higher light intensities increased the pool of reduced RB60 and the rate of psbA mRNA translation, suggesting that a counterbalanced action of reducing and oxidizing activities modulates the translation of psbA mRNA in parallel with fluctuating light intensities. In the dark, chemical reduction of the vicinal dithiol site did not activate translation. These results suggest a mechanism by which light primes redox-regulated translation by an unknown mechanism and then the rate of translation is determined by the reduction-oxidation of a sensor protein located in a complex bound to the 5' untranslated region of the chloroplast mRNA.