Gene-specific trans-regulatory functions of magnesium for chloroplast mRNA stability in higher plants

In higher plant chloroplasts the accumulation of plastid-encoded mRNAs during leaf maturation is regulated via gene-specific mRNA stabilization. The half-lives of chloroplast RNAs are specifically affected by magnesium ions. psbA mRNA (D1 protein of photosystem II), rbcL mRNA (large subunit of ribulose-1,5-bisphosphate carboxylase), 16 S rRNA, and tRNA(His) gain stability at specific magnesium concentrations in an in vitro degradation system from spinach chloroplasts. Each RNA exhibits a typical magnesium concentration-dependent stabilization profile. It shows a cooperative response of the stability-regulated psbA mRNA and a saturation curve for the other RNAs. The concentration of free Mg(2+) rises during chloroplast development within a range sufficient to mediate gene-specific mRNA stabilization in vivo as observed in vitro. We suggest that magnesium ions are a trans-acting factor mediating differential mRNA stability.     

A mechanism for light-induced translation of the rbcL mRNA encoding the large subunit of ribulose-1,5-bisphosphate carboxylase in barley chloroplasts

Translational regulation plays a key role in light-induced expression of photosynthesis-related genes at various levels in chloroplasts. We here present the results suggesting a mechanism for light-induced translation of the rbcL mRNA encoding the large subunit (LS) of ribulose-1,5-bisphosphate carboxylase (Rubisco). When 8-day-old dark-grown barley seedlings that have low plastid translation activity were illuminated for 16 h, a dramatic increase in synthesis of large subunit of Rubisco and global activation of plastid protein synthesis occurred. While an increase in polysome-associated rbcL mRNA was observed upon illumination for 16 h, the abundance of translation initiation complexes bound to rbcL mRNA remained constant, indicating that translation elongation might be controlled during this dark-to-light transition. Toeprinting of soluble rbcL polysomes after in organello plastid translation showed that ribosomes of rbcL translation initiation complexes could read-out into elongating ribosomes in illuminated plastids whereas in dark-grown plastids, read-out of ribosomes of translation initiation complexes was inhibited. Moreover, new rounds of translation initiation could also occur in illuminated plastids, but not in dark-grown plastids. These results suggest that translation initiation complexes for rbcL are normally formed in the dark, but the transition step of translation initiation complexes entering the elongation phase of protein synthesis and/or the elongation step might be inhibited, and this inhibition seems to be released upon illumination. The release of such a translational block upon illumination may contribute to light-activated translation of the rbcL mRNA.     

A Five-Base-Pair-Deletion in the Gene for the Large Subunit Causes the Lesion in the Ribulose Bisphosphate Carboxylase/Oxygenase-Deficient Plastome Mutant Sigma of Oenothera hookeri

The gene for the large subunit of ribulose bisphosphate carboxylase/oxygenase (rbcL) has been mapped on the Oenothera hookeri plastid chromosome. It is located close to the gene for the herbicide-binding “32 kd” protein of the photosystem II reaction center (psbA), at a position different from that found in the ancestral angiosperm type of plastid chromosomes, due to an inversion in the large single-copy region. The gene codes for a polypeptide of 475 amino acid residues corresponding to a molecular mass of 52.7 kd. The deduced amino acid composition diverges by 4.8% from the amino acid sequence of the spinach protein and by 8.2% from that of maize. The corresponding nucleotide sequences differ by 8.5 % and 15 % from each other. The rbcL gene of the RuBPcase/oase-deficient Oenothera plastome mutant sigma contains a TTAAC deletion at amino acid residues 270/271 which introduces a frame shift and an amber stop codon seven triplets later. This lesion which probably arose by slipped mispairing is consistent with the previously observed, virtually full-length mRNA that is decoded into a truncated large subunit polypeptide of approximately 30 kd in vitro and in vivo.