Light-associated and processing-dependent protein binding to 5' regions of rbcL mRNA in the chloroplasts of a C4 plant.

In amaranth, a C(4) dicotyledonous plant, the plastid rbcL gene (encoding the large subunit of ribulose-1,5-bisphosphate carboxylase) is regulated post-transcriptionally during many developmental processes, including light-mediated development. To identify post-transcriptional regulators of rbcL expression, three types of analyses (polysome heel printing, gel retardation, and UV cross-linking) were utilized. These approaches revealed that multiple proteins interact with 5' regions of rbcL mRNA in light-grown, but not etiolated, amaranth plants. Light-associated binding of a 47-kDa protein (p47), observed by UV cross-linking, was highly specific for the rbcL 5' RNA. Binding of p47 occurred only with RNAs corresponding to mature processed rbcL transcripts (5'-untranslated region (UTR) terminating at -66); transcripts with longer 5'-UTRs did not associate with p47 in vitro. Variations in the length of the rbcL 5'-UTR were found to occur in vivo, and these different 5' termini may prevent or enhance light-associated p47 binding, possibly affecting rbcL expression as well. p47 binding correlates with light-dependent rbcL polysome association of the fully processed transcripts in photosynthetic leaves and cotyledons but not with cell-specific rbcL mRNA accumulation in bundle sheath and mesophyll chloroplasts.

A nuclear gene in maize required for the translation of the chloroplast atpB/E mRNA.

To elucidate mechanisms that regulate chloroplast translation in land plants, we sought nuclear mutations in maize that disrupt the translation of subsets of chloroplast mRNAs. Evidence is presented for a nuclear gene whose function is required for the translation of the chloroplast atpB/E mRNA. A mutation in atp1 results in a failure to accumulate the chloroplast ATP synthase complex due to reduced synthesis of the AtpB subunit. This decrease in AtpB synthesis does not result from a change in atpB mRNA structure or abundance. Instead, the atpB mRNA is associated with abnormally few ribosomes in atp1-1 mutants, indicating that atp1 function is required during translation initiation or early in elongation. Previously, only one nuclear gene that is required for the translation of specific chloroplast mRNAs had been identified in a land plant. Thus, atp1 will be a useful tool for dissecting mechanisms of translational control in chloroplasts.

Differential Synthesis of Photosystem Cores and Light-Harvesting Antenna during Proplastid to Chloroplast Development in Spirodela oligorrhiza.

Proplastids and etioplasts are common starting points for monitoring chloroplast development in higher plants. Although proplastids are the primary precursor of chloroplasts, most proplastid to chloroplast systems are cumbersome to study temporally. Conversely, the etioplast to chloroplast transition is initiated by light and is readily examined as a function of time. Etioplasts, however, are found mostly in plants germinated in the dark and are not an obligatory step in chloroplast development. We have chosen to study chloroplast ontogeny in Spirodela oligorrhiza (Kurtz) Hegelm (a C(3)-monocot) because of its unique ability to grow indefinitely in the dark. Ultrastructural, physiological, and molecular evidence is presented in support of a temporal, light-triggered proplastid to chloroplast transition in Spirodela. The dark-grown plants are devoid of chlorophyll, and upon illumination synchronously green over a 3- to 5-day period. Synthesis of chloroplast proteins involved in photosynthesis is coincident with thylakoid assembly, chlorophyll accumulation, and appearance of CO(2) fixation activity. Interestingly, the developmental sequence in Spirodela was slow enough to reveal that biosynthesis of the D1 photosystem II reaction center protein precedes biosynthesis of the major light-harvesting antenna proteins. This, coupled with the high chlorophyll a/b ratio observed early in development, indicated that reaction center assembly occurred prior to accumulation of the light-harvesting complexes. Thus, with Spirodela one can study proplastid to chloroplast conversions temporally in higher plants and follow the process on a time scale that enables a detailed dissection of plastid maturation processes.