Michael Tillich

Chloroplast ribonucleoprotein CP31A is required for editing and stability of specific chloroplast mRNAs

Chloroplast ribonucleoproteins (cpRNPs) are nuclear-encoded, highly abundant, and light-regulated RNA binding proteins. They have been shown to be involved in chloroplast RNA processing and stabilization in vitro and are phylogenetically related to the well-described heterogeneous nuclear ribonucleoproteins (hnRNPs). cpRNPs have been found associated with mRNAs present in chloroplasts and have been regarded as nonspecific stabilizers of chloroplast transcripts. Here, we demonstrate that null mutants of the cpRNP family member CP31A exhibit highly specific and diverse defects in chloroplast RNA metabolism. First, analysis of cp31a and cp31a/cp31b double mutants uncovers that these 2 paralogous genes participate nonredundantly in a combinatorial fashion in processing a subset of chloroplast editing sites in vivo. Second, a genome-wide analysis of chloroplast transcript accumulation in cp31a mutants detected a virtually complete loss of the chloroplast ndhF mRNA and lesser reductions for specific other mRNAs. Fluorescence analyses show that the activity of the NADH dehydrogenase complex, which also includes the NdhF subunit, is defective in cp31a mutants. This indicates that cpRNPs are important in vivo for calibrating the expression levels of specific chloroplast mRNAs and impact chloroplast physiology. Taken together, the specificity and combinatorial aspects of cpRNP functions uncovered suggest that these chloroplast proteins are functional equivalents of nucleocytosolic hnRNPs.

Complex chloroplast RNA metabolism: just debugging the genetic programme?

BackgroundThe gene expression system of chloroplasts is far more complex than that of their cyanobacterial progenitor. This gain in complexity affects in particular RNA metabolism, specifically the transcription and maturation of RNA. Mature chloroplast RNA is generated by a plethora of nuclear-encoded proteins acquired or recruited during plant evolution, comprising additional RNA polymerases and sigma factors, and sequence-specific RNA maturation factors promoting RNA splicing, editing, end formation and translatability. Despite years of intensive research, we still lack a comprehensive explanation for this complexity.ResultsWe inspected the available literature and genome databases for information on components of RNA metabolism in land plant chloroplasts. In particular, new inventions of chloroplast-specific mechanisms and the expansion of some gene/protein families detected in land plants lead us to suggest that the primary function of the additional nuclear-encoded components found in chloroplasts is the transgenomic suppression of point mutations, fixation of which occurred due to an enhanced genetic drift exhibited by chloroplast genomes. We further speculate that a fast evolution of transgenomic suppressors occurred after the water-to-land transition of plants.ConclusionOur inspections indicate that several chloroplast-specific mechanisms evolved in land plants to remedy point mutations that occurred after the water-to-land transition. Thus, the complexity of chloroplast gene expression evolved to guarantee the functionality of chloroplast genetic information and may not, with some exceptions, be involved in regulatory functions.

Arabidopsis Chloroplast RNA Binding Proteins CP31A and CP29A Associate with Large Transcript Pools and Confer Cold Stress Tolerance by Influencing Multiple Chloroplast RNA Processing Steps

This work examines the chloroplast ribonucleoproteins CP31A and CP29A by plastome-wide analysis of chloroplast RNA metabolism, finding that these proteins associate with a large set of chloroplast transcripts and are required for cold stress resistance, targeting multiple chloroplast mRNA processing steps. Chloroplast RNA metabolism is mediated by a multitude of nuclear encoded factors, many of which are highly specific for individual RNA processing events. In addition, a family of chloroplast ribonucleoproteins (cpRNPs) has been suspected to regulate larger sets of chloroplast transcripts. This together with their propensity for posttranslational modifications in response to external cues suggested a potential role of cpRNPs in the signal-dependent coregulation of chloroplast genes. We show here on a transcriptome-wide scale that the Arabidopsis thaliana cpRNPs CP31A and CP29A (for 31 kD and 29 kD chloroplast protein, respectively), associate with large, overlapping sets of chloroplast transcripts. We demonstrate that both proteins are essential for resistance of chloroplast development to cold stress. They are required to guarantee transcript stability of numerous mRNAs at low temperatures and under these conditions also support specific processing steps. Fine mapping of cpRNP–RNA interactions in vivo suggests multiple points of contact between these proteins and their RNA ligands. For CP31A, we demonstrate an essential function in stabilizing sense and antisense transcripts that span the border of the small single copy region and the inverted repeat of the chloroplast genome. CP31A associates with the common 3′-terminus of these RNAs and protects them against 3′-exonucleolytic activity.

Heterologous, splicing‐dependent RNA editing in chloroplasts: allotetraploidy provides trans‐factors

RNA editing is unique among post‐transcriptional processes in plastids, as it exhibits extraordinary phylogenetic dynamics leading to species‐specific editing site patterns. The evolutionary loss of a site is considered to entail the loss of the corresponding nuclear‐encoded site‐specific factor, which prevents the editing of foreign, i.e. heterologous, sites. We investigated the editing of short ‘spliced’ and ‘unspliced’ ndhA gene fragments from spinach in Nicotiana tabacum (tobacco) in vivo using biolistic transformation. Surprisingly, it turned out that the spinach site is edited in the heterologous nuclear background. Furthermore, only exon–exon fusions were edited, whereas intron‐containing messages remained unprocessed. A homologue of the spinach site was found to be present and edited in Nicotiana tomentosiformis, representing the paternal parent, but absent from Nicotiana sylvestris, representing the maternal parent of tobacco. Our data show that: (i) the cis‐determinants for ndhA editing are split by an intron; (ii) the editing capacity cannot be deduced from editing sites; and (iii) allopolyploidization can increase the editing capacity, which implies that it can influence speciation processes in evolution.

Chloroplast RNA-binding proteins: Repair and regulation of chloroplast transcripts

Chloroplast RNA metabolism has greatly diverged from the cyanobacterial ancestral state. The number of processing sites per transcript has increased and novel processing steps not found in bacteria have been acquired. Whereas many of the processing steps are essential for chloroplast development, it is unclear why such steps evolved at all. In this article, two hypotheses seeking to explain the complexity of chloroplast RNA metabolism are explored: the genomic debugging hypothesis and the nuclear regulation hypothesis. The nuclear-encoded RNA processing factors underlying these two alternative, but not mutually exclusive, hypotheses have very different characteristics. We propose that pentatricopeptide repeat (PPR) proteins, with high sequence specificity and essential roles in various RNA-processing steps, act largely as genomic debuggers. By contrast, the chloroplast ribonucleoproteins (cpRNP), which are strongly modulated by external and internal stimuli, are suggested to be major players in transducing signals to the chloroplast transcript pool.

Loss of matK RNA editing in seed plant chloroplasts

BackgroundRNA editing in chloroplasts of angiosperms proceeds by C-to-U conversions at specific sites. Nuclear-encoded factors are required for the recognition of cis-elements located immediately upstream of editing sites. The ensemble of editing sites in a chloroplast genome differs widely between species, and editing sites are thought to evolve rapidly. However, large-scale analyses of the evolution of individual editing sites have not yet been undertaken.ResultsHere, we analyzed the evolution of two chloroplast editing sites, matK-2 and matK-3, for which DNA sequences from thousands of angiosperm species are available. Both sites are found in most major taxa, including deep-branching families such as the nymphaeaceae. However, 36 isolated taxa scattered across the entire tree lack a C at one of the two matK editing sites. Tests of several exemplary species from this in silico analysis of matK processing unexpectedly revealed that one of the two sites remain unedited in almost half of all species examined. A comparison of sequences between editors and non-editors showed that specific nucleotides co-evolve with the C at the matK editing sites, suggesting that these nucleotides are critical for editing-site recognition.Conclusion(i) Both matK editing sites were present in the common ancestor of all angiosperms and have been independently lost multiple times during angiosperm evolution.(ii) The editing activities corresponding to matK-2 and matK-3 are unstable.(iii) A small number of third-codon positions in the vicinity of editing sites are selectively constrained independent of the presence of the editing site, most likely because of interacting RNA-binding proteins.

Maintenance of plastid RNA editing activities independently of their target sites

RNA editing in plant organelles is mediated by site‐specific, nuclear‐encoded factors. Previous data suggested that the maintenance of these factors depends on the presence of their rapidly evolving cognate sites. The surprising ability of allotetraploid Nicotiana tabacum (tobacco) to edit a foreign site in the chloroplast ndhA messenger RNA was thought to be inherited from its diploid male ancestor, Nicotiana tomentosiformis. Here, we show that the same ndhA editing activity is also present in Nicotiana sylvestris, which is the female diploid progenitor of tobacco and which lacks the ndhA site. Hence, heterologous editing is not simply a result of tobaccos allopolyploid genome organization. Analyses of other editing sites after sexual or somatic transfer between land plants showed that heterologous editing occurs at a surprisingly high frequency. This suggests that the corresponding editing activities are conserved despite the absence of their target sites, potentially because they serve other functions in the plant cell.

The ins and outs of editing and splicing of plastid RNAs: lessons from parasitic plants

In chloroplasts of higher plants, editing and splicing of transcripts is a prerequisite for the proper expression of the plastid genetic information and thereby for photosynthesis. Holoparasitic plants differ from photosynthetic plants in that they have abandoned a photoautotrophic life style, which has led to a reduction or loss of photosynthetic activity. The analysis of several parasitic plant plastid genomes revealed that coding capacities were reduced to different extent, encompassing genes that regulate plastid gene expression as well as photosynthesis genes. The reorganization of the plastid genome is also reflected in overall increases in point mutation rates that parallel the vanishing of RNA editing sites. Unprecedented in land plants is the parallel loss of the plastid gene coding for an intron maturase and all but one group IIa introns in two parasitic species. These observations highlight the plastome-wide effects that are associated with a relaxed evolutionary pressure in plants living a heterotrophic life style.