Proteome analysis of chloroplast mRNA processing and degradation

Chloroplasts have a complex enzymatic machinery to adjust the relative half-life of their mRNAs to environmental signals. Soluble protein extracts from spinach (Spinacia oleracea L.) chloroplasts that correctly reproduce in vitro the differential mRNA stability observed in vivo were analyzed using shotgun proteomics to identify the proteins that are potentially involved in this process. The combination of a novel strategy for the database-independent detection of proteins from MS/MS data with standard database searches allowed us to identify 243 proteins with high confidence, which include several nucleases and RNA binding proteins but also proteins that have no reported function in chloroplast mRNA metabolism. Characterization of enzyme activities that adjust mRNA stability in response to illumination revealed that the dark-induced RNA degradation pathway involves enzymatic activities that differ from those that direct RNA processing and stabilization in the light. Dark-induced mRNA degradation comprises a MgCl2-independent and a MgCl2-dependent step, which releases nucleoside di- and monophosphates from the petD 3'-UTR precursor substrate. RNA degradation can be blocked with RNasin, a potent inhibitor of eukaryotic ribonucleases, suggesting that chloroplast mRNA degradation involves enzymes that are distinct from those found in prokaryotic-type RNA degradation. On the basis of the identified proteins and the in vitro characterization of the RNA degradation activities, we discuss scenarios and components that potentially determine plastid mRNA stability.     

Endonucleolytic activation directs dark-induced chloroplast mRNA degradation

Plastid mRNA stability is tightly regulated by external signals such as light. We have investigated the biochemical mechanism responsible for the dark-induced decrease of relative half-lives for mRNAs encoding photosynthetic proteins. Protein fractions isolated from plastids of light-grown and dark-adapted plants correctly reproduced an RNA degradation pathway in the dark that is downregulated in the light. This dark-dependent pathway is initiated by endonucleolytic cleavages in the petD mRNA precursor substrate proximal to a region that can fold into a stem–loop structure. Polynucleotide phosphorylase (PNPase) polyadenylation activity was strongly increased in the protein fraction isolated from plastids in dark-adapted plants, but interestingly PNPase activity was not required for the initiation of dark-induced mRNA degradation. A protein factor present in the protein fraction from plastids of light-grown plants could inactivate the endonuclease activity and thereby stabilize the RNA substrate in the protein fraction from plastids of dark-adapted plants. The results show that plastid mRNA stability is effectively controlled by the regulation of a specific dark-induced RNA degradation pathway.     

Polyadenylation accelerates degradation of chloroplast mRNA.

The expression of chloroplast genes is regulated by several mechanisms, one of which is the modulation of RNA stability. To understand how this regulatory step is controlled during chloroplast development, we have begun to define the mechanism of plastid mRNA degradation. We show here that the degradation petD mRNA involves endonucleolytic cleavage at specific sites upstream of the 3' stem-loop structure. The endonucleolytic petD cleavage products can be polyadenylated in vitro, and similar polyadenylated RNA products are detectable in vivo. PCR analysis of the psbA and psaA-psaB-rps14 operons revealed other polyadenylated endonucleolytic cleavage products, indicating that poly(A) addition appears to be an integral modification during chloroplast mRNA degradation. Polyadenylation promotes efficient degradation of the cleaved petD RNAs by a 3'-5' exoribonuclease. Furthermore, polyadenylation also plays an important role in the degradation of the petD mRNA 3' end. Although the 3' end stem-loop is usually resistant to nucleases, adenylation renders the secondary structure susceptible to the 3'-5' exoribonuclease. Analysis of 3' ends confirms that polyadenylation occurs in vivo, and reveals that the extent of adenylation increases during the degradation of plastid mRNA in the dark. Based on these results, we propose a novel mechanism for polyadenylation in the regulation of plastid mRNA degradation.     

Half-lives of messenger RNA species during growth and differentiation of Dictyostelium discoideum

The half-lives of functional messenger RNAs were determined by a method employing the drugs actinomycin D and daunomycin for the inhibition of mRNA synthesis; the activity of extracted mRNAs was determined by an in vitro translation assay. Several controls indicated that this method yielded reliable values for mRNA half-lives; in particular, the declining rate of protein synthesis in the presence of the drugs is due predominantly to the decay of translatable mRNA. This method was used to determine the half-lives of two specific mRNAs—encoding actin and a protein of MW 51,000—as well as that of total cytoplasmic mRNA activity during growth and at several times in differentiation. The half-lives of at least these two mRNAs were shown to be distinctly different from that of the total mRNA population—about 4 hr. However, no significant change in any of these half-lives was observed between growing and developing cells. Therefore wholesale alterations in the degradation rates of total and at least specific messages do not appear to play a role in the regulation of gene expression during Dictyostelium development.     

Messenger RNA degradation in Saccharomyces cerevisiae

The analysis of 17 functional mRNAs and two recombinant mRNAs in the yeast Saccharomyces cerevisiae suggests that the length of an mRNA influences its half-life in this organism. The mRNAs are clearly divisible into two populations when their lengths and half-lives are compared. Differences in ribosome loading amongst the mRNAs cannot account for this division into relatively stable and unstable populations. Also, specific mRNAs seem to be destabilized to differing extents when their translation is disrupted by N-terminus-proximal stop codons. The analysis of a mutant mRNA, generated by the fusion of the yeast PYK1 and URA3 genes, suggests that a destabilizing element exists within the URA3 sequence. The presence of such elements within relatively unstable mRNAs might account for the division between the yeast mRNA populations. On the basis of these, and other previously published observations, a model is proposed for a general pathway of mRNA degradation in yeast. This model may be relevant to other eukaryotic systems. Also, only a minor extension to the model is required to explain how the stability of some eukaryotic mRNAs might be regulated.     

Effects of water stress on major photosystem II gene expression and protein metabolism in barley leaves

Although it has long been recognized that water deficit in plants reduces photosystem (PS) II mRNAs and proteins, the detailed mechanisms behind this have not been thoroughly elucidated. In the present study, effects of water stress in barley leaves on degradation of major PSII mRNA and dissociation and migration of PSII proteins were investigated. The results indicated that (1) the steady-state levels of major PSII mRNAs and proteins declined with increasing water stress, as a consequence of increased degradation; under severe water stress, the half-lives of D1 and D2 proteins decreased from 12–14 h to 7–8 h and the half-lives of psbA and psbD mRNA decreased from above 16 to 6–10 h; (2) monomerization of PSII were increased during water stress. Severe water stress accelerated turnover of PSII and inhibited PSII activities.     

Control of mRNA stability by the virion host shutoff function of herpes simplex virus

vhs1 is a mutant of herpes simplex virus type 1 that is defective in the virion host shutoff function responsible for the degradation of cellular mRNAs and the concomitant shutoff of host protein synthesis. In this study, the effect of the vhs1 mutation on the metabolism of viral mRNAs was examined by measuring the half-lives and patterns of accumulation of 10 different viral mRNAs representing all kinetic classes. The vhs1 mutation had the effect of dramatically lengthening the cytoplasmic half-lives of all 10 mRNAs. In wild-type virus infections, the 10 mRNAs had similar half-lives, suggesting that little, if any, target mRNA selectivity was exhibited by the vhs function. The vhs1 mutation caused overaccumulation of a number of mRNAs. The effect was most dramatic for the alpha (immediate-early) mRNA for ICP27 and the beta (early) mRNAs encoding thymidine kinase, ICP8, and DNA polymerase. Whereas in wild-type infections these mRNAs increased to peak levels and subsequently declined in abundance, in vhs1 infections they continued to accumulate until late times. A significant but less dramatic overaccumulation was observed for several beta-gamma (delayed-early) and gamma (late) mRNAs. The results suggest that the vhs protein plays an important role in determining the half-lives of viral mRNAs belonging to all kinetic classes and in so doing is important in the normal downregulation at late times of alpha and beta gene expression.     

Cloned DNA sequences that determine mRNA stability of bacteriophage phi X174 in vivo are functional.

The stability of two species of phi X174 polycistronic mRNA in vivo can be altered by mutating sequences existing immediately upstream of a termination site. The wild type phage contains an mRNA stabilizing sequence ((+) sequence), while the same sequence mutated by insertion ((-) sequence) reduces the stability of the mRNAs. These two sequences were cloned at the 3' ends of gene D or gene B of phi X174 in a pBR322 derivative plasmid. The cloned sequences were functional. The (+) sequence stabilized gene B or gene D mRNA; half-lives of these mRNAs were 7 to 8 min. When the (+) sequence is eliminated ((o) sequence) or replaced with the (-) sequence, the half-lives of the mRNA were reduced to about 1 to 2 min. The stabilization of mRNAs caused an increased production of these proteins.     

Poly(A), poly(A) binding protein and the regulation of mRNA stability

This review has focused on the possibility that interactions between mRNA sequences and the poly(A)-nucleoprotein complex play important roles in mRNA turnover. It is important to stress that additional genetic and biochemical tests are necessary to characterize how PABP interacts with mRNA in cells and to determine whether the poly(A) protection hypothesis is accurate. Moreover, there may be a significant number of mRNAs whose half-lives are independent of polyadenylation. For example, the stabilities of poly(A)-containing and deadenylated alpha 2u-globulin and interferon mRNAs are similar in microinjected oocytes. Thus, an important challenge in this field will be to analyse the complex and interactive factors that determine the half-lives of specific mRNAs.