Polyadenylation and Degradation of mRNA in the Chloroplast

doi:10.1104/pp.120.4.937

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Polyadenylation and Degradation of mRNA in the Chloroplast¹

Gadi Schuster^*, Irena Lisitsky, and Petra Klaff

Department of Biology, Technion-Israel Institute of Technology, Haifa 32000, Israel (G.S., I.L.); and Heinrich-Heine-Universitat Düsseldorf, Institute für Physikalische Biologie, Universitatsstrasse 1, D-40225 Düsseldorf, Germany (P.K.)

INTRODUCTION

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Introduction
References

Chloroplast development is characterized by the synthesis and assembly of the photosynthetic complexes of the thylakoid membranes.This maturation process requires the coordinated expression ofmany nuclear- and chloroplast-encoded genes. As chloroplasts aresemiautonomous organelles, they possess their own genome withits inherent transcriptional and translational machinery. However,nuclear-encoded gene products are also necessary for all of theprocesses occurring in the chloroplast. In this Update we willfocus on the control of chloroplast gene expression at the posttranscriptionstage. Posttranscriptional processes are widely used in controllingthe steady-state levels of plastid mRNAs, and are mediated mainlyby nuclear-encoded proteins, suggesting a way in which the nucleuscan modulate gene expression in the chloroplast. For example,mutants of nuclear-encoded genes affecting the accumulation ofspecific chloroplast transcripts have been described in maize,Arabidopsis, and the green algae Chlamydomonas reinhardtii (Goldschmidt-Clermont,1998).

mRNAs of higher plant and green algae chloroplasts are transcribed as precursor RNAs that undergo a variety of maturationevents, including cis- and trans-splicing, cleavage of polycistronicmessages, processing of 5 $'$ and 3 $'$ ends, and RNA editing (Fig.1). A general feature of plastid protein-encoding genes is thepresence of inverted repeat sequences in the 3 $'$ -UTR, which forma stem-loop secondary structure when transcribed to RNA. The 3 $'$ end of mature chloroplast mRNAs is located several nucleotides3 $'$ to this stem-loop structure (Fig. 1). Contrary to similar structuresfound in bacterial mRNA, these elements do not function as transcriptionalterminators in chloroplasts; instead, they serve as RNA-processingelements capable of stabilizing upstream RNA fragments in vivoand in vitro (Barkan and Stern, 1998).

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Figure 1. A, RNA metabolism in the chloroplast. Schematic representation of a monocistronic transcription unit in the chloroplast. UTRs are marked with a thin black line; sequences that code for amino acids with a thick black line; and introns with a thick white line. The inverted repeats characterizing the 3 $'$ -UTR are symbolized by two arrowheads. A tRNA gene usually presenting 3 $'$ to the inverted repeats is shown as a dashed line. B, The precursor RNA transcribed from this transcription unit undergoes 5 $'$ - and 3 $'$ -end processing to generate the 5 $'$ and 3 $'$ ends of the mRNA, respectively. C, The 3 $'$ end is located several nucleotides 3 $'$ of the stem-loop structure formed by the inverted-repeats sequence. The introns are removed by splicing, and the tRNA gene is processed by RNaseP. The mRNA is then translated and later degraded.

Different aspects of chloroplast mRNA processing and stability have been the subject of recently published reviews (Barkanand Stern, 1998; Drager and Stern, 1998; Goldschmidt-Clermont,1998; Nickelsen, 1998) and will not be discussed here. We willfocus on recent discoveries concerning the molecular mechanismof mRNA polyadenylation and degradation in the chloroplast, andthe proteins involved.

	HOW CAN mRNA DEGRADATION CONTROL GENE EXPRESSION DURING CHLOROPLAST DEVELOPMENT?

During leaf development and plastid differentiation, the levels of many plastid mRNAs vary dramatically. The concentrationof a specific mRNA is determined by its transcription rate incomparison with its degradation rate. Run-on experiments revealingrelative rates of RNA synthesis showed that the different mRNAsteady-state levels cannot be related to gene-specific transcriptionalactivity (Gruissem, 1989). Therefore, changes in the degradationrate of specific mRNAs during chloroplast development occur. Tostudy the degradation of mRNAs in the chloroplast of higher plantsin vivo, spinach and barley plants were treated with transcriptioninhibitors. The rate of decay of chloroplast-encoded mRNAs wasdetermined by quantitative northern analysis using gene-specificprobes. The half-life of several chloroplast mRNAs, such as psbA,changed during development from young to mature leaves, whereasthat of others, such as rbcL, did not.

These results showed that differential mRNA stability contributes to chloroplast mRNA concentrations during leaf development(Klaff and Gruissem, 1991; Kim et al., 1993). Analysis of thetranscription, translation, and mRNA levels of 15 plastid genesduring barley chloroplast development revealed a dynamic modulationof gene expression and mRNA stability (Rapp et al., 1992). Furthermore,enhanced levels of psbA mRNA in mature barley chloroplasts weredue primarily to its selective stabilization. Although data aboutthe RNA elements and the proteins involved in this process areslowly emerging (see below), the precise mechanism by which thestability of a specific chloroplast mRNA changes during plantdevelopment and in response to physiological changes (such aslight intensity or quality) is still not understood.

	cis-REGULATORY ELEMENTS CONFERRING STABILITY AND/OR INSTABILITY OF CHLOROPLAST mRNAs

A central issue for understanding the regulation of mRNA stability is the identification of cis-regulatory elements. Theseelements are defined by their ability to transfer properties ofa certain mRNA to a reporter gene. In general, this is achievedby constructing chimeric genes consisting of the respective RNAelement and a reporter gene, such as the Escherichia coli GUSgene, and transforming these constructs into a recipient organism.Chloroplasts of the green algae C. reinhardtii have been routinelytransformed, and, recently, techniques for higher plant chloroplasttransformation have become available. Nevertheless, most informationon cis-regulatory elements in chloroplasts is still derived fromC. reinhardtii. In addition, a wide variety of nuclear mutantsaffecting mRNA stability have been described for C. reinhardtiiand higher plants, providing an additional genetic tool for understandingmRNA-degradation pathways (for review, see Goldschmidt-Clermont,1998).

A well-characterized example of an impaired mRNA metabolism in C. reinhardtii is the nuclear mutation nac2-26, which resultsin the decreased stability of psbD mRNA. Fusing the 5 $'$ -UTR ofthe psbD mRNA to aadA (aminoglycoside adenyltransferase) as areporter gene showed a destabilized chimeric transcript in themutant background and normal accumulation in the wild type, reflectingthe properties of the psbD mRNA. These data indicate that the5 $'$ -UTR of the mRNA includes a determinant for psbD mRNA degradation.Instability of the psbD mRNA in the mutant correlates with a 47-kDprotein binding to the psbD leader that is present in wild-typeC. reinhardtii chloroplasts but not in nac2-26 cells, making thisprotein a candidate for a gene-specific, nuclear-encoded, trans-actingfactor that stabilizes the mRNA (Nickelsen et al., 1994).

A more complex mechanism for the regulation of mRNA stability has been proposed for the C. reinhardtii petD mRNA. Extensivemutational analysis and experiments using reporter constructsrevealed that sequences within the 5 $'$ -UTR are essential for translationand affect RNA stability. In all mutants in which translationwas compromised, petD mRNA accumulated to a lower level than inwild-type strains, indicating that mRNA stability is not onlyregulated by RNA-binding proteins but may also be linked to translatability(Sakamoto et al., 1994). The role of nuclear-encoded factors forpetD mRNA stability was confirmed by F16, a nuclear mutant harboringthe mutation mcd1-1, which failed to accumulate petD mRNA. Theanalysis of this mutant suggested that the mcd1-1 gene productis involved in protein binding the 5 $'$ -UTR to prevent digestionof the mRNA by a 5 $'$ to 3 $'$ exonuclease (Drager et al., 1998).

In chloroplasts of higher plants information on cis-regulatory elements for mRNA stability has been obtained from mutationalstudies and from the recent construction of transplastomic tobaccoplants. Similar to the situation in C. reinhardtii, no generalscheme emerged, but several parameters contributing to the stabilityof a certain mRNA were observed. Nuclear mutants in which manychloroplast mRNAs were associated with abnormally few ribosomesshowed that the level of rbcL mRNA was reduced 4-fold, indicatingthat the rbcL mRNA is destabilized as a consequence of its decreasedpolysome association (Barkan, 1993). For the same mRNA, the analysisof constructs consisting of the 5 $'$ -UTR fused to a reporter geneshowed that mRNA accumulation in the dark is mediated by thisregion, whereas a leaderless molecule cannot be detected. Thatstudy also provided evidence that rbcL mRNA stability is regulatedvia the 5 $'$ -UTR (Shiina et al., 1998).

In addition to the 5 $'$ -UTR and its role in mRNA accumulation in chloroplasts, the 3 $'$ -UTR is also remarkably important. As describedabove, most chloroplast mRNAs are flanked by a stem-loop structure3 $'$ of their coding region that takes part in the mature 3 $'$ -endprocessing (for review, see Barkan and Stern, 1998). In addition,these elements are important for impeding the progress of processiveexoribonucleases, which can be shown in vitro using a solubleextract from higher plant chloroplasts, and of synthetic RNA fragmentsas the substrates (Barkan and Stern, 1998; Drager and Stern, 1998).Partial or complete in vivo deletion of the atpB gene stem-loopin transformed C. reinhardtii chloroplasts led to a dramatic decreasein the accumulation of 3 $'$ -end-processed mRNA, whereas the transcriptionrate of this gene remained unaffected. This result indicated thatthe stem-loop structure is required for the correct 3 $'$ -end processingand mRNA accumulation (for review, see Barkan and Stern, 1998;Drager and Stern, 1998).

The stem-loop structure can be replaced in vivo by a stretch of 18 guanosines, which also serves as a barrier for a 3 $'$ to5 $'$ exonuclease in vitro. The correct 3 $'$ -end processing of themRNA mediated by the structural element is nevertheless essential,since it is required for, or strongly stimulates, its translationin C. reinhardtii chloroplasts (Rott et al., 1998).

The results summarized in this section suggest that cis elements responsible for the modulation of mRNA stability of specificgenes are mainly localized in the 5 $'$ -UTR. On the other hand, RNAstructural elements located in the 3 $'$ -UTR are required for correctprocessing and are therefore necessary for mRNA stability. Wedescribe below the search for the molecular mechanism of mRNAdegradation and the proteins involved.

	WHICH ARE THE RNA DEGRADATION ENZYMES IN THE CHLOROPLAST?

The in vitro RNA processing and degradation system, in which a synthetic RNA is processed or degraded when incubated withsoluble chloroplast extract, was utilized to isolate the enzymesinvolved. The proteins were fractionated using conventional biochemicalseparation methods, and the purified fractions were analyzed foractivity until one or more polypeptides were present. The searchfor the RNase involved in the 3 $'$ -end processing of chloroplastmRNAs yielded 100RNP (100-kD RNA-binding protein; Hayes et al.,1996). Purified 100RNP has biochemical properties similar to PNPase,one of the two exonucleases discovered to date in bacterial cells.Furthermore, the deduced amino acid sequence of the chloroplast100RNP cDNA was highly homologous to the bacterial PNPase. Doesthis result imply that the chloroplast RNA processing and degradationsystem is similar to recently discovered mechanisms in E. coli?(Nierlich and Murakawa, 1996; Carpousis et al., 1999). Togetherwith the discoveries about the mechanisms of mRNA polyadenylationand degradation, which we will describe later, the answer to thisquestion appears to be yes. Nevertheless, unlike bacteria, plastidmRNA metabolism and its associated enzymes are controlled by thenucleus and may be regulated by light or by the redox state ofthe chloroplast (Hayes et al., 1996).

	IS THERE A CHLOROPLAST DEGRADOSOME SIMILAR TO BACTERIA?

The E. coli RNA degradosome is a multienzyme complex consisting of the exoribonuclease PNPase, the endonuclease RNase E, aDEAD-box ATP-dependent RNA-helicase, and the enzyme enolase (Carpousiset al., 1999). This high-molecular-mass protein complex is importantin RNA processing and mRNA degradation in the bacterial cell,since two of its components, PNPase and RNase E, have been shownto be key elements in these processes. The chloroplast 100RNP/PNPasewas isolated in a high-molecular-mass complex of about 600 kD.A 67-kD protein cross-reacting with antibodies prepared againstRNase E of E. coli and displaying endoribonuclease activity wascopurified with that complex (Hayes et al., 1996). Therefore,it is tempting to suggest that a complex similar to the bacterialdegradosome exists in the chloroplast, preserving its ancestralprokaryotic origin (Carpousis et al., 1999).

In both bacteria and chloroplasts, it appears that not all of the PNPase population is associated with the degradosome (Carpousiset al., 1994; Lisitsky et al., 1997b). The question of whetherdifferent forms of the 100RNP/PNPase are involved in each RNAmetabolic activity, such as 3 $'$ -end processing and degradation,therefore, remains open. In vitro experiments using syntheticRNAs and purified 100RNP/PNPase have shown much higher enzymeactivity on polyadenylated RNA (see below). This selectivity topolyadenylated RNA resulted from the high-affinity binding ofthe 100RNP/PNPase to poly(A) sequences (Lisitsky et al., 1997b).It is interesting that a similar function and mode of action haverecently been reported for the E. coli PNPase and for anotherexoribonuclease, RNase II (Coburn and Mackie, 1996; Lisitsky andSchuster, 1999). Therefore, identification, isolation, and characterizationof the other chloroplast exoribonucleases will determine whetherthe preference for poly(A)-rich RNAs is only intrinsic to the100RNP/PNPase, or if it is shared by several or all of the chloroplastexonucleases. In addition, a protein complex composed of severalRNA-degradation enzymes was recently identified and isolated inyeast, and was named the exosome (Mitchel et al., 1997; Jacobset al., 1998). Are the bacterial degradosome, the chloroplastdegradosome, and the yeast cytoplasm exosome related to each otherfunctionally and/or evolutionarily? This interesting questionis now under intensive study.

	POLYADENYLATION OF mRNA IN EUKARYOTIC CELLS

Posttranscriptional addition of a poly(A) tail to the 3 $'$ end of mRNA was first identified and characterized in eukaryoticcells for viral and nuclear-encoded mRNAs. In these cells thepoly(A) tails are formed by the addition of about 250 adenylateresidues to a 3 $'$ end generated by endonucleolytic cleavage ofthe precursor RNA. A complex assembly of proteins is required,along with the activity of poly(A) polymerase. The result of thisprocess is that most of the mRNA molecules are polyadenylated(Wahle and Keller, 1996).

What is the function of the poly(A) tail? Many studies have revealed that the long poly(A) tail of eukaryotic nuclear-encodedmRNAs is an important determinant of their maturation and initiationof translation. When referring to maturation, we include the transferof the precursor RNA from the nucleus to the cytoplasm and thedetermination of stability. In yeast, deadenylation is a majorstep in the degradation pathway of nuclear-encoded mRNAs. Thepoly(A) tail and the protein that bound to it were found to bevery important for the initiation of the translation process.How can the poly(A) located in the 3 $'$ end of the RNA moleculecontrol the translation starting at the 5 $'$ end? A model invokingmRNA circularization has been proposed whereby the mRNA 5 $'$ and3 $'$ ends can interact with each other. In this way, the poly(A)-bindingprotein that is associated with the poly(A) tail stimulates thebinding of the 40S ribosomal subunit to mRNA by associating withthe translation initiation factor eIF4G, which also binds to eIF4Eand the 5 $'$ cap of mRNA. The circularization of the mRNA in thisway is required for the initiation of translation (Sachs et al.,1997).

	IS mRNA POLYADENYLATED IN PROKARYOTE CELLS?

For a long time, polyadenylation was believed to be exclusively associated with eukaryotic mRNAs. Other RNAs, such as rRNAs,tRNAs, and RNAs in prokaryotes, were believed not to be polyadenylated.Most of these RNA molecules do not have a poly(A) tail in their3 $'$ end. Nevertheless, poly(A) tails have recently been detectedin bacteria (Sarkar, 1997). The polyadenylated RNA accounts foronly a tiny fraction of the population of the same RNA in thecell. This fraction increases severalfold in mutant bacteria cellsthat lack exoribonuclease(s) activity. On the other hand, in mutantsin which RNA polyadenylation was inhibited due to the lack ofpoly(A) polymerase enzymes, the half-life of the RNA moleculesdramatically increased.

What do these results suggest? They imply that, unlike the nucleus and cytoplasm of eukaryotic cells, where the poly(A) tailis important for the stability, maturation, and translation ofmRNA and the deadenylation of the long poly(A) tail in part ofthe mRNA degradation pathway, the addition of poly(A) tails inbacterial mRNAs promotes their degradation. Taken together, polyadenylationof RNA molecules in bacteria cells is a part of the molecularmechanism of RNA degradation in bacteria. Is polyadenylation requiredfor RNA degradation, or is there an additional nonpolyadenylated-dependentdegradation pathway in the cell? Is the polyadenylation-dependentdegradation pathway specific to certain types of RNA moleculessuch as mRNA? What is the sequence of events in this RNA-degradationpathway and what is the rate-limiting step? These questions arenow under intensive investigation (Blum et al., 1999).

	IS RNA POLYADENYLATED IN THE CHLOROPLAST?

Chloroplasts evolved from free-living prokaryotes that were introduced into eukaryotic cells in an endosymbiotic event(s).Many characteristics of the gene expression machinery of the chloroplastresemble those of the bacteria. However, some characteristicsof the gene expression apparatus in the chloroplast are similarto the eukaryotic system. For example, chloroplast genes are usuallyinterrupted with introns that have not been found in bacteria.The question then arose, does RNA polyadenylation occur in thechloroplast? Is it similar to the eukaryotic nuclear-encoded genes,such as bacteria, or is it a unique feature?

It is interesting to note that poly(A) RNA was detected in the chloroplast more than 20 years ago (Haff and Bogorad, 1976).Using hybridization experiments with ctDNA and ¹²⁵I-labeled RNA from maize seedlings, it was determined that about6% of the poly(A)-containing RNA hybridized to ctDNA, and thatthe chloroplast poly(A) tracts averaged about 45 nucleotides inlength. Nevertheless, like the situation in the polyadenylationof bacterial RNA, polyadenylation has long been regarded as afeature of eukaryotic nuclear and viral mRNAs. However, polyadenylationof prokaryotic and organellar mRNAs has recently returned as thefocus of research as part of the mRNA degradation mechanism.

To detect polyadenylated RNA in the chloroplast, the powerful method of RT-PCR was used. RNA was isolated from purified chloroplastsand oligo(dT)-primed cDNA was synthesized from the polyadenylatedRNA molecules. The cDNA corresponding to a specific gene was PCRamplified using a gene-specific primer on one side and a (dT)_ntail on the other (Kudla et al., 1996; Lisitsky et al., 1996).Analyzing the nucleotide sequences of the poly(A) tails of chloroplastRNAs revealed several interesting features. First, compared withpoly(A) tails in bacteria and yeast, the chloroplast poly(A) tailsare very long. Several tails of 270 nucleotides were detected,compared with only 40 to 60 nucleotides in bacteria and yeast.Second, unlike eukaryotic nuclear-encoded and bacterial RNAs,the poly(A) moiety in the chloroplast was not found to be a ribohomopolymerof adenosine residues, but rather was composed of clusters ofadenosines mostly bound by guanosines, and, on rare occasions,by cytidines and uridines. A chloroplast poly(A)-rich tail usuallycontains 70% adenosines, 25% guanosines, and 5% cytidines anduridines, making them purine-rich sequences (Lisitsky et al.,1996). Why are the poly(A) tails heterologous in the chloroplastbut not in nuclear-encoded or bacteria RNA? Is there a biologicalfunction for this heterogeneity, or does it just reflect lessspecificity of the chloroplast poly(A) polymerase enzyme? Currently,we do not know the answers to these questions. Other nucleotidesin addition to adenosine were recently found in RNA isolated fromE. coli cells under stationary growth conditions (Cao and Sarkar,1997). The third phenomenon is related to the location of thepolyadenylation sites in the RNA molecule and will be discussedbelow. Two possibilities for the formation of polyadenylated sitesare truncated transcription termination and cleavage of mature,full-length RNA.

Most of the polyadenylation sites that were found by RT-PCR of oligo(dT)-primed chloroplast RNA were localized within theamino acid-coding region of the mRNA. RT-PCR clones of mRNA polyadenylatedat the 3 $'$ end were also obtained, but were at least 50 times lowerin frequency (Lisitsky et al., 1996). This result indicated thatmost truncated mRNAs are polyadenylated. How did the truncatedRNA molecules undergoing the addition of poly(A)-rich tails originate?The truncation may originate from either early transcription terminationor cleavage of a full-length transcript.

Two observations suggest that in vivo polyadenylation occurs subsequent to the cleavage of an mRNA as part of the specificdegradation pathway. First, five of the polyadenylation sitesmapped by RT-PCR in spinach psbA mRNA perfectly matched endonucleolyticcleavage sites that were mapped by a primer extension in the lysedchloroplast mRNA-degradation system (Fig. 2) (Lisitsky et al.,1996). Since mapping the endonucleolytic cleavage site by primerextension marks the first nucleotide at the 5 $'$ end of the distalcleavage product, and the poly(A) tail is added to the 3 $'$ endof the proximal product, the nucleotide labeled by primer extensionwas the adjusted nucleotide 3 $'$ to the polyadenylated one (Fig.2). Second, polyadenylation sites located in the 3 $'$ -UTR of thepetD mRNA determined by RT-PCR were mapped to the positions observedas cleavage sites of the purified endoribonuclease p67 on synthetictranscribed RNA corresponding to the petD 3 $'$ -UTR (Kudla et al.,1996). These results strongly suggest that most of the polyadenylatedmRNAs result from endonucleolytic cleavage of full-length transcripts.Nevertheless, the possibility cannot be ruled out that some ofthe polyadenylated RNA molecules in the chloroplast are the resultof polyadenylation of truncated transcribed molecules. These moleculesmust immediately enter the degradation pathway, because otherwisethey might serve as the templates for the translation of truncated,defective proteins. Full-length polyadenylated transcripts werealso detected, albeit in very small amounts relative to the nonpolyadenylatedor truncated polyadenylated transcripts.

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Figure 2. Experimental design used to analyze polyadenylation of endonucleolytically cleaved mRNA. The mRNA 3 $'$ - and 5 $'$ -UTRs are symbolized by thin lines and the coding region by a thick black line. RT-PCR of purified chloroplast RNA using the primers p1 and p2 revealed clones whereby the poly(A)-rich sequences were added to the last 3 $'$ nucleotide of the proximal cleavage product (N1). The 5 $'$ nucleotide of the distal cleavage product (N2) was determined by primer extension analysis (using the primer p3) of endonucleolytically cleaved RNA in the lysed chloroplast mRNA degradation system (see text). N2 was found to be one nucleotide 3 $'$ to N1. Therefore, polyadenylation occurs at the 3 $'$ end of the proximal endonucleolytic cleavage product.

	IS POLYADENYLATION REQUIRED FOR CHLOROPLAST mRNA DEGRADATION?

The question of whether polyadenylation is required for mRNA degradation, or whether other decay pathways also exist for chloroplastmRNAs, was approached via studies using the lysed-chloroplastsystem and the polyadenylation inhibitor 3 $'$ -dATP (cordycepin triphosphate).Blocking the polyadenylation of RNA inhibits RNA degradation andhas similar, if not identical, effects as the direct blockingof the exonucleases by the addition of excess yeast tRNA (Fig.3) (Lisitsky et al., 1997a). In both treatments the full-lengthmRNA was endonucleolytically cleaved to distinct degradation productsthat accumulated instead of being exonucleolytically degraded.Therefore, the addition of poly(A)-rich sequences to the endonucleolyticcleavage products of mRNA is required to target these moleculesfor rapid exonucleolytic degradation in the chloroplast. A systemthat degrades mRNA without the addition of poly(A)-rich sequencesto the endonucleolytic cleavage product either does not existor was inactive under this experimental system.

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Figure 3. Similar inhibition of mRNA degradation by blocking polyadenylation and inhibiting the exoribonucleases. Lysed chloroplasts were incubated for 0 or 60 min in the presence or absence ( $-$ ) of 2 mM 3 $'$ -dATP (cordycepin triphosphate) or 0.5 mg/mL yeast tRNA (tRNA), as specified in the figure. RNA was extracted from equal amounts of lysed chloroplasts and analyzed by an RNA gel blot that was hybridized with a psbA-specific probe. The migration of DNA size markers is indicated on the left as the number of nucleotides (nt).

	THE BIOCHEMISTRY OF POLYADENYLATION IS ELUCIDATED USING AN IN VITRO SYSTEM

An in vitro polyadenylation system was used to elucidate the biochemistry of mRNA polyadenylation and degradation activities,to isolate the proteins involved, and to reconstitute their activities.In vitro-transcribed RNAs corresponding to the chloroplast RNAscould be polyadenylated at their 3 $'$ end using a soluble chloroplastprotein extract complemented by the addition of ATP (Lisitskyet al., 1996). In vitro analysis of chloroplast polyadenylationactivity revealed specificity to ATP and GTP, reflecting the compositionof the poly(A)-rich tails observed by RT-PCR described above.In this respect, it is interesting to note that poly(A)- and poly(G)-polymeraseactivities were purified from wheat chloroplasts 25 years ago(Burkard and Keller, 1974). Furthermore, in vitro polyadenylationactivity is dependent on the substrate structure. UnstructuredRNAs were polyadenylated in a highly efficient manner comparedwith those molecules forming the stem-loop structure characteristicof the mature plastid mRNA 3 $'$ end (Lisitsky et al., 1996). Again,this observation is in agreement with the RT-PCR clones obtained,where polyadenylated RNA molecules at the mature 3 $'$ end (characterizedby a stem-loop structure) were found 50 less times than thoseat the middle of the RNA molecule.

	CAN THE POLYADENYLATED-DEPENDENT DEGRADATION OF CHLOROPLAST RNA BE MIMICKED IN VITRO?

RNA can be synthesized in a test tube using a DNA template of the corresponding nucleotide sequence of the interested geneand an RNA polymerase from a bacteriophage. RNA degradation bychloroplast proteins can be followed by incubating a chloroplastsoluble protein extract harboring the ribonucleases, as well asthe other RNA-binding proteins and components of this process,together with a radioactive-labeled synthetic RNA. In vitro-transcribed,synthetic polyadenylated RNA was rapidly degraded compared withthe same nonpolyadenylated RNA incubated in a soluble chloroplastprotein extract. Competition experiments revealed that polyadenylatedRNA molecules are more efficient competitors for the degradationmachinery than nonpolyadenylated molecules. These results suggestthat poly(A)-rich tails play a major role in the rapid degradationof intermediate products of mRNA decay in the chloroplast by targetingthe cleavage products for rapid degradation, due to their highaffinity to chloroplast exonuclease(s) (Kudla et al., 1996; Lisitskyet al., 1996, 1997b). A possible scenario for the situation inthe chloroplast is that the relative concentration of the exonucleasesis such that they are all occupied in degrading polyadenylatedendonucleolytic cleavage products. In this scenario, only polyadenylatedRNA molecules will be degraded, as was described above for theexperiments using polyadenylation inhibition in the lysed chloroplastsystem.

	WHAT IS THE BIOCHEMICAL MECHANISM OF PREFERENTIAL DEGRADATION OF POLYADENYLATED RNA?

The 100RNP/PNPase discussed above, similar to the bacterial PNPase, is a processive exoribonuclease binding to the 3 $'$ end,digesting the RNA nucleotide by nucleotide without dissociatingfrom the molecule. As described above, this protein could be obtainedas a purified single polypeptide. Therefore, it was possible todetermine whether the purified enzyme would retain the preferentialdegradation activity to polyadenylated RNA observed with the chloroplastprotein extract. The other possibility was that other auxiliaryproteins are required. In competition experiments using isolated,purified 100RNP/PNPase, the polyadenylated RNA competed with thenonpolyadenylated RNA for the exonuclease, as shown for the solubleprotein extract (Lisitsky et al., 1997b).

The results implied that competition for polyadenylated RNA is an intrinsic phenomenon of the enzyme as one polypeptide. Therefore,competition for polyadenylated RNA does not depend on the associationwith the multiprotein complex, the degradosome described above.Is the enzyme's preferred activity to polyadenylated RNA due tothe higher binding activity of this protein to a poly(A)-richsequence or to the faster degradation activity of polyadenylatedRNA? Affinity-binding assays of the 100RNP/PNPase to poly(A),as well as to other RNA molecules, displayed higher binding affinityof this protein to poly(A) than to other RNA molecules (Lisitskyet al., 1997b). On the other hand, the degradation rate was similarfor all RNA molecules examined. These results suggest that thepreferential degradation of polyadenylated RNA in the chloroplastis based on the exoribonuclease 100RNP/PNPase's high binding affinityto the poly(A) sequence. This polypeptide possibly harbors a poly(A)high-affinity binding site in addition to the RNA degradationactive site. In addition, the possibility should be emphasizedthat another, as-yet-unidentified chloroplast exoribonuclease(s)also binds polyadenylated RNA with higher affinity than nonpolyadenylatedRNA. Higher in vitro degradation activity of bacterial RNase IIto polyadenylated RNA was recently detected (Coburn and Mackie,1996). Similarly, the E. coli PNPase was recently found to bindpolyadenylated RNA with higher affinity than other RNA molecules(Lisitsky and Schuster, 1999).

	THE MOLECULAR MECHANISM OF mRNA DEGRADATION IN THE CHLOROPLAST

Our recent model of the mRNA degradation pathway in the chloroplast is presented in Figure 4. The initial event is endonucleolyticcleavage(s) producing RNA molecules with no stem-loop structureat the 3 $'$ end (Fig. 4B). RNAs ending in a stem-loop structurewere poorly polyadenylated in vitro, and RT-PCR clones of poly(A)-richsequences at the end of the mRNA molecule (characterized by astem-loop structure) were obtained with much lower frequency thanthose having the additional site inside the coding region (Lisitskyet al., 1996). Therefore, we suggest that the stem-loop structurecharacterizing most of the chloroplast mRNAs, and shown to bean effective 3 $'$ -end processing signal, also serves as a poor polyadenylationsite for preventing exonucleolytic degradation of the functionalmolecule. Following the endonucleolytic cleavage(s), the proximalfragments were polyadenylated by the addition of poly(A)-richsequences (Fig. 4C). This stage is inhibited by 3 $'$ -dATP (cordycepin)and is required for the continuation of mRNA degradation in thechloroplast. Due to the higher affinity of this enzyme(s) to thepoly(A)-rich sequence, the RNAs were rapidly digested only followingpolyadenylation (Fig. 4D). This last stage can be slowed downby the addition of yeast tRNA (Lisitsky et al., 1997a).

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Figure 4. A model for the degradation pathway of mRNA in the chloroplast. A, Schematic representation of the psbA mRNA molecule. The white box represents the amino acid-coding region, and the stem-loop structures represent inverted repeats in the 5 $'$ - and 3 $'$ -UTRs that potentially form stem-loop structures. B, The initial step in the mRNA degradation process is suggested to be endonucleolytically cleaved by an as-yet-unidentified endonuclease(s). The endonuclease is schematically symbolized by scissors. C, A poly(A)-rich tail, which can be up to several hundred nucleotides in length, is then added to the 3 $'$ end of the 5 $'$ endonucleolytically cleaved product. D, The polyadenylated RNA molecule is rapidly degraded by an exonuclease(s), possibly the 100RNP/PNPase.

The model suggests two mechanisms for modulating the half-life of a particular RNA molecule. The first implies that once themRNA molecule is endonucleolytically cleaved, it is targeted forthe degradation process. In this model the rate-limiting stepis the initial endonucleolytic cleavage. Once this has occurred,cleaved mRNA will be rapidly polyadenylated and exonucleolyticallydegraded. In such a mechanism, the nature, specificity, and modulationof activity and/or expression of the endonuclease(s) determinethe half-life of a particular mRNA molecule, and the activitiesof the poly(A) polymerase and exonuclease do not control the rate-limitingstep. The second model suggests that other steps in the degradationpathway could limit the degradation rate. It is still unknownif the poly(A) tail length, which can amount to several hundrednucleotides, influences the degradation rate. Furthermore, theguanosine residues characteristic of the poly(A) tails of chloroplastpsbA mRNA may be involved in modulating the activity of the respectiveenzyme. On the other hand, they may simply reflect the specificityof the poly(A) polymerase(s) (Burkard and Keller, 1974; Lisitskyet al., 1996). In vitro experiments in which synthetic transcribedRNA with poly(A) tails of different lengths and different proportionsof guanosine residues were incubated with chloroplast proteinextract revealed remarkable differences in degradation rates.The significance of these results in relation to the in vivo situationis still unclear and awaits further investigation.

So far, our model does not explain how the distal endonucleolytic cleavage product is degraded. One possibility is that manyendonucleolytic cleavages along the mRNA occur until the smallRNA fragment representing the 3 $'$ -UTR is degraded by the polyadenylation-dependentpathway, possibly by demolishing the stem-loop structure, therebyenabling polyadenylation. A low degree of polyadenylation of themature 3 $'$ end has already been obtained in vivo and in vitro (Lisitskyet al., 1996). Moreover, an additional exonucleolytic degradationpathway in the chloroplast that is independent of polyadenylationmay exist. For example, evidence of 5 $'$ to 3 $'$ exonuclease activitywas recently obtained in C. reinhardtii chloroplasts (Drager etal., 1998). Whether or not an additional degradation pathway exists,the results of the experiments using the polyadenylation inhibitor3 $'$ -dATP (cordycepin) indicated that the rbcL and psbA mRNAs areexonucleolytically degraded only in the polyadenylation-dependentdegradation pathway. To understand the role of this degradationpathway in the developmental regulation of plastid mRNA stability,the degradation pathway and the necessity for polyadenylationin etioplasts and root amyloplasts has to be determined. In thesedevelopmental stages the psbA and rbcL RNAs have short half-livesand are rapidly degraded.

Over the past few years, our understanding of the chloroplast mRNA degradation pathway has progressed significantly. For certainmRNAs, such as psbA, the different steps of its specific decayhave been revealed. The succession of endonucleolytic degradationevents is reminiscent of that of the prokaryotic ancestor. Thisis supported by the observation that one of the enzymes involvedhas been identified as sharing structural and functional homologywith its prokaryotic counterpart. The chloroplast, however, isin part regulated by the nucleus and by external stimuli suchas light. Moreover, the longevity of its mRNA better reflectsthe properties of plants than those of bacteria. Therefore, thechloroplast probably adopted an intermediate position by combiningthese different features. Following the biochemical pathway ofplastid mRNA degradation, research will continue on the regulationof mRNA stability as part of the regulatory network determiningleaf development and adaptation to environmental conditions.

	FOOTNOTES

¹ This work was supported by the Israel Science Foundation (administered by the Israel Academy of Science and Humanities), bya U.S.-Israel Binational Agricultural Research and DevelopmentFund by U.S.-Israel Binational Science Foundation grants to G.S.,and by a grant from the Deutsche Forschungsgemeinschaft to P.K.
^* Corresponding author; e-mail gadis{at}tx.technion.ac.il; fax 972-4-8225153.

Received December 29, 1998; accepted April 1, 1999.

ABBREVIATIONS

Abbreviations: PNPase, polynucleotide phosphorylase. RT, reverse transcription.

	ACKNOWLEDGMENTS

This paper is dedicated to Irena Lisitsky, who passed away on October 21, 1998. We would like to thank the members of theP.K. and G.S. laboratories for numerous helpful comments and suggestions.We would also like to thank Prof. Riesner for his continuous support.

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Polyadenylation and Degradation of mRNA in the Chloroplast1

Copyright Clearance Center: 0032-0889/99/120//08 © 1999 American Society of Plant Physiologists

Polyadenylation and Degradation of mRNA in the Chloroplast¹

Copyright Clearance Center: 0032-0889/99/120//08

© 1999 American Society of Plant Physiologists