Multiple Translational Control Sequences in the 5' Leader of the Chloroplast psbC mRNA Interact With Nuclear Gene Products in Chlamydomonas reinhardtii

Multiple Translational Control Sequences in the 5' Leader of the Chloroplast psbC mRNA Interact With Nuclear Gene Products in Chlamydomonas reinhardtii

William Zerges^a, Andrea H. Auchincloss^1,b, and Jean-David Rochaix^b
^a Biology Department, Concordia University, Montreal, Quebec H3G 1M8, Canada
^b Departments of Molecular Biology and Plant Biology, University of Geneva, CH 1211, Geneva 4, Switzerland

Corresponding author: Jean-David Rochaix, University of Geneva, 30 Quai Ernest-Ansermet, CH 1211, Geneva 4, Switzerland., jean-david.rochaix{at}molbio.unige.ch (E-mail)

Communicating editor: V. L. CHANDLER

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Translation of the chloroplast psbC mRNA in the unicellulareukaryotic alga Chlamydomonas reinhardtii is controlled by interactionsbetween its 547-base 5' untranslated region and the productsof the nuclear loci TBC1, TBC2, and possibly TBC3. In this study,a series of site-directed mutations in this region was generatedand the ability of these constructs to drive expression of areporter gene was assayed in chloroplast transformants thatare wild type or mutant at these nuclear loci. Two regions locatedin the middle of the 5' leader and near the initiation codonare important for translation. Other deletions still allow forpartial expression of the reporter gene in the wild-type background.Regions with target sites for TBC1 and TBC2 were identifiedby estimating the residual translation activity in the respectivemutant backgrounds. TBC1 targets include mostly the centralpart of the leader and the translation initiation region whereasthe only detected TBC2 targets are in the 3' part. The 5'-most93 nt of the leader are required for wild-type levels of transcriptionand/or mRNA stabilization. The results indicate that TBC1 andTBC2 function independently and further support the possibilitythat TBC1 acts together with TBC3.

PLASTIDS of plants and eukaryotic algae maintain and expressthe genomes they inherited from their endosymbiont bacterialancestor(s). The translational machinery of plastids has manycomponents in common with eubacterial translational systems,e.g., 5S, 16S, 23S rRNAs, tRNAs, initiation factors, elongationfactor EF-1A (EF-Tu), and ribosomal proteins (HARRIS et al.1994 ; SUGIURA et al. 1998 ). In most cases examined in Chlamydomonasreinhardtii, the Shine-Dalgarno (SD) sequence, which recruitsthe small ribosomal subunit to the initiation codon of bacterialmRNAs by base pairing with the 3' end of the 16S rRNA, is notrequired for translation in plastids (STERN et al. 1997 ; FARGOet al. 1998 ; ZERGES 2000 ; see DISCUSSION). Translation ofplastid mRNAs occurs in the absence of the 5' met ⁷G cap structuresand 3' poly(A) tails used by cytoplasmic mRNAs to direct thesmall ribosomal subunit to their AUG initiation codons. Moreover,some similarities between translation in plastids and eukaryoticnuclear cytosolic systems have been found, including stimulatoryeffects of 3' mRNA termini (ROTT et al. 1998 ) and a possiblerole of a poly (A)-binding protein (reviewed by DANON 1997; ZERGES 2000 ).

The importance of translational control sequences within the5' leaders of many chloroplast mRNAs has been revealed by fusingthem to reporter genes and by their ability to confer translationalregulation of the reporter by environmental factors such aslight (STAUB and MALIGA 1993 ) or trans-acting factors (NICKELSENet al. 1994 ; ZERGES and ROCHAIX 1994 ; STAMPACCHIA et al.1997 ; ZERGES et al. 1997 ). For a few plastid mRNAs of C.reinhardtii, cis-acting translational control sequences havebeen identified within 5' leaders by site-directed and randommutations (reviewed by DANON 1997 ; STERN et al. 1997 ; BRUICKand MAYFIELD 1999 ; NICKELSEN et al. 1999 ; ZERGES 2000 ).Some appear to function as unstructured RNA, while others havesecondary and tertiary structural features, which appear tobe important (ROCHAIX et al. 1989 ; MAYFIELD et al. 1994 ; HIGGS et al. 1999 ). Many cis-acting sequences could interactwith protein factors, as determined by in vitro RNA-protein-bindingassays (ZERGES and ROCHAIX 1994 ), genetic experiments (YOHNet al. 1996 , YOHN et al. 1998 ), and in vivo footprintingwith dimethyl sulfate (HIGGS et al. 1999 ). Unlike most knowneubacterial translational control elements, which are repressiveand situated close to the translation initiation codon (GOLD1988 ), the characterized chloroplast elements have positiveroles in translation and many are distant from the translationinitiation codon in the 5' leader (MAYFIELD et al. 1994 ; SAKAMOTOet al. 1994 ; ZERGES et al. 1997 ; reviewed by DANON 1997; STERN et al. 1997 ; BRUICK and MAYFIELD 1999 ; ZERGES 2000).

Translation of the psbC mRNA in the chloroplast of the unicellulareukaryotic alga C. reinhardtii is controlled by interactionsbetween its 547-nucleotide (nt) 5' leader and the products ofthe nuclear loci TBC1, TBC2, and TBC3. (psbC encodes the 51-kDchlorophyll-binding PSII reaction center subunit P6, the homologof the CP43 protein in vascular plants.) The region of the psbC5' leader between positions 222 and 320 is required for translationinitiation (ZERGES et al. 1997 ). (The 5' end of the mRNA is+1.) This central region has the potential to form a stablestem-loop secondary structure (see Fig 1; ROCHAIX et al. 1989). Two bulges in the stem, caused by two sites of noncomplementaritybetween the strands, are essential for translation because amutation that eliminates them, psbC-FuD34 (Fig 1), completelyabolishes translation of the mRNA (ROCHAIX et al. 1989 ; ZERGESet al. 1997 ). A point mutation at position 227 within thisregion (Fig 1, psbC-F34suI) partially reverses the translationblock caused by the TBC1 mutation, but not that caused by aTBC2 mutation. Thus, this position is critical for the trans-actingrole of TBC1 (ROCHAIX et al. 1989 ; ZERGES and ROCHAIX 1994).

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Figure 1. Identification of functional regions within the psbC 5' leader. The sequence of the 547-nt psbC 5' leader (ROCHAIX et al. 1989

) is shown with the relevant regions indicated as follows. Horizontal arrows indicate the complementary sequences that result from two inverted repeats in the DNA from which the 5' leader is transcribed. Regions that are partially required for translation are indicated with striped boxes (27–222) and open boxes (321–378). The regions that are important for translation are indicated with a shaded box: 223–320 and 519–532. "TBC1" and "TBC3" indicate the target regions of the factors that are encoded or controlled by these loci. The region that is dispensable for translation and partially required for the interactions with TBC1 and TBC2 is indicated by a box with a dashed border and is underlined. The GUG initiation codon is in boldface type. The SD-like sequence (GGAGG) is indicated as "SD." The mutations psbC-FuD34 and psbC-F34suI are indicated.

A dominant nuclear suppressor mutation partially reverses thetranslational blocks caused by mutations of this central region(psbC-FuD34 and a deletion of this region) and tbc1-F34. Thissuppressor mutation has a weak phenotype on its own and inducesa twofold decrease in the rate of synthesis and in the accumulationof P6 (ZERGES et al. 1997 ). Thus, this suppressor mutationidentifies a third nuclear locus, TBC3, which could be involvedin the initiation of translation of psbC mRNA, possibly throughother factors. Like the cis-acting suppressor mutation psbC-F34suI,the tbc3-rb1 suppressor mutation does not reverse the translationalblock caused by a mutation in TBC2, tbc2-F64 (ZERGES et al.1997 ). Our current model is described in the DISCUSSION.

While TBC1 and TBC3 have not yet been characterized at the molecularand biochemical levels, the TBC2 coding sequence predicts aprotein of 1115 residues with nine copies of a novel degenerate39-amino-acid repeat with a quasi-conserved PPPEW motif nearits C-terminal end (AUCHINCLOSS et al. 2002 ). The central regionof the protein displays partial amino acid sequence identitywith Crp1, a protein in Zea mays that is implicated in the processingand translation of the chloroplast petA and petD mRNAs. TheTbc2 protein cofractionates with chloroplast stroma, is associatedwith a 400-kD protein complex, and has been proposed to playa role in the specific translation of the psbC mRNA.

In this study, the psbC 5' leader was dissected for sequencesthat control translation and interact, directly or indirectly,with the TBC1, TBC2, and TBC3 gene products. We have generatedmutant and hybrid psbC 5' leaders and examined their abilityto mediate a response to the products of the nuclear genes TBC1,TBC2, and possibly TBC3.

MATERIALS AND METHODS

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Construction of psbC 5' leader deletions:
To construct the mutant 5' leaders shown in Fig 2A, DNA fragmentsthat flank the deletions were generated as two series. In oneseries fragments extend from position -68 bp [with respect tothe site corresponding to the 5' terminus of mature psbC mRNA(ROCHAIX et al. 1989 )] to various positions within the 5' leader(93, 167, 222, 320, 391, 467, 519, and 532; see Fig 1 and Fig 2A). In the second series, DNA fragments extend from theGUG initiation codon in an upstream direction to various endpointswithin the 5' leader (positions 484, 475, 408, 379, 321, 223,168, 95, 27, and 3; see Fig 1 and Fig 2A). To generate manyof these 5' leader subfragments, two series of deletions weregenerated with ExoIII. First, a fragment of the psbC 5' flankingand 5' leader sequences (between positions -68 and +550, thethird base of the GUG initiation codon), which had been generatedby PCR and cloned in a previous study (ZERGES and ROCHAIX 1994), was excised by digestion with ClaI and BamHI, rendered bluntat its ends, and cloned into the HincII site of the pBluescribevectors pBS+ and pBS- (Stratagene, La Jolla, CA). Each recombinantplasmid was digested with BamHI and KpnI, which cleave adjacentto and on the same side of the insert, for the pBS+ at the distalside and for the pBS- clone at the proximal side, i.e., nearthe GUG initiation codon. Short treatments (30–90 sec)with ExoIII and S1 nuclease (at 30°) followed by intramolecularligation (GUO and WU 1983 ; SAMBROOK and RUSSELL 2001 ) generateda series of plasmids with varying amounts of sequences deletedfrom one end of the 5' leader or the other. Deletion endpointswere determined by DNA sequencing (SAMBROOK and RUSSELL 2001). Various combinations of these partial 5' leaders were combinedby ligating HindIII (rendered blunt)-SacI fragments with 5'flanking and distal 5' leader regions into plasmids with theproximal 5' leader sequences digested with SacI and HindIII(rendered blunt). Other endpoints were generated by PCR, cloned,sequenced to verify that no errors had occurred during PCR (SAMBROOKand RUSSELL 2001 ), and used to generate 5' leader deletionmutants in similar cloning steps to create the set of deletion-mutant5' leaders shown in Fig 2A. Mutagenesis of the SD-like sequencewas performed by PCR with an oligonucleotide that hybridizes67–81 nt upstream from the 5' end of the transcriptionunit and a mutagenic oligonucleotide (5' CCATGGACACTTTGCATTAGGAGGGTACAAATTATTTTGATT3'), which hybridizes to sequences from 516 to 551 (Fig 1) andintroduces a CCTCC in place of the SD-like sequence, GGAGG.

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Figure 2. Analyses of the effects of psbC 5' leader deletions on spc resistance conferred by chimeric psbC-aadA-rbcL reporter genes. (A) The predicted stem-loop structure (diamond-shaped) and the target regions of TBC1, TBC2, and TBC3 are indicated at the top. The psbC 5' leader is shown with the series of deletion mutants. (B) Levels of spc resistance are given for strains that are wild type (wt) or mutant (m) for TBC1, TBC2, or TBC3. n.d., not determined. RNA levels are indicated by + (wild-type level), +/- (low), and - (undetectable).

The resulting fragments with the 5' flanking region and mutant5' leaders were excised from their plasmid vector by digestionwith ClaI and NcoI. The corresponding restriction sites werepresent within the 5' and 3' oligonucleotides. They were ligatedto similarly digested cg20-atpB-INT, a chloroplast transformationvector containing the aadA coding sequence translationally fusedwithin the NcoI site. Fused to the 3' end of aadA are the 3'untranslated region (UTR) and 3' flanking sequence of the chloroplastrbcL gene, which serves to generate processed transcripts ofuniform length (GOLDSCHMIDT-CLERMONT 1991 ).

To generate the hybrid psbC-atpA 5' leader, PCR was used toamplify a DNA fragment with the oligonucleotide that hybridizes67–81 nt upstream of the 5' end and an oligonucleotidethat hybridizes immediately 5' to the SD-like element of psbC.This fragment was cloned into a plasmid vector and sequencedto exclude mutations introduced during PCR. This fragment wasexcised by digestion at the ClaI and XhoI sites introduced atits 5' and 3' extremities, respectively, and ligated into similarlydigested p-atpB-INT, a plasmid containing a chimeric gene withthe atpA 5' leader translationally fused to aadA, containingthe rbcL 3' untranslated region and flanking sequences (GOLDSCHMIDT-CLERMONT1991 ). Digestion of this plasmid with ClaI and XhoI excisesmost of the atpA 5' flanking region and 5' leader, but not theproximal 57 nt and ATG initiation codon (Fig 4; DRON et al.1982 ; LEU et al. 1992 ). This resulted in a fusion of thedistal 533 nt of the psbC 5' leader, up to but not includingthe SD-like sequence, to the proximal 57 nt of the atpA 5' leader,translationally fused to the aadA coding sequence.

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Figure 3. RNA-gel blot analysis of the psbC-aadA-rbcL chimeric mRNAs. Total RNA isolated from homoplasmic transformants was fractionated by agarose gel electrophoresis, blotted, and hybridized with a probe corresponding to the aadA coding sequence to detect the psbC-aadA-rbcL chimeric mRNA (indicated by an arrowhead). To control for the amounts of RNA loaded in each lane, the filter was hybridized with a RbcS2 probe.

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Figure 4. Analysis of chimeric psbC-atpA 5' leaders. (A) Maps show the 5' leaders of the chimeric genes psbC-aadA-rbcL, psbC-atpA-aadA-rbcL, and atpA-aadA-rbcL. The initiation codons are indicated. The psbC-atpA 5' leader consists of the 533 5'-terminal nt of the psbC 5' leader and the 57 3'-terminal nt of the atpA 5' leader (indicated by a shaded box). It is followed by the 75 5'-terminal nt of the atpA coding sequence, which had been fused to aadA (GOLDSCHMIDT-CLERMONT 1991

). (B) spc resistance levels conferred by the chimeric genes in strains with nuclear backgrounds that are wild type or mutant for TBC1 or TBC2. (C) RNA-gel blot analysis of the chimeric mRNAs of A in the wild-type, TBC1, and TBC2 mutant background. The filter was hybridized with a probe specific for the psbC coding region (which is not present in the reporter gene) to control for the amount of total RNA in each lane. The lower RNA band observed in lanes 1–4 is due to some unknown processing event and has been observed previously (GOLDSCHMIDT-CLERMONT 1991

These chloroplast transformation vectors have the atpB geneas a marker to select for rescue of the photosynthesis deficiencyof FuD50, a mutant with a deletion of the 3' portion of thischloroplast gene (WOESSNER et al. 1986 ; GOLDSCHMIDT-CLERMONT1991 ). Thus, following delivery of the DNA into the chloroplastby a biolistic particle gun (ZUMBRUNN et al. 1989 ), stableinsertions of the reporter and marker genes by homologous recombinationcan be selected on "minimal" medium, which requires photosynthesisfor growth. Homoplasmic transformants (strains with all copiesof the multicopy chloroplast genome transformed) were selectedon minimal medium and identified by genomic Southern blot analysisas described previously (ZERGES and ROCHAIX 1994 ).

Culture conditions and genetic analyses:
Strains were grown in Tris/acetate/phosphate medium (GORMANand LEVINE 1965 ). Cultures were grown under a light intensityof 100–150 µE/m²/sec. Induction of gametes, crosses,maturation of zygotes, and tetrad dissections were carried outas described previously (GOLDSCHMIDT-CLERMONT et al. 1990 ).Mutant strains carried tbc1-F34, tbc2-F64, or tbc3-rb1 (ROCHAIXet al. 1989 ; ZERGES and ROCHAIX 1994 ; ZERGES et al. 1997). Growth tests were performed by spotting 10 µl of eachculture (10³ cells) on media solidified with agar (Difco) andvarying concentrations of spectinomycin [spc (Sigma, St. Louis);corrected for its partial purity] in petri plates and observedfor growth and photographed after 5–7 days of incubationat 24° under dim light. Growth is defined as the appearanceof an even distribution of cells throughout the circular areathat received the inoculated cells. Cell growth was equal tothat observed for cells grown in the absence of spectinomycin.Papillary growth occurring over longer periods was excludedand considered as nongrowth. To distinguish wild-type and mutantprogeny for TBC3, mt- progeny were testcrossed to FuD34 (mt+)and their progeny were tested for phototrophic growth on minimalmedium.

RNA-gel blot analyses:
Samples (10 µg) of total RNA prepared with Tri-reagent(Sigma) were electrophoresed through a 1% agarose gel (containingformaldehyde), transferred to Hybond-C+ membrane (Amersham,Buckinghamshire, UK), and probed with double-stranded DNA probes,which had been labeled with random primers using [ ${alpha}$ -³²P]dATP(SAMBROOK and RUSSELL 2001 ). The aadA probe was a 0.81-kb NcoI-PstIcloned DNA fragment corresponding to the aadA structural gene(GOLDSCHMIDT-CLERMONT 1991 ). The relative amounts of the RNAin the samples were standardized by probing the blots with either³²P-labeled DNA fragments derived from psbC [0.95-kb HindIIIfragment from the chloroplast DNA fragment R9 (ROCHAIX 1978)] or a PstI cDNA fragment from the nuclear rbcS2 gene (GOLDSCHMIDT-CLERMONTand RAHIRE 1986 ).

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

To identify regions of the 547-nt psbC 5' leader that promotetranslation and control it through interactions with the productsof TBC1, TBC2i, and TBC3, a series of mutant 5' leaders wasgenerated (Fig 2A). Each was fused to the aadA reporter gene,which was linked previously to the 3' UTR of the chloroplastrbcL gene (ZERGES and ROCHAIX 1994 ). The resulting chimericpsbC-aadA-rbcL reporter genes were introduced into the chloroplastgenome by biolistic transformation (see MATERIALS AND METHODS).

We decided to use aadA as a reporter for this study becausedetection of P6 synthesis by in vivo pulse labeling does notprovide a very sensitive assay as the signal drops below backgroundlevels when the rate of synthesis of P6 is <20–30%of the wild-type level. In contrast, spc resistance conferredby aadA provides a highly sensitive assay. We acknowledge thatthe lack of a calibration curve between spectinomycin resistanceand aadA expression at low resistance levels makes some of ourmeasurements qualitative. Nevertheless, the results describedbelow demonstrate clear and reproducible differences in spcresistance levels between wild-type and mutant nuclear backgrounds,which reveal differences in requirements for 5' UTR sequencesfor the interactions with the three nucleus-encoded functions.

To distinguish translational effects from effects on earliersteps of gene expression, it was necessary to determine thelevel of accumulation and the size of each chimeric mRNA expressedin the chloroplast of the transformants. As seen in Fig 3,RNA-gel blot analyses revealed that the deletions alter theelectrophoretic mobility of the chimeric mRNAs consistent withthe lengths of the deleted regions. Deletions of sequences betweenpositions 95 and 532 do not significantly reduce the steady-statelevels of the chimeric mRNAs (Fig 3). However, reduced mRNAlevels were detected from the chimeric genes with deletions ${Delta}$ 3–222 and, to a lesser extent, ${Delta}$ 27–93 (Fig 3). Thus,sequences within the 5'-most 93 nt of the 5' leader are requiredfor transcription, 5' end processing (ROCHAIX 1996 ), and/ormRNA stabilization (NICKELSEN 1998 ). It appears that the mRNAwith the ${Delta}$ 27–93 deletion is partially active in translationbecause aadA expression was detected (Fig 2). Replacement ofthe SD-like sequence (GGAGG, positions 535–539) in someexperiments was observed to moderately increase the level ofthe mRNA (Fig 3), while in other trials no increase was observed(data not shown).

Two regions of the psbC 5' leader are required for translation and are separated by a dispensable region:
To identify regions of the psbC 5' leader that control translationfrom its initiation codon, the level of aadA reporter gene expressionwas determined by assaying the degree of spc resistance of atleast five transformants for each chimeric reporter gene. Spcresistance is a measure of aadA expression because it correlateswith levels of the streptomycin/spectinomycin adenyltransferaseprotein and its activity (ZERGES et al. 1997 ; FARGO et al.1998 , FARGO et al. 1999 , FARGO et al. 2001 ). [Our antiserumagainst this protein (ZERGES and ROCHAIX 1994 ) lost its specificityduring storage and could not be used.] Growth was assayed inthe presence of spc at concentrations of 50, 100, 250, 500,750, and 1000 µg/ml. Strains resistant to 1000 µg/mlspc were tested for growth in the presence of 1500, 2000, 3000,4000, 5000, and 6000 µg/ml spc. The maximum spc concentrationto which each chimeric reporter gene conferred resistance isshown in the first column of Fig 2B. For example, the chimericgene with the wild-type psbC 5' leader confers resistance to5000 µg/ml spc, but not to 6000 µg/ml. Mutationsthat alter spc resistance without producing a correspondingchange in the steady-state level of the chimeric mRNA shouldaffect translation from the psbC 5' leader.

Translational effects were observed for most mutations. Deletionsaffecting sequences 3' to position 95 do not drastically alterthe level of the mRNA and vary in their ability to promote translation,as revealed by the variable levels of spc resistance that theyconfer. For example, deletions of sequences located betweenpositions 379 and 519 ( ${Delta}$ 379–519, ${Delta}$ 408–519, ${Delta}$ 475–519)do not dramatically alter the level of spc resistance and, therefore,the level of translation of the aadA reporter gene; transformantsexpressing these chimeric mRNAs are resistant to spc concentrationsbetween 1000 and 3000 µg/ml (Fig 2B, column 1). Thus,sequences in the 379–519 region are only weakly requiredfor translation (Fig 2).

In contrast, two regions are required for translation. The largeris located between positions 95 and 378 and appears to containdistinct elements, which are required to varying degrees. Forexample, deletions affecting sequences between positions 95and 222 ( ${Delta}$ 95–222, ${Delta}$ 95–167, and ${Delta}$ 168–222) drasticallylower the level of spc resistance to 50 µg/ml, relativeto the chimeric mRNA with the wild-type 5' leader (Fig 2B).The ${Delta}$ 27–93 deletion results in a reduced level of the chimericmRNA and confers a level of spc resistance similar to that of ${Delta}$ 95–222, ${Delta}$ 95–167, and ${Delta}$ 168–222, suggesting aless stringent requirement for sequences in the 27–93interval than in the 95–222 interval. As reported previously,the central region of the psbC 5' leader has the potential toform a stable stem-loop structure (ROCHAIX et al. 1989 ) andis required for translation (ZERGES et al. 1997 ). Immediatelydownstream of this central element are 58 nt that are partiallyrequired for translation; deletions removing the bases 321–391reduce spc resistance (100 µg/ml). The finding that ${Delta}$ 379–519does not significantly reduce spc resistance delimits this partiallyrequired region to positions 321–378. The second regionrequired for translation, located between 519 and 532 closeto the GUG initiation codon, is defined by two deletions ( ${Delta}$ 321–532and ${Delta}$ 484–532) that severely reduce spc resistance withoutaffecting the chimeric mRNA levels and deletions ( ${Delta}$ 379–519, ${Delta}$ 408–519, and ${Delta}$ 475–519) that still allow for highspc resistance. This required region could extend to the SD-likeelement (GGAGG, positions 534–538) because its replacementconsiderably reduces spc resistance (to 100 µg/ml spc, Fig 2B). Translation is probably more drastically reduced becausethis SD-like sequence replacement was observed in many experimentsto augment the level of the mRNA by severalfold (Fig 3).

cis-acting targets of TBC1 and TBC2:
The previous finding that the 5' leader of the psbC mRNA canconfer all genetic interactions with mutant alleles of TBC1,TBC2, and TBC3 upon expression of the aadA reporter gene (ZERGESand ROCHAIX 1994 ; ZERGES et al. 1997 ) indicates that thesenuclear loci either encode or control factors that interactwith the psbC 5' leader and are involved in its ability to promotetranslation from its GUG initiation codon (see Introduction).

To identify regions in the psbC 5' leader that are involvedin these interactions, for example, RNA sequences or structuresthat bind to regulatory factors encoded or controlled by TBC1or TBC2, we first asked whether the mutant TBC1 and TBC2 allelesalter expression of the aadA reporter gene from the mutant psbC5' leaders. It was possible to look only at effects on expressionfrom the mutant 5' leaders that give a detectable level of expressionin the presence of wild-type TBC1 and TBC2 alleles. We expectedthat deletion of a target RNA element could result in independencefrom the wild-type TBC1 or TBC2 functions.

Transformant strains carrying a mutant chimeric reporter geneand wild type for TBC1 and TBC2 were crossed individually tostrains carrying mutant alleles for either TBC1 or TBC2. Asthe resulting progeny are haploid and their endogenous psbCgene is wild type, the wild-type and mutant progeny for thenuclear locus could be distinguished by their ability to growphotoautotrophically (i.e., in a medium that selects for photosynthesis)or not, respectively, and by analyses of their fluorescencetransients (BENNOUN and BEAL 1997 ). Moreover, unlike mutationsthat abolish photosynthesis, 5' leader mutations that abolishexpression of aadA produce no effect on viability in the absenceof spc and thus impose no selective pressure for reversion.

The chimeric reporter gene is inherited by >95% of progeny becausethe chloroplast genome is inherited in a non-Mendelian fashion,predominantly from the mating-type plus (mt+) parent. To confirmthe presence of the chimeric gene in the progeny analyzed andto exclude possible effects of the TBC1 or TBC2 mutations onthe level of the chimeric mRNAs, total RNA was prepared fromthree progeny strains (wild type, tbc1 mutant, or tbc2 mutant)and analyzed by RNA-gel blotting. The presence of the psbC-aadA-rbcLmRNA revealed that the chimeric reporter gene was inheritedby all progeny tested (data not shown). Although some variationsin the levels of certain chimeric mRNAs were observed betweendifferent experiments and preparations, none could fully accountfor the effects of the TBC1 or TBC2 mutations on spc resistance(as described below). Moreover, the mutant alleles of TBC1 orTBC2 were not associated with any reproducible alterations ofthe electrophoretic mobility of the chimeric mRNAs.

The level of spc resistance was determined for 5–20 progenystrains (from the crosses described above) for the translatablemutant chimeric genes and for either mutant or wild type forTBC1 or TBC2 (Fig 2B). Wild-type progeny for TBC1 and TBC2 showedthe same level of spc resistance as their parental strain did,as both carry the same chimeric reporter gene. Differing levelsof spc resistance were observed for the PSII-deficient progenythat had inherited a mutant allele of either TBC1 or TBC2 (Fig 2B,columns 2 and 3).

As described above, the deletions that remove sequences betweenpositions 27 and 222 ( ${Delta}$ 27–93, ${Delta}$ 95–222, ${Delta}$ 95–167,and ${Delta}$ 168–222) strongly diminish translation. Progeny strainsthat inherited a mutant allele of either TBC1 or TBC2 are sensitiveto 50 µg/ml spc (Fig 2B). Thus, that translation fromthese mutant 5' leaders still requires the wild-type functionsof TBC1 and TBC2 indicates that sequences between positions27 and 222 probably do not contain major cis-acting sequencesthat are required for the interactions with these nuclear geneproducts. Similarly, the SD-like sequence (positions 534–538, Fig 1) also does not appear to constitute an essential partof the TBC1 or TBC2 cis-acting targets because the level ofspc resistance conferred by the chimeric mRNA without this sequencewas abolished by the mutant alleles of TBC1 and TBC2 (Fig 2B).

Because the deletions ${Delta}$ 223–320 and ${Delta}$ 484–532 abolishtranslation of the chimeric mRNAs (neither mRNA confers spcresistance), it was not possible to determine whether the Tbc1and Tbc2 products require these 5' leader sequences to promotetranslation. However, the previous finding that the point mutationat position 227 (Fig 1) suppresses the mutant phenotype producedby tbc1-F34 (but not by a mutant allele of TBC2) revealed afunctional relationship between this site and TBC1 function(ROCHAIX et al. 1989 ; ZERGES and ROCHAIX 1994 ).

cis-acting target sequences of TBC1 are located between positions 321 and 519 of the psbC 5' leader:
In addition to this genetic interaction of TBC1 with position227 of the 5' leader, sequences located 3' to the central regionalso appear to be involved in the interaction with TBC1. The5' leader with deletion ${Delta}$ 321–391 is exceptional in thatthe mutant tbc1 allele does not diminish translation further;both wild-type and mutant progeny for TBC1 are resistant to100 µg/ml spc (Fig 2B). The major TBC1 target within thisregion appears to be confined between 321 and 378 because ${Delta}$ 379–391drives only a low level of expression in the TBC1 mutant background.The importance of the 321–378 region was observed onlyfor TBC1, as the mutant tbc2 allele further reduces translationof the chimeric mRNA with the ${Delta}$ 321–391 deletion: the progenywith the mutant TBC2 allele are sensitive to the lowest spcconcentration tested (50 µg/ml; Fig 2B).

The tbc1 and tbc2 mutant alleles showed more complex interactionswith chimeric mRNAs with deletions of sequences between positions379 and 519 ( ${Delta}$ 379–519, ${Delta}$ 408–519, ${Delta}$ 475–519). Recallthat these deletions only partially lower the level of spc resistancein the presence of wild-type alleles for both TBC1 and TBC2(Fig 2B, column 1). Expression of aadA from the chimeric mRNAswith these deletions was drastically reduced in the progenythat inherited the mutant allele of either TBC1 or TBC2. Butunlike the expression of mRNA bearing the wild-type psbC 5'leader, expression of these mutant mRNAs was not completelyabolished by the trans-acting nuclear mutations (Fig 2B, columns2 and 3). These deletions thus weakly suppress the tbc1 andtbc2 mutations. The observation that translation from mutant5' leaders with sequences between 379 and 519 deleted is onlypartially dependent upon the wild-type functions TBC1 and TBC2suggests that sequences in this region mediate some of the trans-actingeffects of these nuclear gene products.

The response to TBC1, but not TBC2, requires the psbC translation initiation region:
It was not possible to determine whether deletion of the psbCtranslation initiation region (the 14 nt with the SD-like elementand initiation codon, Fig 1) affects the dependencies on thewild-type functions of the nuclear loci because it is fundamentallyrequired for translation. Therefore, these sequences were replacedwith the 57 3'-terminal nt of the 5' leader of the atpA mRNAand its ATG initiation codon (Fig 4). The psbC-atpA-aadA-rbcLreporter gene was integrated into the C. reinhardtii chloroplastgenome, homoplasmic transformant strains were obtained, andthey were crossed to mt- strains that carry a mutant allelefor either TBC1 or TBC2 (MATERIALS AND METHODS). To controlfor any effects of the TBC1 and TBC2 mutations on translationfrom the atpA AUG initiation codon, transformants for an atpA-aadA-rbcLchimeric reporter gene (GOLDSCHMIDT-CLERMONT 1991 ) were analyzedin parallel.

RNA-gel blot analyses of the mRNAs expressed from both chimericgenes, atpA-aadA-rbcL and psbC-atpA-aadA-rbcL, revealed thatthese mRNAs accumulate and neither this accumulation nor themolecular weights of the mRNAs are significantly altered bythe presence of the mutant alleles of TBC1 or TBC2 in the nuclearbackground (Fig 4). Tests of spc resistance revealed that translationof the atpA-aadA-rbcL mRNA is independent of the wild-type TBC1and TBC2 functions: mutant progeny for either loci are as spcresistant as their wild-type siblings (Fig 4). Translation ofthe psbC-atpA-aadA-rbcL chimeric mRNA was also unaltered bythe mutant allele of TBC1: these progeny are nearly as spc resistantas their wild-type siblings. Thus, replacement of the psbC translationinitiation region alleviates the requirement for the wild-typeTBC1 function. Strains with the psbC-atpA-aadA-rbcL chimericreporter gene and the mutant TBC2 allele, however, are severelyaffected in the translation of the psbC-atpA-aadA-rbcL chimericmRNA; they are sensitive to low levels of spc (Fig 4). Thus,the 5'-terminal 533 nt of the psbC 5' leader can confer therequirement for wild-type TBC2 function across 57 nt of atpA5' leader sequences to translation initiation at its AUG initiationcodon. This excludes the involvement of the GUG initiation codon,and sequences immediately 5' to it, in the role of TBC2.

Effect of tbc3-rb1 on mutant psbC 5' leaders:
Because tbc3-rb1 has been characterized only genetically asa dominant suppressor of mutations affecting the psbC 5' leaderand the trans-acting TBC1 locus without null or loss-of-functionalleles we are unable to make any firm inferences regardingTBC3 function or its mechanism of action. Nevertheless, we wereable to localize regions of the psbC 5' leader that containsequences that interact with TBC3 either directly or indirectly.We tested the ability of the tbc3-rb1 suppressor mutation tostimulate translation of the psbC-aadA-rbcL mRNAs with the deletionsthat diminish translation and do not prevent accumulation ofthe mRNA (i.e., ${Delta}$ 95–167, ${Delta}$ 168–222, ${Delta}$ 223–320, ${Delta}$ 321–391, ${Delta}$ 321–319, ${Delta}$ 484–532, ${Delta}$ SD). Deletionsthat are not suppressed could affect sequences that are requiredfor some interaction with TBC3, while suppression would indicatethat the deleted sequences are not required. Transformant strains(mt+) carrying a mutant chimeric psbC-aadA-rbcL reporter genewere crossed to a mt- strain carrying the tbc3-rb1 mutation.All progeny inherited the chimeric reporter gene in the chloroplastgenome and either the wild-type or the mutant TBC3 allele. Toexclude effects of the tbc3-rb1 suppressor mutation on transcriptionor stability of the chimeric reporter mRNAs, RNA-gel blot analyseswere performed. For each deletion the levels of RNA were comparablein the presence of the wild-type or tbc3 mutant allele (datanot shown).

As shown previously, the tbc3-rb1 mutation partially restorestranslation from psbC 5' leaders with either the ${Delta}$ 223–320deletion or the psbC-FuD34 mutation (ROCHAIX et al. 1989 ; ZERGES et al. 1997 ). Similarly, the levels of spc resistanceconferred by chimeric genes with the deletions ${Delta}$ 321–391and ${Delta}$ 484–532 revealed that translation is stimulated bythe tbc3-rb1 suppressor allele in the absence of these sequences(Fig 2B, column 4). In contrast, tbc3-rb1 was unable to increasetranslation in mutants affected in two distinct regions of thepsbC leader: deletions ${Delta}$ 27–93, ${Delta}$ 95–167, ${Delta}$ 168–222, ${Delta}$ 95–222, and the SD-like sequence (Fig 2). In both caseswild-type and mutant progeny for TBC3 showed similar low, butdetectable, levels of spc resistance (Fig 2B, column 4). Thus,the TBC3 suppressor mutation is able to increase the level ofexpression from mutant psbC leaders affected in the middle part,but not from those with lesions in the 5'- and 3'-terminal part.The mechanistic significance of these data will have to awaitthe molecular identification of the TBC3 product.

DISCUSSION

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

In prokaryotes, translation is most frequently regulated byrepressive cis-acting elements, which form secondary structuresor bind to proteins that block access of the small ribosomalsubunit to the translation initiation region (GOLD 1988 ; KOZAK1999 ). This led us to expect repressive sequences in the psbC5' leader, which, when deleted, would result in constitutivetranslation of the mRNA that is independent of the wild-typefunctions of the TBC1 and TBC2 loci (ROCHAIX et al. 1989 ).However, similar to results of analyses of other chloroplast5' leaders (SAKAMOTO et al. 1994 ; HIGGS et al. 1999 ; NICKELSENet al. 1999 ), we found no repressive sequences; none of the5' leader deletions resulted in an increased level of expressionin otherwise wild-type strains (Fig 2). In addition, insertionof overlapping psbC 5' leader regions and of the entire 5' leaderinto the atpA leader did not render aadA expression dependentupon wild-type TBC1 and TBC2 loci (W. ZERGES and J. D. ROCHAIX,unpublished data). These data suggest that TBC1 and TBC2 andtheir cis-acting target sequences activate translation (andthat these functions can be replaced by analogous activatorsin the atpA 5' leader). Thus, unlike eubacterial translationalregulatory elements, sequences throughout the psbC 5' leaderare required for translation, the largest region being separatedfrom the translation initiation region by 140 nt of dispensablesequences within the 379–519 interval.

Five regions containing cis-acting sequences that are requiredfor translation were identified. Partial requirements were foundfor sequences in three regions: 95–222, 321–378,and the SD-like sequence GGAGG, located 10 nt upstream of theGUG initiation codon (positions 534–538; see Fig 1).Two regions are important for translation: the central regionbetween positions 223 and 320 (ZERGES et al. 1997 ) and, atthe 3' end of the 5' leader, sequences between positions 519and 532.

The translational requirement for the SD-like sequence indicatesthat it could function by base pairing with the 3' end of the16S rRNA to position the small ribosomal subunit at the initiationcodon. However, this sequence could be part of a larger translationalelement comprising the 28 nt 5' to the initiation codon, assequences immediately 5' to the SD-like sequence are strictlyrequired for translation (Fig 1 and Fig 2).

Site-directed replacement mutations of the SD-like sequencesof five mRNAs [petD (SAKAMOTO et al. 1994 ), atpB, atpE, rps4,and rps7 (FARGO et al. 1998 )] had little or no effect on theirtranslation in vivo. Deletion of a SD-like sequence in the psbA5' leader of the chloroplast psbA mRNA (encoding the D1 subunitof the photosystem II reaction center) abolished translation,but also severely reduced the level of the mRNA (MAYFIELD etal. 1994 ). Similar to results reported here for psbC, replacementof the SD-like sequence in the 5' leader of the C. reinhardtiipsbD mRNA reduced translation, but did not abolish it (NICKELSENet al. 1999 ). SD sequences could have a more prominent rolein translation of highly expressed mRNAs of cyanobacteria (OSADAet al. 1999 ) and chloroplasts (NICKELSEN et al. 1999 ) andfrom initiation codons with otherwise suboptimal contexts forsmall subunit binding (ESPOSITO et al. 2001 ).

Several sequence elements within the 5' leaders of chloroplastmRNAs have been found to promote their translation. A sequenceof 17 nt located near the 5' end of the tobacco psbA mRNA hasa positive influence on translation (EIBL et al. 1999 ). A predictedstem-loop structure in the 5' leader of the C. reinhardtii psbAmRNA has been proposed to interact with translational activationfactors and to regulate translation of the psbA mRNA in responseto light (MAYFIELD et al. 1994 ). However, this sequence ispresent only in a minor form of the psbA RNA, but absent fromthe mature mRNA. In the 5' leader of the C. reinhardtii chloroplastrps7 mRNA several mutations that affect the predicted foldingpattern of the RNA also block translation, suggesting that thefolding pattern of the RNA is important for its ability to drivetranslation (FARGO et al. 1999 ). The organization of the cis-actingtranslational elements in the 5' leader of the C. reinhardtiichloroplast petD mRNA is most similar to that of the psbC 5'leader. Translation from both 5' leaders requires three distinctsequence elements (SAKAMOTO et al. 1994 ; HIGGS et al. 1999). Translation from the 5' leader of the psbD mRNA in C. reinhardtiirequires a U-rich sequence 15–20 nt distal to the initiationcodon and a SD-like sequence (NICKELSEN et al. 1999 ). Translationfrom the psbC 5' leader requires an element 16–28 nt 5'to the GUG initiation codon; however, this element is not U-rich(Fig 1).

Using the mutant psbC 5' leaders with deletions that allow adetectable level of translation, it was possible to determinewhether the deleted sequences mediate the trans-acting functionsof TBC1 or TBC2. For example, dependence upon the wild-typeTBC1 function was abolished by deletion ${Delta}$ 321–391, but notby ${Delta}$ 379–391 (Fig 2). Therefore, sequences in the 321–378interval are required for the interaction with factor(s) encodedby or controlled by TBC1. The TBC1 independence of translationfrom the hybrid psbC-atpA 5' leader (Fig 4) revealed that TBC1requires the 3' end of the 5' leader to promote translation(and an element in the 57 nt of the atpA 5' leader can substitutefor this interaction). A less probable explanation is that TBC1relieves repression by an unidentified sequence in the translationinitiation region (the 14 nt, including the SD-like sequenceand the GUG initiation codon).

Each of the translatable 5' leaders still requires TBC2. Thus,much of the 5' leader could be excluded as containing TBC2 targetsequences; the intervals 95–222 and 321–391 arenot involved (Fig 1 and Fig 2). However, a weak requirementfor TBC2 function could be identified for the 391–519region. These results could reflect repeated TBC2 target sequences,which are dispersed throughout the 5' leader such that elementslocated outside of any of the deletions can confer TBC2 dependence.More probably, however, the main TBC2 target sequence couldbe within an essential region (223–320 or 519–532)so that there is insufficient translation from these mutant5' leaders to assay for TBC2 independence. The presence of majorTBC2 targets in the translation initiation region was excludedby the ability of the rest of the psbC 5' leader to confer TBC2dependence on translation from the atpA translation initiationregion (Fig 4). It is intriguing that this effect occurs overthe 57 3'-terminal nt of the atpA 5' leader.

Our current model proposes that psbC translation requires interactionsbetween TBC1 and the predicted secondary structure (positions223–320) and sequences immediately 5' to the initiationcodon. Whether TBC3 functions in conjunction with TBC1, probablythrough sequences in the 95–222 region and the SD-likesequence, or whether it is involved in other functions remainsto be explored. Because TBC3 is defined by a single dominantallele that suppresses the effects of two different cis-actingmutations within the psbC leader as well as the effects of thenuclear tbc1-F34 mutation, we cannot exclude the possibilitythat tbc3-rb1 represents a gain-of-function mutation that confersa new RNA-binding specificity to a protein that normally bindselsewhere and is not involved in psbC mRNA translation. TBC2appears to function independently of these components, possiblyin a distinct pathway. Translation of psbC mRNA requires bothpathways.

Most studies of translational control have used reconstitutedsystems in vitro, and few have taken genetic approaches. Ofeubacterial systems, predominantly Escherichia coli has beenused in these studies. Thus, an understanding of the translationalcontrol by the direct or indirect interactions of the Tbc1,Tbc2, and Tbc3 products and the psbC 5' leader could lead tonew insights into the general mechanisms of translational controland reveal the signal transduction pathways and genetic regulatorysystems that control translation in plastids. A class of mRNA-specifictranslational regulators has been identified for mRNAs encodingcentral subunits of the oxidoreductase complexes of the electrontransport chains in both chloroplasts of land plants and C.reinhardtii (GOLDSCHMIDT-CLERMONT 1998 ; BARKAN and GOLDSCHMIDT-CLERMONT2000 ; ZERGES 2000 ) and the mitochondria of Saccharomycescerevisiae (FOX 1996 ). These regulatory functions have beenproposed to control the assembly of the polypeptide productsof the target organelle mRNA into an integral membrane complex(ZERGES 2000 , ZERGES 2002 ; CHOQUET et al. 2001 ).

FOOTNOTES

¹ Present address: SWISS-PROT Group, Swiss Institute of Bioinformatics,CH 1211 Geneva 4, Switzerland.

ACKNOWLEDGMENTS

We thank the members of our laboratories for stimulating discussionsand helpful comments, M. Goldschmidt-Clermont for critical readingof the manuscript, and N. Roggli for preparing the figures.This work was supported by grant 3100-050895.97 from the SwissNational Fund to J.-D.R. and a Canadian National Science andEngineering Research Council operating grant to W.Z.

Manuscript received October 28, 2002; Accepted for publication December 16, 2002.

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