A cosmid vector containing a dominant selectable marker for cloning Chlamydomonas genes by complementation.

Cosmid vectors containing a dominate selectable marker (ble) for complementation cloning of genes in Chlamydomonas reinhardtii were created. The usefulness of these vectors, which differ in the orientation of the ble cassette, was demonstrated by transforming C. reinhardtii to phleomycin resistance, by constructing a large library (approximately 5 x 10(5) recombinants) in one of them using DNA from a C. reinhardtii mutant, and by transforming C. reinhardtii with recombinant cosmid clones and pools.

Mobile self-splicing group I introns from the psbA gene of Chlamydomonas reinhardtii: highly efficient homing of an exogenous intron containing its own promoter.

Introns 2 and 4 of the psbA gene of Chlamydomonas reinhardtii chloroplasts (Cr.psbA2 and Cr.psbA4, respectively) contain large free-standing open reading frames (ORFs). We used transformation of an intronless-psbA strain (IL) to test whether these introns undergo homing. Each intron, plus short exon sequences, was cloned into a chloroplast expression vector in both orientations and then cotransformed into IL along with a spectinomycin resistance marker (16S rrn). For Cr.psbA2, the sense construct gave nearly 100% cointegration of the intron whereas the antisense construct gave 0%, consistent with homing. For Cr.psbA4, however, both orientations produced highly efficient cointegration of the intron. Efficient cointegration of Cr.psbA4 also occurred when the intron was introduced as a restriction fragment lacking any known promoter. Deletion of most of the ORF, however, abolished cointegration of the intron, consistent with homing. The Cr.psbA4 constructs also contained a 3-(3,4-dichlorophenyl)-1,1-dimethylurea resistance marker in exon 5, which was always present when the intron integrated, thus demonstrating exon coconversion. Remarkably, primary selection for this marker gave >100-fold more transformants (>10,000/microgram of DNA) than did the spectinomycin resistance marker. A trans homing assay was developed for Cr.psbA4; the ORF-minus intron integrated when the ORF was cotransformed on a separate plasmid. This assay was used to identify an intronic region between bp -88 and -194 (relative to the ORF) that stimulated homing and contained a possible bacterial (-10, -35)-type promoter. Primer extension analysis detected a transcript that could originate from this promoter. Thus, this mobile, self-splicing intron also contains its own promoter for ORF expression. The implications of these results for horizontal intron transfer and organelle transformation are discussed.

Renilla luciferase as a vital reporter for chloroplast gene expression in Chlamydomonas.

The use of luciferases as reporters of gene expression in living cells has been extended to the chloroplast genome. We show that the luciferase from the soft coral Renilla reniformis (Rluc) can be successfully expressed in the chloroplast of Chlamydomonas reinhardtii. Expression of the rluc cDNA was driven by the promoter and 5' untranslated regions of the atpA gene. Western analysis with an anti-Rluc antibody detected a single polypeptide of 38 kDa in the luminescent cells. This is 3 kDa larger than native Rluc, and suggests that translation of the chimeric mRNA begins at the atpA start codon, 29 codons upstream from the rluc start site. We also show that the luminescence of the transformants was sufficient to enable imaging of colonies using a cooled CCD camera.

Different conformations of nascent peptides on ribosomes.

The length at which the N terminus of nascent proteins becomes available to antibodies during their synthesis on ribosomes was determined. Three different proteins, bovine rhodanese, bacterial chloramphenicol acetyltransferase and MS2 coat protein, were synthesized with coumarin at their N terminus in a cell-free system derived from Escherichia coli. A derivative of coumarin was cotranslationally incorporated as N-coumarin-methionine at the N terminus of polypeptides. The interaction of specific anti-coumarin antibodies with this N-terminal coumarin of ribosome-bound nascent peptides was examined. The results indicate that short nascent peptides of each of the three proteins are unreactive, that the length at which they become accessible to the antibodies is different for the three proteins, and that longer peptides differ in their reactivity. It is suggested that these differences are due to differences in the conformation acquired by the peptides as they are synthesized on the ribosomes.

Binding of an N-terminal rhodanese peptide to DnaJ and to ribosomes.

A peptide corresponding to the N-terminal 17 amino acids of bovine rhodanese was fluorescently labeled with a coumarin derivative at its primary amino group(s) and then purified by high performance liquid chromatography. This peptide interacted with the molecular chaperone DnaJ in the absence of other chaperones and ATP. In the presence of ATP, the molecular chaperone DnaK bound to the DnaJ-peptide complex, but not to the peptide alone. The chaperone GrpE appeared to cause the release of the peptide bound to the ternary complex in the presence of ATP but not in the presence of ADP. This nucleotide apparently stabilized the complex. The peptide also bound to salt-washed Escherichia coli 70 S ribosomes, specifically to 50 S ribosomal subunits, not to 30 S subunits. DnaJ plus DnaK interacted with the peptide on the ribosome. GrpE caused dissociation of the peptide from the ribosome; ATP was required for this reaction. It was inhibited by ADP. A comparable series of chaperone-mediated reactions is assumed to occur with the N-terminal segment of the nascent polypeptide to facilitate its folding on ribosomes.

Cotranslational folding of nascent proteins on Escherichia coli ribosomes.

Evidence is presented for cotranslational folding of rhodanese or ricin during its synthesis on Escherichia coli ribosomes. During transcription-translation, full-length but enzymatically inactive polypeptides accumulated as peptidyl-tRNA on the ribosomes. These polypeptides were activated and released by subsequent incubation with the bacterial chaperones and with release factor (RF-2). Coumarin was incorporated cotranslationally at the N-terminus of the nascent protein from fluorophore-S-Ac-Met-tRNAf. Changes in fluorescence indicated that DnaJ bound to the nascent proteins and to a fluorescently labeled synthetic peptide corresponding to the N-terminal 17 amino acids of bovine rhodanese. This peptide also bound to 70S ribosomes or 50S subunits but not to 30S subunits. It inhibited activation and RF-2-dependent release of the full-length ribosome-bound rhodanese. A deletion mutant of rhodanese lacking the N-terminal 23 amino acids was not accumulated on the ribosome but was synthesized very efficiently. However, the protein that was formed was enzymatically inactive. DnaJ did not bind to this deletion mutant on ribosomes. We conclude that the chaperone-mediated reactions facilitate binding of the N-terminal sequence of nascent proteins to a specific site on 50S ribosomal subunits where it blocks release. The ribosome-bound protein undergoes chaperone-mediated reactions that are required for folding into an enzymatically active conformation.

Inhibition of the release factor-dependent termination reaction on ribosomes by DnaJ and the N-terminal peptide of rhodanese.

A peptide consisting of the 17 N-terminal amino acids of native bovine rhodanese in combination with the chaperone DnaJ specifically inhibits release factor- and stop codon-dependent hydrolysis of N-formylmethionine from N(formyl)-methionyl-tRNA bound with AUG to salt-washed ribosomes. Neither the peptide nor DnaJ by itself causes this inhibition. The N-terminal peptide and DnaJ both singularly and combined do not affect the peptidyltransferase reaction per se. The total amount of rhodanese synthesized in the cell-free coupled transcription-translation system is reduced by the peptide, with concomitant accumulation of full-length enzymatically inactive rhodanese polypeptides on ribosomes. In combination with DnaJ, the N-terminal polypeptide inhibits the termination and release of full-length rhodanese peptides that have accumulated on Escherichia coli ribosomes during the course of uninhibited coupled transcription-translation in the cell-free system. This inhibition appears to involve release factor 2-mediated termination at the UGA termination codon in the coding sequence for rhodanese. It is suggested that the N-terminal peptide inhibits the binding of the release factor to ribosomes. These data appear to provide the first report of differential inhibition of the termination reaction on ribosomes without inhibition of the peptidyltransferase reaction and peptide elongation.

Elongation and folding of nascent ricin chains as peptidyl-tRNA on ribosomes: the effect of amino acid deletions on these processes.

Ricin A-chain was used as a test protein to study the effects of deletion of codons on the ribosomal synthesis, release and chaperone-mediated folding of the proteins. Synthesis of wild-type ricin and five mutant proteins was carried out in an Escherichia coli cell-free coupled transcription/translation system from otherwise identical non-linearized plasmids. The deletions involved small numbers of contiguous amino acid residues at different points from the N terminus to the C terminus of the wild-type protein. Deletion of the N-terminal 20 amino acid residues caused a 45% reduction in total protein synthesis whereas deletion of the next three amino acid residues caused a 1.5-fold increase in synthesis compared with wild-type with an accumulation of full-length polypeptides as peptidyl-tRNA in the ribosomal P site. Intermediate levels of synthesis and release were seen with the other three mutants. Enzymatic activity was detected only with wild-type protein and a mutant lacking the C-terminal five amino acid residues. These were the only ricin species in which chaperone-dependent reactions could be detected by fluorescence from coumarin incorporated with methionine at the N terminus of the proteins. By using sparsomycin to block termination of full-length peptidyl-tRNA, it was demonstrated that the chaperone-mediated reactions detected by fluorescence occur on the ribosomes and involve folding of the nascent protein as peptidyl-tRNA. The results presented provide a direct demonstration of two points of fundamental importance: folding of nascent proteins involving chaperone-mediated reactions can occur on ribosomes and is directly related to the conformation of the native enzyme. Deletion of amino acid residues at different points from the N terminus to the C terminus affects the reactions of elongation, chaperone-mediated folding and release of full-length protein.

The importance of the N-terminal segment for DnaJ-mediated folding of rhodanese while bound to ribosomes as peptidyl-tRNA.

Two lines of evidence indicate the importance of the N-terminal portion of rhodanese for correct folding of the nascent ribosome-bound polypeptide. A mutant gene lacking the codons for amino acids 1-23 of the wild-type protein is expressed very efficiently by coupled transcription/translation on Escherichia coli ribosomes; however, the mutant protein that is released from the ribosomes is enzymatically inactive. The mutant protein does not undergo the reaction that is promoted by the bacterial chaperone, DnaJ, which appears to be essential for folding of ribosome-bound rhodanese into the native conformation. The effect of DnaJ is monitored by fluorescence from coumarin cotranslationally incorporated at the N terminus of nascent rhodanese. Secondly, a synthetic peptide corresponding to the N-terminal 17 amino acids of the wild-type protein interferes with the synthesis of wild-type rhodanese but has much less effect on the synthesis of the N-terminal deletion mutant. The N-terminal peptide inhibits the effect of DnaJ on the nascent wild-type rhodanese and blocks the chaperone-mediated release and activation of ribosome-bound full-length rhodanese polypeptides that accumulate during in vitro synthesis. The results lead to the hypothesis that the N-terminal segment of rhodanese is required for its chaperone-dependent folding on the ribosome.

Chaperone-dependent folding and activation of ribosome-bound nascent rhodanese. Analysis by fluorescence.

Fluorescently labeled rhodanese was synthesized by coupled transcription/translation in a cell-free Escherichia coli system. A derivative of coumarin was co-translationally incorporated at the N terminus of the polypeptide. Molecules released from the ribosomes during the incubation are enzymatically active; however, continued incubation results in accumulation of enzymatically inactive full-length rhodanese polypeptides on the ribosomes. These can be activated and released in the presence of the added chaperones, DnaJ, DnaK, GrpE, GroEL, GroES and ATP. Fluorescence parameters (quantum yield, anisotropy and the emission maximum) of ribosome-bound coumarin-labeled rhodanese are affected differentially by addition of the chaperones individually or sequentially. Rhodanese released from the ribosomes in the presence of all chaperones (enzymatically active) differs in fluorescence properties from rhodanese released by GroES or DnaK only or by puromycin (enzymatically inactive) indicating a difference in conformation. Using sparsomycin, an inhibitor of the peptidyl transferase reaction, full-length rhodanese can be trapped on the ribosomes. A ribosome-bound intermediate formed by DnaJ or DnaJ plus DnaK was demonstrated by the effect of these chaperones on fluorescence spectra resulting from binding of anticoumarin antibodies to the N terminus of newly synthesized rhodanese. The results support the hypothesis that folding of nascent proteins can take place on the ribosome.

Activation and release of enzymatically inactive, full-length rhodanese that is bound to ribosomes as peptidyl-tRNA.

Synthesis of rhodanese in a cell-free coupled transcription/translation system derived from Escherichia coli leads to an accumulation of full-length rhodanese protein on the ribosomes as well as to enzymatically active protein that is released from the ribosomes into the supernatant fraction. The ribosome-bound protein is enzymatically inactive but can be activated and released from the ribosomes without additional protein synthesis by subsequent incubation in the presence of the added chaperones DnaJ, DnaK, GrpE, GroEL, and GroES plus ATP. Efficient activation requires that all of the chaperones are present together during incubation which yields fully active rhodanese. Incubation in the presence of DnaJ only inhibits release whereas incubation with only GroES or DnaK promotes the release of enzymatically inactive protein. Incubation of the ribosome with puromycin leads to the release of enzymatically inactive protein whereas release and activation in the presence of all of the chaperones is blocked by sparsomycin. The effect of these antibiotics provides very strong evidence that enzymatically inactive, full-length rhodanese is bound to the ribosomes as peptidyl-tRNA and that the peptidyl transferase reaction is required for its release. Considered together, the data indicate that chaperone-mediated late stages of rhodanese folding into the enzymatically active, native conformation are intimately associated with the process of termination and release that occurs as part of the reaction cycle of protein synthesis.

In vitro protein engineering using synthetic tRNA(Ala) with different anticodons.

The use of synthetic tRNA for in vitro protein engineering was tested in a coupled transcription/translation system prepared from Escherichia coli. DNA sequences similar to the natural tRNA(Ala/UGC) gene from E. coli but with different anticodons were synthesized in vitro, cloned into a DNA plasmid, and then transcribed in vitro with T7 RNA polymerase. The UGC alanine anticodon was changed to CUA corresponding to the UAG stop codon, CCU corresponding to the rarely used AGG arginine codon, and two four-nucleotide anticodons used to suppress stop codons. Bacterial dihydrofolate reductase was the test protein. Its cloned coding sequence was mutagenized at the GUG codon for valine-75 to correspond to the anticodons of the tRNA constructs, and then the plasmids were used to direct the synthesis of dihydrofolate reductase in the coupled transcription/translation system containing the corresponding synthetic tRNA. The results indicate that all four synthetic tRNAs were functionally active in the synthesis of full-length, enzymatically active dihydrofolate reductase protein.

Evidence for RNA in the peptidyl transferase center of Escherichia coli ribosomes as indicated by fluorescence.

A coumarin derivative was covalently attached to either the amino acid or the 5' end of phenylalanine-specific transfer RNA (tRNA(phe)). Its fluorescence was quenched by methyl viologen when the tRNA was free in solution or bound to Escherichia coli ribosomes. Methyl viologen as a cation in solution has a strong affinity for the ionized phosphates of a nucleic acid and so can be used to qualitatively measure the presence of RNA in the immediate vicinity of the tRNA-linked coumarins upon binding to ribosomes. Fluorescence lifetime measurements indicate that the increase in fluorescence quenching observed when the tRNAs are bound into the peptidyl site of ribosomes is due to static quenching by methyl viologen bound to RNA in the immediate vicinity of the fluorophore. The data lead to the conclusion that the ribosome peptidyl transferase center is rich in ribosomal RNA. Movement of the fluorophore at the N-terminus of the nascent peptide as it is extended or movement of the tRNA acceptor stem away from the peptidyl transferase center during peptide bond formation appears to result in movement of the probe into a region containing less rRNA.

Use of 50 S-binding antibiotics to characterize the ribosomal site to which peptidyl-tRNA is bound.

Five antibiotics (puromycin, erythromycin, lincomycin, sparsomycin, and virginiamycin M1) that bind specifically to the 50 S ribosomal subunit near the peptidyl transferase center were used to compare and characterize the positions of bound AcylPhe-tRNA in the puromycin-reactive and -unreactive states. Binding of the antibiotics was quantitatively measured by their perturbation of fluorescence from probes attached to the alpha-amino group of Phe-tRNA. Derivatives of three probes with differing chemical characteristics and environmental sensitivities were used: a coumarin, an aminonaphthalenesulfonate, and a pyrene. The effects of the antibiotics on the fluorescence of labeled AcylPhe-tRNAs in the two states, while generally qualitatively similar, are nonetheless quantitatively distinct, as are the calculated binding constants for the antibiotics. Puromycin, as reported earlier, binds to both the puromycin-reactive and -unreactive states, but its dissociation constant is higher for the latter state. Erythromycin binds tightly to ribosomes bearing labeled AcylPhe-tRNA in either the puromycin-reactive or -unreactive state. Its effect on the fluorescence of the labeled tRNA is very similar in the two states, except with the pyrene probe, where it has a larger effect in the puromycin-reactive state. Lincomycin and sparsomycin bind to both ribosomal states, but both bind more tightly to the puromycin-reactive state, the extent of the difference varying with the identity of the fluorescent probe. Virginiamycin M1 binds to ribosomes with AcylPhe-tRNA in the puromycin-reactive site, but its binding could not be detected to ribosomes with AcylPhe-tRNA in the puromycin-unreactive site.

Ribosome function determined by fluorescence.

Five different fluorescence phenomena are considered in relation to their use to study the structure and function of ribosomes. These are: quantum yield or emission intensity; emission wavelength maximum; fluorescence anisotropy; collisional quenching; and nonradiative energy transfer. Results from a number of studies in which these techniques were used are described and summarized in relation to the movement and conformation of tRNA, the nascent peptide, and mRNA in a ribosome during the reaction steps of peptide elongation.

Fluorescence characterization of the environment encountered by nascent polyalanine and polyserine as they exit Escherichia coli ribosomes during translation.

The fate of the amino termini of nascent polyalanine, polyserine, and polylysine was monitored by fluorescence techniques as each was translated on Escherichia coli ribosomes. A coumarin probe was placed at the alpha-amino group of a synthetic elongator alanyl-tRNA or a synthetic initiator alanyl-tRNA or at the epsilon-amino group of natural lysyl-tRNA, and each was used to nonenzymatically initiate peptide synthesis. The fluorescent alanyl-tRNAs containing an AAA anticodon were used to initiate polyserine (with a synthetic tRNA(Ser] or polyalanine synthesis from a poly(uridylic acid) template. The fluorescent lysyl-tRNA was used to initiate polylysine synthesis from poly(adenylic acid). Changes in the fluorescence of the amino-terminal coumarin were examined to characterize the environment of the probe as the nascent peptides were extended. Protection from proteolysis and the binding of anti-coumarin antibodies or Fab fragments suggest that the amino terminus of each polypeptide is protected from interaction with proteins (Mr greater than 28,000) until the peptides are extended to an average length of 40-50 residues; however, the fluorescence from the amino terminus of shorter nascent polyalanine and polyserine peptides was readily quenched by methyl viologen (Mr = 257), indicating ribosomes do not shield the nascent peptide from molecules of this size. The data appear to indicate that polyalanine, polyserine, and polylysine are extended from the peptidyl transferase into a protected region of the ribosome such as a groove or tunnel but that this region is readily accessible to small molecules.

The synthesis of polyphenylalanine on ribosomes to which erythromycin is bound.

Erythromycin binds to the large subunit of Escherichia coli ribosomes at a specific site that is very close to the amino acid of aminoacyl-tRNA bound into the peptidyltransferase center, and to the site to which puromycin is bound, the P and A sites, respectively, of the classical two-site model of ribosome function. Both erythromycin and puromycin affect fluorescence from fluorescent derivatives of aminoacyl-tRNAs, while both puromycin and aminoacyl-tRNAs affect fluorescence of fluorescent derivatives of erythromycylamine. The results demonstrate unequivocally that erythromycin, deacylated tRNA, a peptidyl-tRNA analogue and puromycin can be bound simultaneously to the same ribosome. Nascent peptides of more than a few amino acids in length block binding of erythromycin to the ribosomes but, unlike most other peptides, long polyphenylalanine chains can be synthesized on ribosomes to which erythromycin is bound. It is suggested that this refractory synthesis in the presence of erythromycin reflects the atypical physical and structural properties of polyphenylalanine.

Fluorescence study of the topology of messenger RNA bound to the 30S ribosomal subunit of Escherichia coli.

Short RNAs (25-36 nucleotides in length) with sequences of the translational initiation region of bacteriophage R17 protein A mRNA were produced by chemical and in vitro transcription techniques and labeled at their 5' or 3' ends with fluorescent probes. The interaction of these labeled RNAs with the 30S subunit of Escherichia coli was studied by using fluorescence spectroscopic techniques. All the RNAs bound tightly to 30S subunits (Kd less than or equal to 200 nM). Resonance energy transfer experiments demonstrated the proximity of the ends of the RNAs to each other and to two fluorescently labeled sites on the 30S subunit: the 3' end of 16S rRNA and the cysteine residue of ribosomal protein S21. By using the distances calculated from energy transfer between the 3' end of 16S rRNA and the ends of RNAs of varying lengths, a topological map of this region of mRNA on the 30S subunit was constructed.