In vitro selection and evolution of functional proteins by using ribosome display

Model System and Quantification of Yields of Affinity Selection.

As a model system, we used scFv fragments of antibodies (21), in which the variable domain of the light chain (V_L) is connected by means of a flexible linker to the variable domain of the heavy chain (V_H). To tether the folded protein to the ribosome and not interfere with folding we fused a spacer to the C terminus of the scFv fragment. Since the antibody domains must form disulfide bonds, and the RNA polymerase requires 2-mercaptoethanol for maximal stability, we performed transcription in a separate reaction and optimized the conditions for oxidative protein folding during translation (22) (see below).

Polypeptide release is an active process, requiring three polypeptide release factors in E. coli (23–25) and one ribosome recycling factor which releases the mRNA (26). The consequence of release factor binding is normally the hydrolysis of the peptidyl-tRNA between the ribose and the last amino acid by the peptidyltransferase center of the ribosome (25). Our system is devoid of stop codons, and thus a fraction of the polypeptide may not be hydrolyzed off the tRNA and remain attached to the ribosome and thus be available for affinity selection.

Translation is stopped by cooling on ice, and the ribosome complexes are further stabilized against dissociation by 50 mM magnesium acetate (18). Chloramphenicol at 50 μM, assumed to also induce ribosome stalling (10, 27), did not improve the selection properties (data not shown). The whole complex, consisting of synthesized protein, ribosome, and mRNA was then bound to the affinity matrix, washed, and eluted with competing ligand, or the ribosomes were dissociated with EDTA (Fig. 1). We did not find it necessary to preparatively isolate polysomes at any stage. The efficiency of ribosome display was found to be two orders of magnitude lower when using coupled in vitro transcription–translation (data not shown).

We developed the ribosome display system in two stages, first by engineering the gene structure for in vitro transcription, translation, and folding, then by optimizing the translation reaction itself. Each test started with 10 μg of input mRNA; this corresponds to ≈1.5 × 10¹³ molecules. The input mRNA was subjected to a single round of affinity selection: translation in vitro, capture of ribosome complexes on immobilized target ligand, and release of mRNA. The released mRNA was then quantified by Northern analysis.

Effect of mRNA Structure on Yield.

In designing the ribosome display system, we first engineered the flanking regions of the scFv gene (Fig. 2A). The gene must be transcribed very efficiently from the PCR product, and its mRNA must be stable against nucleases. For the 5′ end, we used the T7 promoter and the natural T7 gene 10 upstream region, which encodes a stem–loop structure directly at the beginning of the mRNA (29). At the 3′ end, we fused a spacer region of 57–116 amino acids to the reading frame of the scFv to tether the emerging folded polypeptide to the putative polypeptide channel of the ribosome and to give it enough distance to not interfere with folding. This spacer encodes at the RNA level a 3′ stem–loop, either the terminator of the E. coli lipoprotein (29) (lpp term) or the early terminator of phage T3 (30) (T3Te), to increase the stability of mRNA against exonucleases. The mRNA is therefore protected against exonucleases at both ends, much like a natural mRNA would be, but does not contain a translational stop codon. In a direct comparison of flanking regions (Fig. 2B) after one round of translation and selection, we obtained the best result for constructs possessing a 5′-loop (from T7-g10), a 3′-loop (from lpp term), and the longest spacer, 116 amino acids. The yield of mRNA after one round of ribosome display improved from less than 0.001% of input mRNA to 0.015% (15 times).

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Figure 2

(A) Schematic drawing of the scFv construct used for ribosome display. T7 denotes the T7 promoter, SD the ribosome-binding site, F the 3-amino-acid-long FLAG (28) with N-terminal methionine, V_L and V_H the variable domains of the scFv fragment, L the linker, spacer the part of protein construct connecting the folded scFv to the ribosome, and 5′sl and 3′sl the stem–loops on the 5′ and 3′ ends of the mRNA. The arrow indicates the transcriptional start. The strategy for the PCR amplification is shown. (B) The amount of the scFvhag mRNA bound to the polysome complexes is influenced by the secondary structure of its ends and the length of the spacer connecting the folded scFv to the ribosome. Different constructs of scFvhag mRNA were used for one cycle of ribosome display (constructs c1–c9). None of them contained a stop codon. Each species was tested separately. After affinity selection of the ribosome complexes from 100 μl of translation mixtures, mRNAs were isolated and analyzed by Northern hybridization. The presence of the 5′ stem–loop is labeled + or −; that of the 3′ stem–loop is labeled as − when absent, l when derived from lpp term, or t when derived from T3Te. The spacer length indicates the number of amino acids following the scFv and connecting it to the ribosome, including the translated stem–loop. The lengths of RNA in kb are derived from RNA molecular weight marker III (Boehringer Mannheim). The bar graph shows the quantified amounts of mRNA from fluoroimager analysis. (C) Effect of additives on the amount of mRNA bound to the ribosome complexes. The mRNA of the scFvhag construct c7 was used for one cycle of ribosome display. Samples in B lane c7 and C lane 6 are identical. When indicated, 3.5 mM anti-ssrA oligonucleotide ON10 (5′-TTAAGCTGCTAAAGCGTAGTTTTCGTCGTTTGCGACTA-3′), 35 mg/ml protein disulfide isomerase (PDI), or 1 mg/ml VRC was included in the translation mixture. Translations were stopped by addition of Mg(OAc)₂ to the final concentration indicated (in mM) and by cooling on ice. After affinity selection of the ribosome complexes from 100 μl of translation mixtures, mRNAs were isolated and analyzed by Northern hybridization. The bar graph shows the quantified amounts of mRNA from fluoroimager analysis.

Effect of Translation Conditions on Yield.

We then tested the effect of various compounds present during translation. Nucleases were found to be efficiently inhibited by VRC, which should act as transition state analogs (31). VRC at 1 mg/ml maximized the yield of isolated mRNA from ribosome complexes after one round of affinity selection when they were present during translation (Fig. 2C), even though protein synthesis was partially inhibited (data not shown), and omitting VRC led to a severalfold-decreased efficiency of the ribosome display (Fig. 2C). In contrast, Rnasin (10) had no effect on the efficiency of the system (data not shown). We did not find evidence for significant proteolytic degradation of the scFv synthesized under these conditions, since prolonged incubation of released product (up to 300 min) did not alter the electrophoretic pattern (data not shown).

From a systematic study on the in vitro translation of soluble scFv fragments in the presence of molecular chaperones and disulfide-forming catalysts (22), we found that binding activity is obtained if and only if disulfide formation and rearrangement are allowed to take place during translation and folding. The strong beneficial effect of PDI was verified for the ribosome display system, in which the protein is not released. It can be seen that PDI improves the performance of the ribosome display for scFv fragments 3-fold (Fig. 2C) and thus catalyzes the formation and isomerization of disulfide bonds on the ribosome-bound protein.

Recently, a peptide tagging system was discovered in E. coli, whereby proteins translated from mRNA, devoid of a stop codon, are modified and released from the ribosomes by the addition of a C-terminal tag, encoded by ssrA RNA, and thereby marked for degradation (32). We thus investigated the inhibition of the action of this RNA by an antisense oligonucleotide complementary to the tag-coding sequence of ssrA RNA. Indeed, a 4-fold higher efficiency of ribosome display is visible in the presence of anti-ssrA oligonucleotide (Fig. 2C), and the molecular weight of the longest protein product is decreased, presumably by preventing the attachment of the degradation tag (Fig. 3). Combining PDI and the anti-ssrA oligonucleotide led to a 12-fold-increased efficiency of the ribosome display system (Fig. 2C).

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Figure 3

Anti-ssrA antisense oligonucleotide ON10 (Fig. 2C) decreases the molecular mass of the longest protein species (arrows). In vitro translation was performed using [³⁵S]methionine and scFvhag c7 mRNA. Reactions were carried out in the absence (−) or presence (+) of 3.5 mM oligonucleotide ON10. An SDS/PAGE of translation products is shown.

By the combination of proper mRNA secondary structure and various compounds present during translation we could increase the yield of mRNA after one round of affinity selection 200 times—from less than 0.001% to 0.2% of input mRNA. This number expresses the combined efficiency of covalent attachment to the ribosome, protein folding, ligand binding, ribosome capture, and RNA release and amplification.

Specific Enrichment of Target mRNA Through Multiple Rounds of Selection.

In a test of the optimized system, we investigated how well a mixture of two proteins can be enriched for function. Two scFv antibody mRNAs, constructed identically according to Fig. 2A, both possessing the 5′ and the 3′ T3Te loop, one encoding the anti-hemagglutinin scFv 17/9 (11) (scFvhag), the other the anti-β-lactam antibody AL2 (13) (scFvAL2), were mixed at a ratio of 1:10⁸. Their PCR products differ slightly in length, because of differences mainly in the spacer length, and can thus easily be distinguished (Fig. 4A). After five cycles according to Fig. 1, undergoing selection on immobilized hemagglutinin-peptide, 90% of the ribosome complexes contained scFvhag. We can thus conclude that the enrichment is about 2 orders of magnitude per cycle under these conditions.

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Figure 4

(A) Enrichment of the scFvhag ribosome complexes from mixtures with scFvAL2 by ribosome display. mRNA of scFvhag c5 was diluted 10⁸ times with mRNA of scFvAL2, and the mixture was used for ribosome display. After affinity selection of scFvhag ribosome complexes, mRNA was isolated and reverse transcribed to cDNA using oligonucleotide ON5, and cDNA was amplified by PCR using oligonucleotides ON3 and ON7 and analyzed by agarose electrophoresis. Lanes 1–5 are PCR products amplified after the first to fifth cycles of the ribosome display, respectively. Lane M is the 1-kb DNA ladder (GIBCO/BRL) used as molecular weight markers. PCR products corresponding to scFvhag and scFvAL2 are labeled. (B) Enrichment of either scFvhag c5 or scFvAL2 ribosome complexes by ribosome display as a function of immobilized antigen. mRNAs of scFvhag and scFvAL2 were mixed in a 1:1 ratio and used for one cycle of ribosome display. After affinity selection, mRNA was isolated, reverse transcribed, amplified by PCR, and analyzed by agarose electrophoresis as in A. The same 1:1 mixture was affinity selected on immobilized transferrin (tr) as a control, ampicillin-transferrin conjugate (amp), or hemagglutinin-peptide-transferrin conjugate (hag). PCR products corresponding to scFvhag and scFvAL2 are labeled.

To verify that enrichment really occurred through affinity selection, we tested enrichment of a 1:1 mixture of both mRNAs on an irrelevant surface and saw no change from the input ratio (Fig. 4B). Furthermore, from the identical 1:1 mRNA mixture either antibody could be enriched, depending on which antigen was immobilized (Fig. 4B).

Analysis of scFv Antibody Fragments After Affinity Selection.

After the fifth round of selection, the PCR products were ligated into a vector, which was used to transform E. coli, and single clones were analyzed. Of 20 clones sequenced, 18 had the scFvhag sequence and 2 had the scFvAL2 sequence, demonstrating that the 10⁸-fold enrichment was successful. Of the 18 scFvhag clones, 13 gave ELISA signals within 43–102% of wild type and were inhibitable by soluble hemagglutinin peptide, 2 were reduced to 14% and 18%, and 3 were significantly reduced in binding (less than 10%), probably a result of mistakes from the last PCR amplification (Table 1). Thus, the selective pressure to maintain antigen binding, executed by binding and elution from immobilized antigen, is clearly operating, albeit in the context of an ongoing genetic diversification through PCR errors.

The sequence analysis showed that the clones contained between 3 and 7 base changes, with 90% transitions and 10% transversions, in good agreement with the known error properties of Taq DNA polymerase (34). Each clone has gone through a total of 165 cycles of PCR, interrupted by five phenotypic selections for binding, and an error rate of 3.3 × 10⁻⁵ can be calculated under these conditions, where only mutations that have survived the selection are counted.

At the protein level, the selected clones carry between 0 and 4 exchanged amino acids, distributed over V_L, V_H, and the linker. All mutations are independent of each other (Table 1) and give, therefore, an indication of a large range of neutral mutations compatible with function, and perhaps even of improvements the system has selected for. While the exact properties of the selected molecules require further analysis, we note the selection of a proline at the beginning of the linker, which may facilitate the required turn formation (35), and the selection of acidic residues, which are known to increase solubility (36, 37).

Conclusions.

We have shown in this study that it is possible to carry out phenotypic selection for ligand binding with a complete, native protein molecule in vitro by using ribosome display, in this example with a disulfide containing single-chain fragment of an antibody. Functional disulfide-containing protein can be made in vitro, when oxidative folding is suitably catalyzed (22). Since binding of the cognate ligand (antigen) is dependent on the correct three-dimensional structure of the protein (antibody) and its sufficient stability, many molecular properties of a protein can now be selected for. The method described here, ribosome display, does not use any cells at any step, and thus, to our knowledge, constitutes the first evolution and selection system for folded proteins that takes place completely in vitro. No transformation is necessary, and very large libraries become accessible in a single step. While large repertoires have been created for phage display as well (38), many repeated electroporations are necessary, since transformation cannot be scaled up. Furthermore, complex libraries must often be created by repeating this process for the subsequent ligation of different fragments (38). In ribosome display, all replication and amplification, as well as the introduction of the promoter and the 3′ tether, are carried out by PCR in vitro, and thus this method is conveniently interfaced with novel, elegant methods for obtaining even more genetic diversity, such as sexual PCR (39), error-prone PCR (40), or PCR using oligonucleotides made with mixtures of trinucleotide codons (41). Thus, ribosome display is an ideal method for the evolution of proteins through many generations, avoiding the tedious alternation between in vitro and in vivo steps, which would be required to achieve the same with phage display. Conversely, the error rate can also be decreased in ribosome display by the use of proof-reading polymerases, if ribosome display is used merely as a screening tool. We believe that with this technology described here very fundamental questions of protein structure and evolution become accessible for study, and that it has great utility in lead compound identification and optimization.