Effects of palindrome size and sequence on genetic stability in the bacteriophage phi X174 genome

By inserting palindromes of varying length and sequence into a non-essential region of the bacteriophage phi X174 genome we have investigated the effect of palindrome size and sequence on their genetic stability. Multimers of increasing size of the EcoRI linker CCGAATTCGG (E), the BamHI linker CCGGATCCGG (B) or mixtures of both (E, B) were inserted into the PvuII site of a previously constructed bacteriophage strain phi X174 J-F ins6. The largest inserts that could be maintained in the genome without significant loss of genetic stability were 2B, 4E, and 4(E, B), respectively. Polymers exceeding this size could be inserted but resulted in rapid and precise deletion from the phage genome, whereby nB was more unstable than nE, and nE was more unstable than n(E, B). Analysis of the resulting deletion mutants provided evidence for two different types of deletions. The more frequent deletion arose from either type palindrome and removed nucleotides in blocks of ten base-pairs (one linker unit), but only from the palindromic sequence, and always left at least an 18 base-pair long palindrome (one linker plus 8 neighboring base-pairs) behind. The less frequently occurring deletions arose only from nB type palindromes, removing the complete palindromic sequence plus adjacent nucleotides. At least the first type of deletion occurred in the absence of recA activity. Our results show a correlation between the sequence, as well as size, and the genetic stability of palindromes, i.e. sequences that could decrease the stability of a cruciform increased their genetic stability. This supports the theory that palindrome deletion occurs via extrusion of the palindrome into a cruciform or cruciform-like structure.     

Regions of incompatibility in single-stranded DNA bacteriophages phi X174 and G4.

The intracellular presence of a recombinant plasmid containing the intercistronic region between the genes H and A of bacteriophage phi X174 strongly inhibits the conversion of infecting single-stranded phi X DNA to parental replicative-form DNA. Also, transfection with single-stranded or double-stranded phi X174 DNA of spheroplasts from a strain containing such a "reduction" plasmid shows a strong decrease in phage yield. This phenomenon, the phi X reduction effect, was studied in more detail by using the phi X174 packaging system, by which plasmid DNA strands that contain the phi X(+) origin of replication were packaged as single-stranded DNA into phi X phage coats. These "plasmid particles" can transduce phi X-sensitive host cells to the antibiotic resistance coded for by the vector part of the plasmid. The phi X reduction sequence in the resident plasmid strongly affected the efficiency of the transduction process, but only when the transducing plasmid depended on primosome-mediated initiation of DNA synthesis for its conversion to double-stranded DNA. The combination of these results led to a model for the reduction effect in which the phi X reduction sequence interacted with an intracellular component that was present in limiting amounts and that specified the site at which phi X174 replicative-form DNA replication takes place. The phi X reduction sequence functioned as a viral incompatibility element in a way similar to the membrane attachment site model for plasmid incompatibility. In the DNA of bacteriophage G4, a sequence with a similar biological effect on infecting phages was identified. This reduction sequence not only inhibited phage G4 propagation, but also phi X174 infection.     

Nucleotide sequence of the genome of the bacteriophage alpha 3: interrelationship of the genome structure and the gene products with those of the phages, phi X174, G4 and phi K.

The complete nucleotide sequence of the genome of the circular single-stranded DNA (isometric) phage alpha 3 has been determined and compared with that of the related phages phi X174 and G4. The alpha 3 genome consists of 6087 nucleotides, which is 701 nucleotides longer than the nucleotide sequence of the phi X174 genome and 510 nucleotides more than that of the G4 genome. The results demonstrated that the three phage species have 11 homologous genes (A, A*, B, C, K, D, E, J, F, G and H), the order of which is fundamentally identical, suggesting that they have evolved from a common ancestor. The sequence of some genes and untranslated intergenic regions, however, differs significantly from phage to phage: for example, the degree of amino acid sequence homology of the gene product is averaged at 47.7% between alpha 3 and phi X174 and 46.9% between alpha 3 and G4, and alpha 3 has a remarkable longer intergenic region composed of 758 nucleotides between the genes H and A compared with the counterparts of phi X174 and G4. Meanwhile, in vivo experiments of genetic complementation showed that alpha 3 can use none of the gene products of phi X174 and G4, whereas the related phage phi K can rescue alpha 3 nonsense mutants of the genes B, C, D and J. These sequencing and in vivo rescue results indicated that alpha 3 is closely related to phi K, but distantly remote from phi X174 or G4, and supported an evolutional hypothesis which has been so far proposed that the isometric phages are classified into three main groups: the generic representatives are phi X174, G4 and alpha 3.     

Effects of genome size on bacteriophage phi X174 DNA packaging in vitro

Effects of the size of template DNA on the DNA packaging reaction of bacteriophage phi X174 were studied using plasmids of various sizes which contain the phi X174 origin of DNA replication and the in vitro phage synthesizing system (Aoyama, A., Hamatake, R. K., and Hayashi, M. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 4195-4199). DNA between 78.5% and 101% of the length of phi X174 DNA produced infectious particles efficiently. Packaging of DNA smaller or larger than this range produced uninfectious defective particles. Although these particles contained circular single-stranded DNA, they suffered structural changes which altered the sedimentation properties or the ability to adsorb to the cells. Mutant phage were found from the packaging reaction of DNA larger than 101% of phi X174 DNA. These mutants deleted the termination region of DNA, suggesting that they were produced by early termination of the phage synthesizing reaction.     

The complete 30-base-pair origin region of bacteriophage phi X174 in a plasmid is both required and sufficient for in vivo rolling-circle DNA replication and packaging

The origin of replication of the isometric single-stranded DNA bacteriophages is located in a specific sequence of 30 nucleotides, the origin region, which is highly conserved in these phage genomes. Plasmids harboring this origin region are subject to rolling-circle DNA replication and packaging of single-stranded (ss) plasmid DNA into phage coats in phi X174 or G4-phage-infected cells. This system was used to study the nucleotide sequence requirements for rolling-circle DNA replication and DNA packaging employing plasmids which contain the first 24, 25, 26, 27, 28 and the complete 30-base-pair (bp) origin region of phi X174. No difference in plasmid ss DNA packaging was observed for plasmids carrying only the 30-bp origin region and plasmids carrying the 30-bp origin region plus surrounding sequences (i.e. plasmids carrying the HaeIII restriction fragment Z6B of phi X174 replicative-form DNA). This indicates that all signals for DNA replication and phage morphogenesis are contained in the 30-bp origin region and that no contribution is made by sequences which immediately surround the origin region in the phi X174 genome. The efficiency of packaging of plasmid ssDNA for plasmids containing deletions in the right part of the origin region decreases drastically when compared with the plasmid containing the complete 30-bp origin region (for a plasmid carrying the first 28 bp of the origin region to approximately 5% and 0.5% in the phi X174 and G4 systems respectively). Previous studies [Fluit, A.C., Baas, P.D., van Boom, J.H., Veeneman, G.H. and Jansz, H.S. (1984) Nucleic Acids Res. 12, 6443--6454] have shown that the presence of the first 27 bp of the origin region is necessary as well as sufficient for cleavage of the viral strand in the origin region by phi X174 gene A protein. Moreover, Brown et al. [Brown, D.R., Schmidt-Glenewinkel, T., Reinberg, D. and Hurwitz, J. (1983) J. Biol. Chem. 258, 8402--8412] have shown that omission of the last 2 bp of the origin region does not interfere with phi X174 rolling-circle DNA replication in vitro. Our results therefore suggest that for optimal phage development in vivo, signals in the origin region are utilized which have not yet been noticed by the in vitro systems for phi X174 phage DNA replication and morphogenesis.     

Viral DNA-synthesizing intermediate complex isolated during assembly of bacteriophage phi X174.

A DNA protein complex that is a precursor of mature phi X174 phage was isolated. The complex sedimented with an S value of 50 in a sucrose gradient and contained phage DNA consisting of a replicative form molecule with an extended tail of single-stranded viral DNA. The viral-strand DNA ranged from one to two genomes in length. Proteins coded on the phi X174 genome as well as the host genome were associated with the viral DNA in the 50S precursor complex. Our results indicated that both viral DNA synthesis and cleavage of the growing viral-strand DNA occurred in the 50S complex.     

DNA sequences which support activities of the bacteriophage phi X174 gene A protein

The DNA sequence of 30 nucleotides which surrounds the origin of viral strand DNA replication is highly conserved amongst the icosahedral single-stranded DNA bacteriophages. The A gene of these phages encodes a protein which is required for initiation and termination of viral strand DNA synthesis and acts as a nicking-closing activity specifically within this 30-nucleotide sequence. A system of purified Escherichia coli host proteins and phi X174 gene A protein has been developed which specifically replicates in vitro the viral strand of phi X174 from RF (replicative form) I template DNA and yields single-stranded circular DNA products (RF leads to SS(c) DNA replication system). Recombinant plasmids carrying inserts derived from phage phi X174 or G4 DNA which range in length from 49 to 1175 base pairs and contain the 30-nucleotide conserved sequence have been shown to support phi X A protein-dependent DNA synthesis in vitro in this replication system. We report here that insertion of the 30-nucleotide sequence alone into pBR322 allows the resulting recombinant plasmids to support phi X A protein-dependent in vitro DNA synthesis as efficiently as phi X174 template DNA in the RF leads to SS(c) replication system. The 30-nucleotide sequence functions as a fully wild type DNA replication origin as determined by the rate of DNA synthesis and the structure of resulting DNA products. Furthermore, the DNA sequence requirements for nicking of RF I DNA by the phi X A protein and for supporting replication origin function have been partially separated. Homology to positions 1, 29, and 30 of the 30-nucleotide conserved sequence are not required for cleavage of RF I DNA by the A protein; homology to position 1 but not 29 or 30 is required for efficient DNA replication.     

Construction of bacteriophage luminal diameterX174 mutants with maximum genome sizes.

The bacteriophage phi X174 strain ins6 constructed previously was used to investigate the maximum genome size that could be packaged into the icosahedral phage without concomitant loss of phage viability. The J-F intercistronic region of ins6, which already contains an insert of 117 base pairs with a unique PvuII site, was enlarged further by insertion of HaeIII restriction fragments of the plasmid pBR322 into that PvuII site. By using a biochemical approach for the site-specific mutagenesis as well as selection of mutant genomes, a series of mutants was isolated with genomes of up to 5,730 nucleotides, 6.4% larger than that of the wild-type DNA. Phages with genomes larger than 5,550 nucleotides were highly unstable and were rapidly outgrown by spontaneously occurring deletion mutants. The data predict that genomes of at least 6,090 nucleotides could be constructed and, most likely, packaged, but the resulting phages would not grow well. We speculate that the volume of the phage capsid is not the limiting factor of genome size or is not the only limiting factor.     

Selective cloning of a DNA single-strand initiation determinant from phi X174 replicative-form DNA.

An M13 phage deletion mutant, M13 delta E101, developed as a vector for selecting DNA sequences that direct DNA strand initiation on a single-stranded template, has been used for cloning restriction enzyme digests of phi X174 replicative-form DNA. Initiation determinants, detected on the basis of clear-plaque formation by the chimeric phage, were found only in restriction fragments containing the unique effector site in phi X174 DNA for the Escherichia coli protein n' dATPase (ATPase). Furthermore, these sequences were functional only when cloned in the orientation in which the phi X174 viral strand was joined to the M13 viral strand. A 181-nucleotide viral strand fragment containing this initiation determinant confers a phi X174-type complementary-strand replication mechanism on M13 chimeras. The chimeric phage is converted to the parental replicative form in vivo by a mechanism resistant to rifampin, a specific inhibitor of the normal RNA polymerase-dependent mechanism of M13. In vitro, the chimeric single-stranded DNA promotes the assembly of a functional multiprotein priming complex, or primosome, identical to that utilized by intact phi X174 viral strand DNA. Chimeric phage containing the sequence complementary to the 181-nucleotide viral strand sequence shows no initiation capability, either in vivo or in vitro.     

Mutational analysis of the bacteriophage phi X174 replication origin

Bacteriophage phi X174 mutants within the 30 base-pair replication origin were constructed using oligodeoxynucleotide-directed mutagenesis. A total of 18 viable base substitution mutants at 13 different positions within the origin region were obtained. The majority of these ori mutants have a plaque morphology and burst size comparable to that of wild-type phi X174. Two phi X174 ori mutants with a reduced growth ability spontaneously acquired additional mutations that enhanced the growth rate. The additional mutation was located at the same site as the original mutation or was located in the N-terminal part of the gene A protein. This latter secondary mutation is responsible for a better binding and/or recognition of the gene A protein to the mutated origin. In a Darwinian experiment wild-type phi X174 outgrows all phi X174 ori mutants, indicating the superiority of the wild-type ori sequence for the reproduction of bacteriophage phi 174. Insertions and deletions were constructed at different positions within the phi X174 replication origin cloned in a plasmid. Small insertions and deletions in the A + T-rich spacer region do not inhibit phi X174 gene A protein cleavage in vitro, but severely impair packaging of single-stranded plasmid DNA in viral coats.     

Cloned bacteriophage phi X174 DNA sequence interferes with synthesis of the complementary strand of infecting bacteriophage phi X174.

The insertion of a particular phi X DNA sequence in the plasmid pACYC177 strongly decreased the capacity of Escherichia coli cells containing such a plasmid to propagate bacteriophage phi X174. The smallest DNA sequence tested that showed the effect was the HindII fragment R4. This fragment does not code for a complete protein. It contains the sequence specifying the C-terminal part of the gene H protein and the N-terminal part of the gene A protein, as well as the noncoding region between these genes. Analysis of cells that contain plasmids with the "reduction sequence" showed that (i) the adsorption of the phages to the host cells is normal, (ii) in a single infection cycle much less phage is formed, (iii) only 10% of the infecting viral single-stranded DNA is converted to double-stranded replicative-form DNA, and (iv) less progeny replicative form DNA is synthesized. The reduction process is phi X174 specific, since the growth of the related G4 and St-1 phages was not affected in these cells. The effect of the recombinant plasmids on infecting phage DNA shows similarity to the process of superinfection exclusion.     

An international collaborative study of ''genetic drift'' in Salmonella typhimurium strains used in the Ames test

The efficiency of Weigle reactivation of ultraviolet light-irradiated single and double-stranded phi X174 DNA by wild-type and excision repair-defective E. coli hosts was determined. After limited exposure to ultraviolet light, the efficiency of Weigle reactivation by an ultraviolet light-irradiated wild-type host was greater for double-stranded phi X174 DNA than for its single-stranded counterpart. However, the efficiency of inducible recovery of the double-stranded DNA molecule decreased as its exposure to ultraviolet light increased until it became constant at a value 1.5 times less than that for single-stranded form of phi X174 DNA. The efficiency of Weigle reactivation of the single-stranded DNA molecule by the same host, however, was independent of the dose to the DNA, as were the efficiencies of reactivation for both forms of phi X174 DNA by ultraviolet light-irradiated excision repair-deficient hosts. In excision repair-defective hosts the efficiency of Weigle reactivation of double-stranded phi X174 DNA was also 1.5 times less than that for the single-stranded molecule. These results suggest that the Weigle reactivation of double-stranded phi X174 DNA is mediated in part by an excision repair process, and that this component of Weigle reactivation eventually can be saturated by ultraviolet light-induced DNA damage leaving other repair processes, such as trans-damage synthesis, responsible for the remaining inducible reactivation.     

Genes and regulatory sequences of bacteriophage phi X174

Fragments of the DNA of bacteriophage phi X174 were inserted in the plasmids pACYC177 and pBR322, in order to test the in vivo effects of separate phage genes and regulatory sequences. The phi X174 inserts were identified by recombination and complementation with phage mutants, followed by restriction enzyme analysis. The genes B, C, F and G can be maintained stably in the cell even when there is efficient expression of these viral genes. Recombinant plasmids with the complete genes D and E can only be maintained when the expression of these genes is completely blocked. Expression of complete H and J genes could not yet be demonstrated. The intact gene A was apparently lethal for the host cell, as it was never found in the recombinants. The genes F and G are expressed, even when they are not preceded by one of the well characterized viral or plasmid promoter sequences. Screening of the nucleotide sequence of phi X174 gives two promoter-like sequences just in front of the two genes. Viral sequences with replication signals (the phi X174 (+) origin of replication, the initiation site for complementary strand synthesis and the incompatibility sequence) appeared to be functional also when inserted in recombinant plasmids. A plasmid with the phi X (+) origin can be forced to a rolling circle mode of replication. The A protein produced by infecting phages works in trans on the cloned viral origin. The (-) origin can function as initiation signal for complementary strand synthesis during transduction of single-stranded plasmid DNA. The intracellular presence of the incompatibility sequence on a plasmid prevents propagation of infecting phages.     

Mechanism of replication of bacteriophage phi X174. XXII. Site-specific mutagenesis of the A* gene reveals that A* protein is not essential for phi X174 DNA replication

The A and A* proteins of phage phi X174 are encoded in the same reading frame in the viral genome; the smaller A protein is the result of a translational start signal with the A gene. To differentiate their respective functions, oligonucleotide-directed site-specific mutagenesis was used to change the ATG start codon of the phi X 174 A* gene, previously cloned into pCQV2 under lambda repressor control, into a TAG stop codon. The altered A gene was then inserted back into phi X replicative form DNA to produce an amber mutant, phi XamA*. Two different Escherichia coli amber suppressor strains infected with this mutant produced viable progeny phage with only a slight reduction in yield. In Su+ cells infected with phi XamA*, phi X gene A protein, altered at one amino acid, was synthesized at normal levels; A* protein was not detectable. These observations indicate that the A* protein increases the replicative efficiency of the phage, perhaps by shutting down host DNA replication, but is not required for replication of phi X174 DNA or the packaging of the viral strand under the conditions tested.     

The ABC-primosome. A novel priming system employing dnaA, dnaB, dnaC, and primase on a hairpin containing a dnaA box sequence

A priming mechanism requiring dnaA, dnaB, and dnaC proteins operates on a single-stranded DNA coated with single-stranded DNA-binding protein. This novel priming, referred to as "ABC-priming," requires a specific hairpin structure whose stem carries a dnaA protein recognition sequence (dnaA box). In conjunction with primase and DNA polymerase III holoenzyme, ABC-priming can efficiently convert single-stranded DNA into the duplex replicative form. dnaA protein specifically recognizes and binds the single-stranded hairpin and permits the loading of dnaB protein to form a prepriming protein complex containing dnaA and dnaB proteins which can be physically isolated. ABC-priming can replace phi X174 type priming on the lagging strand template of pBR322 in vitro, suggesting a possible function of ABC-priming for the lagging strand synthesis and duplex unwinding. Similar to the phi X174 type priming, a mobile nature of ABC-priming was indicated by helicase activity in the presence of ATP of a prepriming protein complex formed at the hairpin. The implications of this novel priming in initiation of replication at the chromosomal origin, oriC, and in its contribution to the replication fork are discussed.     

Initiation and termination of the bacteriophage phi X174 rolling circle DNA replication in vivo: packaging of plasmid single-stranded DNA into bacteriophage phi X174 coats.

The bacteriophage phi X174 viral (+) origin when inserted in a plasmid can interact in vivo with the A protein produced by infecting phi X174 phages. A consequence of this interaction is packaging of single-stranded plasmid DNA into preformed phage coats resulting in infective particles (1). This property was used to study morphogenesis and to analyse the signals for initiation and termination of the rolling circle DNA replication in vivo. It is shown that the size of the DNA had a strong effect on the encapsidation by the phage coats and the infectivity of the particle. Termination was analysed by using plasmids with two phi X (+) origins either in the same orientation or in opposite orientation. Both origins were used with equal frequency. Initiation at one origin resulted in very efficient termination (greater than 96%) at the second origin in the case of two origins in the same orientation. When the two (+) origins have opposite orientations, no correct termination was observed. The second origin in the opposite strand effectively inhibits (greater than 98%) the normal DNA synthesis; i.e. the covalently bound A protein present in the replication fork interacts with the (+) origin sequence in the opposite strand.     

Differences in secondary structure between packaged and unpackaged single-stranded DNA of bacteriophage phi X174 determined by Raman spectroscopy: a model for phi X174 DNA packaging.

The single-stranded packaged genome (ssDNA) of bacteriophage phi X174 is shown by Raman spectroscopy to lack both the ordered phosphodiester backbone and base stacking, which are demonstrated for unpackaged, protein-free ssDNA. In solutions of moderate ionic strength, unpackaged ssDNA contains 36 +/- 7% of deoxyribosyl phosphate groups with conventional B-type backbone geometry [i.e., gauche- and trans orientations, respectively, for the 5'O-P (alpha) and 3'O-P (zeta) torsions], indicative of hairpin formation and intramolecular base pairing. Additionally, the bases of unpackaged ssDNA are extensively stacked. Estimates from Raman band hypochromic effects indicate that unpackaged ssDNA contains approximately 70% of the maximal base stacking exhibited in the linear, double-stranded, replicative form III of phi X174 DNA. Conversely, for the packaged phi X174 genome, ordered (B-type) phosphodiester groups are not present, and only 40% of the base stacking in RFIII DNA is observed. These results are interpreted as evidence that the substantial hairpin-forming potential of ssDNA is eliminated by specific and extensive ssDNA-protein interactions within the phi X174 virion. Comparison of the present results with studies of other packaged single-stranded nucleic acids suggests that proteins of the capsid shell (gpF + gpG + gpH) do not fully account for the conformational constraints imposed on ssDNA of phi X174. Accordingly, we propose a model for ssDNA packaging in which the small basic gpJ protein, which is packaged along with the genome, is involved stoichiometrically in binding to the ssDNA (approximately 90 nucleotides per subunit). The proposed gpJ-DNA interactions could prevent helical hairpin formation, restrict base stacking, and disfavor fortuitous base pairing within the capsid. The present analysis is based upon use of model nucleic acids of known conformation for calibration of the Raman intensity in the region 810-860 cm-1 in terms of specific secondary structures. The calibration curve allows quantitative determination of the percentage of ssDNA nucleotides for which the 5'O-P-O3' group is configured (g-,t) as in the B-form of DNA. The method proposed here is analogous to that employed by Thomas and Hartman (1973) for ssRNA and should be applicable to single-stranded DNA and to partially denatured forms of double- and multiple-stranded DNAs.     

Structure of simian virus 40-phiX174 recombinant genomes isolated from single cells.

Three simian virus (SV40)-phi X174 recombinant genomes were isolated from single BSC-1 monkey cells cotransfected with SV40 and phi X174 RF1 DNAs. The individual cell progenies were amplified, cloned, and mapped by a combination of restriction endonuclease and heteroduplex analyses. In each case, the 600 to 1,000 base pairs of phi X174 DNA (derived from different regions of the phi X174 genome) were present as single inserts, located in either the early or late SV40 regions; the deletion of SV40 DNA was greater than the size of the insert; and the remaining portions of the hybrid genome were indistinguishable from wild-type SV40 DNA, as judged by both mapping and biological tests. Hence, apart from the deletion which accommodates the phi X174 DNA insert, no other rearrangements of SV40 DNA were detected. The restriction map of a SV40-phi X174 recombinant DNA isolate before molecular cloning was indistinguishable from those of two separate cloned derivatives of that isolate, indicating that the species cloned was the major amplifiable recombinant structure generated by a single recombinant-producing cell. The relative simplicity of the SV40-phi X174 recombinant DNA examined is consistent with the notion that most recombinant-producing BSC-1 cells support single recombination events generating only one amplifiable recombinant structure.     

Random removal of inserts from an RNA genome: selection against single-stranded RNA.

We have monitored the evolution of insertions in two MS2 RNA regions of known secondary structure where coding pressure is negligible or absent. Base changes and shortening of the inserts proceed until the excessive nucleotides can be accommodated in the original structure. The stems of hairpins can be dramatically extended but the loops cannot, revealing natural selection against single-stranded RNA. The 3' end of the MS2 A-protein gene forms a small hairpin with an XbaI sequence in the loop. This site was used to insert XbaI fragments of various sizes. Phages produced by these MS2 cDNA clones were not wild type, nor had they retained the full insert. Instead, every revertant phage had trimmed the insert in a different way to leave a four- to seven-membered loop to the now extended stem. Similar results were obtained with inserts in the 5' untranslated region. The great number of different revertants obtained from a single starting mutant as well as sequence inspection of the crossover points suggest that the removal of redundant RNA occurs randomly. The only common feature among all revertants appears the potential to form a hairpin with a short loop, suggesting that single-stranded RNA negatively affects the viability of the phage. To test this hypothesis, we introduced XbaI fragments of 34 nucleotides that could form either a long stem with a small loop or a short stem with a large loop (26 nucleotides). The base-paired inserts were perfectly maintained for many generations, whereas the unpaired versions were quickly trimmed back to reduce the size of the loop. These data confirm that single-stranded RNA adversely affects phage fitness and is strongly selected against. The repair of the RNA genome that we describe here appears as the result of random recombination. Of the plethora of recombinants, only those able to adopt a base-paired structure survive. The frequency with which our inserts are removed seems higher than measured by others for small inserts in a reading frame in Q beta RNA. To account for this higher frequency, we suggest models in which the single-stranded nature of our inserts induces random recombination at the site of the insertion.