Cycles, chaos, and evolution in virus cultures: a model of defective interfering particles

Dynamics of mutation and recombination in a replicating population of complementing, defective viral genomes

In a previous study, we documented that serial passage of a biological clone of foot-and-mouth disease virus (FMDV) at high multiplicity of infection (moi) in cell culture resulted in viral populations dominated by defective genomes that included internal in-frame deletions, affecting the L and capsid-coding regions, and were infectious by complementation. In the present study, analyses of the defective genomes present in individual viral plaques, and of consensus nucleotide sequences determined for the entire genomes of sequential samples, have revealed a continuous dynamics of mutation and recombination. At some points of high genetic instability, multiple minority genomes with different internal deletions co-existed in the population. At later passages, a new defective RNA arose and displaced a related, previously dominant RNA. Nucleotide sequences of the different genomic forms found in sequential isolates have revealed an accumulation of mutations at an average rate of 0.12 substitutions per genome per passage. At the regions around the deletion sites, substantial, minor or no nucleotide sequence identity is found, suggesting relaxed sequence requirements for the occurrence of internal deletions. Competition experiments indicate a selective advantage of late phase defective genomes over their precursor forms. The defective genome-based FMDV retained an expansion of host cell tropism, undergone by the standard virus at a previous stage of the same evolutionary lineage. Thus, despite a complex dynamics of mutation and recombination, and phases of high genetic instability, a biologically relevant phenotypic trait was stably maintained after the evolutionary transition towards a primitive genome segmentation. The results extend the concept of a complex spectrum of mutant genomes to a complex spectrum of defective genomes in some evolutionary transitions of RNA viruses.

Quasispecies in time-dependent environments

In recent years, quasispecies theory in time-dependent (that is, dynamically changing) environments has made dramatic progress. Several groups have addressed questions such as how the time scale of the changes affect viral adaptation and quasispecies formation, how environmental changes affect the optimal mutation rate, or how virus and host co-evolve. Here, we review these recent developments, and give a nonmathematical introduction to the most important concepts and results of quasispecies theory in time-dependent environments. We also compare the theoretical results with results from evolution experiments that expose viruses to successive regimes of replication in two or more different hosts.

Real-time quantitative PCR for the design of lentiviral vector analytical assays

From the recent and emerging concerns for approving lentiviral vector-mediated gene transfer in human clinical applications, several analytical methods have been applied in preclinical models to address the lentiviral vector load in batches, cells or tissues. This review points out the oldest generation methods (blots, RT activity, standard PCR) as well as a full description of the newest real-time quantitative PCR (qPCR) applications. Combinations of primer and probe sequences, which have worked in the lentiviral amplification context, have been included in the effort to dress an exhaustive list. Also, great variations have been observed from interlaboratory results, we have tempted to compare between them the different analytical methods that have been used to consider (i) the titration of lentiviral vector batches, (ii) the absence of the susceptible emerging replicative lentiviruses or (iii) the lentiviral vector biodistribution in the organism.

Quasispecies theory in the context of population genetics

BACKGROUND

A number of recent papers have cast doubt on the applicability of the quasispecies concept to virus evolution, and have argued that population genetics is a more appropriate framework to describe virus evolution than quasispecies theory.

RESULTS

I review the pertinent literature, and demonstrate for a number of cases that the quasispecies concept is equivalent to the concept of mutation-selection balance developed in population genetics, and that there is no disagreement between the population genetics of haploid, asexually-replicating organisms and quasispecies theory.

CONCLUSION

Since quasispecies theory and mutation-selection balance are two sides of the same medal, the discussion about which is more appropriate to describe virus evolution is moot. In future work on virus evolution, we would do good to focus on the important questions, such as whether we can develop accurate, quantitative models of virus evolution, and to leave aside discussions about the relative merits of perfectly equivalent concepts.

Molecular characterization of banana virus X (BVX), a novel member of the Flexiviridae family

A novel virus was identified in banana (Musa spp). Analysis of the last 2917 nucleotides of its positive strand genomic RNA showed five open reading frames corresponding, from 5' to 3', to a truncated ORF coding for a replication-associated protein, three ORFs coding for a movement-associated triple gene block (TGB) and a capsid protein (CP) gene. This genome organization is similar to that of some members of the Flexiviridae family such as potexviruses and foveaviruses. This virus was named Banana virus X (BVX). Comparative sequence analysis showed that BVX is only distantly related to other members of the Flexiviridae family, in which it appears to define a new genus. BVX produces defective RNAs derived from its genomic RNA by non-homologous recombination. Three distinct pairs of donor/acceptor recombination sites involving short direct nucleotide repeats were characterized, accounting for deletions of 1268, 1358 and 1503 nucleotides. Contrary to the situation encountered for Potexviruses, these recombination sites are located within the TGB1 and CP genes and result in a truncated TGB1 protein.

A segmented form of foot-and-mouth disease virus interferes with standard virus: a link between interference and competitive fitness

Serial passage of foot-and-mouth disease virus (FMDV) in BHK-21 cells at high multiplicity of infection resulted in dominance of particles containing defective RNAs that were infectious by complementation in the absence of standard viral RNA. In the present study, we show that the defective FMDV particles interfere with replication of the cognate standard virus. Coinfections of defective FMDV with standard FMDV mutants that differ up to 151-fold in relative fitness have documented that the degree of interference is higher for low fitness than for high fitness standard virus. These comparisons suggest a likely overlap between those mechanisms of intracellular competition that underlie viral interference and those expressed as fitness differences between two viruses when they coinfect the same cells. Interference may contribute to the selective pressures that help maintain dominance of segmented defective RNAs over the standard FMDV genome.

Phenotypic mixing and hiding may contribute to memory in viral quasispecies

BACKGROUND

In a number of recent experiments with food-and-mouth disease virus, a deleterious mutant, RED, was found to avoid extinction and remain in the population for long periods of time. Since RED characterizes the past evolutionary history of the population, this observation was called quasispecies memory. While the quasispecies theory predicts the existence of these memory genomes, there is a disagreement between the expected and observed mutant frequency values. Therefore, the origin of quasispecies memory is not fully understood.

RESULTS

We propose and analyze a simple model of complementation between the wild type virus and a mutant that has an impaired ability of cell entry, the likely cause of fitness differences between wild type and RED mutants. The mutant will go extinct unless it is recreated from the wild type through mutations. However, under phenotypic mixing-and-hiding as a mechanism of complementation, the time to extinction in the absence of mutations increases with increasing multiplicity of infection (m.o.i.). If the RED mutant is constantly recreated by mutations, then its frequency at equilibrium under selection-mutation balance also increases with increasing m.o.i. At high m.o.i., a large fraction of mutant genomes are encapsidated with wild-type protein, which enables them to infect cells as efficiently as the wild type virions, and thus increases their fitness to the wild-type level. Moreover, even at low m.o.i. the equilibrium frequency of the mutant is higher than predicted by the standard quasispecies model, because a fraction of mutant virions generated from wild-type parents will also be encapsidated by wild-type protein.

CONCLUSIONS

Our model predicts that phenotypic hiding will strongly influence the population dynamics of viruses, particularly at high m.o.i., and will also have important effects on the mutation-selection balance at low m.o.i. The delay in mutant extinction and increase in mutant frequencies at equilibrium may, at least in part, explain memory in quasispecies populations.

Real-time quantitative reverse transcriptase-polymerase chain reaction as a method for determining lentiviral vector titers and measuring transgene expression

The use of lentiviral vectors for basic research and potential future clinical applications requires methodologies that can accurately determine lentiviral titers and monitor viral transgene expression within target cells, beyond the context of reporter genes typically used for this purpose. Here we describe a quantitative RT-PCR (qRT-PCR) method that achieves both goals using primer sequences that are specific for the woodchuck hepatitis virus posttranscriptional regulatory element (WPRE), an enhancer contained in many retroviral vectors and that is incorporated in the 3' UTR of nascent transgene transcripts. Quantitation of titers of three recombinant lentiviruses, genetically identical except for the transgene, demonstrated consistent differences in titer that were likely due to transgene-associated toxicity in producer cells and target cells. Viruses encoding the tumor-associated antigens tyrosinase and neo-poly(A) polymerase yielded reproducibly lower titers than a virus encoding enhanced green fluorescent protein (GFP) at the viral RNA, integrated DNA, and transgene mRNA levels, as measured by WPRE qPCR. Furthermore, the magnitude of differences in expression of the three transgenes in transduced target cells could not have been predicted by measuring vector DNA integration events. Since transgene expression in target cells is the most common goal of lentiviral transduction, and since methods to quantify transgene expression on the protein level are not always readily available, qRT-PCR based on a nucleotide sequence included in the transcript provides a useful tool for titering novel recombinant lentiviruses.

Titering lentiviral vectors: comparison of DNA, RNA and marker expression methods

To better characterize lentiviral vector supernatants, we compared three methods of titer assessment. These titer methods include assessment of vector RNA sequences in supernatants, DNA sequences in transduced cells, and vector expression in transduced cells (using a vector which expressed the green fluorescence protein, GFP). For analysis of RNA and DNA, we developed a real-time PCR method for detecting the lentiviral packaging sequence and used this methodology to quantitate the number of vector sequences. Vector expression was assessed by flow cytometric analysis for GFP. As functional titers (DNA and GFP expression titers) are dependent on transduction efficiency, we calculated the titer of a lentiviral vector, RRL-CMV-GFP, after transduction of 293, HeLa, or Mus dunni cells. Genomic DNA was extracted at 4 and 14 days after transduction and the number of vector DNA molecules was determined against a plasmid standard. Of the three cell lines tested, 293 cells provided the highest rate of transduction (PCR estimated DNA titer for RRL-CMV-GFP vector was 2.52 +/- 0.25 x 10(6) molecules/ml at 14 days, and 2.31 +/- 0.15 x 10(6) molecules/ml at 4 days). When titer was calculated based on GFP expression, the highest titer was also obtained on 293 cells (0.26 +/- 0.04 x 10(6) TU/ml at 14 days, and 0.24 +/- 0.03 +/- 10(6) TU/ml at 4 days). The titers obtained by GFP expression assay were approximately one log lower than those obtained by DNA analysis suggesting that variability in vector expression may underestimate titer. Measurement of RNA titers directly from vector supernatants against a plasmid standard indicated that the RNA titers are substantially higher than the DNA (approximately 10(3)-fold) and GFP titers (approximately 10(4)-fold). To show that the lentiviral probe and primers could be used for titering a variety of lentiviral vectors, we have also used the real-time PCR method to determine the DNA titers of two other HIV1 derived vectors, RRL-PGK-GFP (6.1 +/- 1.4 x 10(5) molecules/ml), and SMPU-RRE-BN (1.26 +/- 0.2 x 10(6) molecules/ml). We conclude that of the three methods tested, titers assessed by DNA analysis of transduced cells provide the most reliable estimate of functional titers as these are least likely to be influenced by factors, such as defective interfering particles and vector expression levels. The real-time PCR method described offers a reproducible method for lentiviral titering and can be applied to a wide variety of vectors, regardless of transgene.

Multiplicity of infection and the evolution of hybrid incompatibility in segmented viruses

Some viral genomes are divided into segments. When multiple viruses infect a single cell, progeny form by reassorted mixtures of genomic segments. Hybrid incompatibilities arise when a progeny virus has incompatible segments from different parental viruses. Hybrid incompatibility has been observed in influenza and in the multiparticle plant virus Dianthovirus. Hybrid incompatibility provides an opportunity to study rates of viral evolution, divergence and speciation, and the extent of epistatic interactions among components of the viral genome. This paper presents mathematical and computer simulation models to study hybrid incompatibility between diverging strains. The models identify multiplicity of infection as a key factor. When many viral particles infect each host cell, the effective ploidy of the genetic system is high. High ploidy dilutes the contribution of each locus to the phenotype, weakening the selective intensity on each locus. Weaker selection on variant alleles allows the population to maintain greater genetic diversity and to be more easily perturbed by stochastic fluctuations. Greater diversity and stochastic fluctuations explore more widely the space of epistatic interactions, causing more frequent shifts among favoured combinations of alleles. Variable ploidy of viral genetics differs from standard Mendelian genetics.

RNA replication kinetics, genetic polymorphism and selection in the case of the hepatitis C virus

We show in a simple theoretical quasispecies model that the replication dynamics of hepatitis C virus and a related model-system, the bovine viral diarrhoea virus, result in an effective reduction of RNA templates in infected cells. Viral fitness does not translate directly into RNA sequence replication efficiency, and hence the abundance of the viral master sequences diminishes over time. Our results suggest that genes not involved in RNA replication accumulate mutations over time because they do not undergo selection during this phase. The selection of viral RNA occurs not only during replication but also during the ensuing stages of the viral life cycle: (i) envelopment of viral RNA and (ii) successful infection of other cells, which also requires functionality of non-replicative genes. In particular, viral fitness requires the ability of the genome to encode structural proteins which do not encounter selective pressure during RNA replication. We conclude by discussing the potential value of antiviral drugs which inhibit selection on parts of the viral genome.

Variability and genetic structure of plant virus populations

Populations of plant viruses, like all other living beings, are genetically heterogeneous, a property long recognized in plant virology. Only recently have the processes resulting in genetic variation and diversity in virus populations and genetic structure been analyzed quantitatively. The subject of this review is the analysis of genetic variation, its quantification in plant virus populations, and what factors and processes determine the genetic structure of these populations and its temporal change. The high potential for genetic variation in plant viruses, through either mutation or genetic exchange by recombination or reassortment of genomic segments, need not necessarily result in high diversity of virus populations. Selection by factors such as the interaction of the virus with host plants and vectors and random genetic drift may in fact reduce genetic diversity in populations. There is evidence that negative selection results in virus-encoded proteins being not more variable than those of their hosts and vectors. Evidence suggests that small population diversity, and genetic stability, is the rule. Populations of plant viruses often consist of a few genetic variants and many infrequent variants. Their distribution may provide evidence of a population that is undifferentiated, differentiated by factors such as location, host plant, or time, or that fluctuates randomly in composition, depending on the virus.

Packaging cell line characteristics and optimizing retroviral vector titer: the National Gene Vector Laboratory experience

During the production of clinical-grade retroviral vector supernatant, we noted significant differences in the lactate production and glucose consumption of various producer cell lines submitted to the National Gene Vector Laboratory (NGVL). Since differences in growth characteristics could be important in determining the optimal culture conditions for maximizing titer, we studied the growth characteristics of three commonly used packaging cell lines: PA317, PG13 and GP+envAM12. A transformed phenotype, assessed by the ability to form colonies in semisolid media, was evident in all three packaging cell lines tested. In confluent cultures, the rates of glucose consumption and lactate production (per cell per hour) were similar for the three lines tested, but the growth rate and culture density varied. PA317 and PG13 continued to expand after reaching confluence, resulting in higher cell densities and subsequent rapid depletion of glucose within the 24-hr observation period. When the cell lines were evaluated for titer optimization, the slower growing packaging cell line GP+envAM12 generally provided the highest titer after 8 hr of culture in confluent roller bottles, while most vectors introduced into PA317 and PG13 cells yielded optimal titers after 24 hr of culture. We also found that the improved titers obtained by culturing cells at 32 degrees C previously reported for PA317 cells do not apply to other packaging cell lines. In particular, PG13 rapidly lost titer when grown at the lower temperature. Our findings suggest that optimization of titer requires careful consideration of the culture conditions, which should be individualized for the vector producer cell line.

Within-host spatial dynamics of viruses and defective interfering particles

Defective-interfering (DI) viruses arise spontaneously by deletion mutations. The shortened genomes of the DI particles cannot replicate unless they coinfect a cell with a wild-type virus. Upon coinfection, the DI genome replicates more quickly and outcompetes the wild type. The coinfected cell produces mostly DI viruses. At the population level, the abundances of DI and wild-type viruses fluctuate dramatically under some conditions. In other cases, the DI viruses appear to mediate persistent infections with relatively low levels of host cell death. This moderation of viral damage has led some to suggest DI particles as therapeutic agents. Previous mathematical models have shown that either fluctuation or persistence can occur for plausible parameter values. I develop new mathematical models for the population dynamics of DI and wild-type viruses. My work extends the theory by developing specific predictions that can be tested in the laboratory. These predictions, if borne out by experiment, will explain the key processes that control the diversity of observed outcomes. The most interesting prediction concerns the rate at which killed host cells are replaced. A low rate of replacement causes powerful epidemics followed by a crash in viral abundance. As the rate of replacement increases, the frequency of oscillations increases in DI and wild-type viral abundances, but the severity (amplitude) of the fluctuations declines. At higher replacement rates for host cells, nearly all cells become infected by DI particles and a low level of fluctuating, wild-type viremia persists.

Rapid titer determination using quantitative real-time PCR

Quantitative real-time PCR was utilized to evaluate retroviral vector titer. RNA was prepared from vector supernatant and run in a one-step RT-PCR reaction combining reverse transcription (RT) and amplification in one tube. Sample analysis was performed in the ABI Prism 7700 Sequence Detector. PCR was quantitative over a range of 101 to 6 x 105 vector particles per reaction (2 x 102 to 1 x 107 vector particles per millilites of supernatant) and closely corre- lated with biologic titers performed on the test material. The 96-well capacity of the machine and 2 h of running time permit titer determinations within 8 h, facilitating the processing of large sample numbers while greatly decreasing technician time. Real-time PCR improves titer quantification and the identification of high-titer producer cells. This methodology will help investigators meet the challenges of developing vectors which lack selectable markers.

Influence of sequence and size of DNA on packaging efficiency of parvovirus MVM-based vectors

We have derived a vector from the autonomous parvovirus MVM(p), which expresses human IL-2 specifically in transformed cells (Russell et al., J. Virol 1992;66:2821-2828). Testing the therapeutic potential of these vectors in vivo requires high-titer stocks. Stocks with a titer of 10(9) can be obtained after concentration and purification (Avalosse et al., J. Virol. Methods 1996;62:179-183), but this method requires large culture volumes and cannot easily be scaled up. We wanted to increase the production of recombinant virus at the initial transfection step. Poor vector titers could be due to inadequate genome amplification or to inefficient packaging. Here we show that intracellular amplification of MVM vector genomes is not the limiting factor for vector production. Several vector genomes of different size and/or structure were amplified to an equal extent. Their amplification was also equivalent to that of a cotransfected wild-type genome. We did not observe any interference between vector and wild-type genomes at the level of DNA amplification. Despite equivalent genome amplification, vector titers varied greatly between the different genomes, presumably owing to differences in packaging efficiency. Genomes with a size close to 100% that of wild type were packaged most efficiently with loss of efficiency at lower and higher sizes. However, certain genomes of identical size showed different packaging efficiencies, illustrating the importance of the DNA sequence, and probably its structure.

Experimental evolution of complexity: in vitro emergence of intermolecular ribozyme interactions

In the course of evolving variants of the Tetrahymena thermophila Group I ribozyme for improved DNA cleavage in vitro, we witnessed the unexpected emergence of a derived molecular species, capable of acting as a partner for the ribozyme, but no longer autocatalytic. This new RNA species exhibits a deletion in the catalytic core and participates in a productive intermolecular interaction with an active ribozyme, thus insuring its survival in the population. These novel RNA molecules have evolved a precise catalytic interaction with the Group I ribozyme and depend for their survival on the continued presence of active catalysts. This interaction hints at the complexity that may inevitably arise even in simple evolving systems.

New satellite RNAs, but no DI RNAs, are found in natural populations of tomato bushy stunt tombusvirus

A collection of 57 field isolates of the tombusvirus tomato bushy stunt virus was obtained from eggplant and tomato during 1994-1997 and was examined for the presence of defective interfering (DI) RNA species by Northern blot hybridization and RT-PCR. No DI RNA species were detected associated with any of the field TBSV isolates. However, serial passaging of two field isolates in Nicotiana clevelandii at high multiplicity of infection resulted in the rapid generation of DI-like RNA species, indicating that the absence of DI RNAs in natural populations of the virus was not due to the inability of the TBSV field isolates to generate them in a suitable host. The results indicate that DI RNAs may not play a role in modulating natural TBSV infections in the hosts examined. In 4 of 57 isolates analyzed we have detected less than full-length RNAs and we show here that they are true satellite RNAs. Two different satellite RNA species were detected, named TBSV sat RNAs B1 (822 nt) and B10 (612 nt). TBSV sat RNAs lack significant open reading frames and do not present sequence homology except in a central box that is also conserved in TBSV-Ch genomic RNA and in all the DI RNAs derived from it. TBSV sat RNA B10 attenuated the symptoms induced by the helper virus in N. clevelandii while sat RNA B1 did not modify the symptoms. This is the first report of sat RNAs associated with TBSV and the first time that sat RNAs are associated with natural tombusvirus infections.

Involvement of a subgenomic mRNA in the generation of a variable population of defective citrus tristeza virus molecules

The fusion sites between the termini of naturally occurring defective RNAs (D-RNAs) from three citrus tristeza virus (CTV) isolates were sequenced. Seven of eight clones showed a common 3' terminus of 940 nucleotides (nt) fused to 5' termini with different sizes. An extra cytosine nucleotide was found at the junction site of the majority of the common 3' D-RNAs. Molecular analysis of the plus and minus strands of the 0.9-kbp double-stranded RNA, corresponding to the CTV open reading frame 11 subgenomic RNA (sgRNA), showed that they were identical in length and sequence to the common 3' sequence of the D-RNAs. These results imply that viral sgRNA messengers also function as building components for genomic rearrangement and exchange of complete viral genes.

A mutation in tomato aspermy cucumovirus that abolishes cell-to-cell movement is maintained to high levels in the viral RNA population by complementation

The nucleotide substitution C-->A at nucleotide 100 of tomato aspermy cucumovirus (TAV) strain V (V-TAV) RNA segment 3 (RNA3) introduces an ocher stop at the fourth codon of the movement protein open reading frame. Experiments with RNA transcripts from full-length clones showed that this mutation abolished cell-to-cell movement and, thus, infectivity in planta. Heterogeneity analyses on stock V-TAV virion RNA showed that an A at position 100 was present in the molecular population of RNA3 at a frequency of 0.76 and that a C at this position was present at a frequency of 0.24. This result indicates that a fraction of RNA3 molecules complements cell-to-cell movement of movement-defective molecules. It was shown that the mutation C-->A conferred enhanced RNA replication of the defective mutant in tobacco protoplasts. The effect of the mutation on replication was dependent on sequence context, since the same mutation did not affect the replication efficiency in the related TAV strain 1 RNA3. Competition experiments in tobacco protoplasts were done to estimate the fitness during a cell invasion cycle of the movement-defective mutant relative to the wild type (wt). From these data, a lower limit to the degree of complementation of movement-defective molecules by movement-competent ones could be estimated as 0.13. This estimate shows that complementation may play an important role in the determination of genetic structure in RNA genome populations. A further effect of the enhanced replication of the movement-defective mutant was the efficient competition with the wt for the initiation of infection foci in planta.

30 years later--a new approach to Sol Spiegelman's and Leslie Orgel's in vitro evolutionary studies. Dedicated to Leslie Orgel on the occasion of his 70th birthday

The conditions necessary for evolution are amplification, mutagenesis and selection. Here we describe the evolutionary response of an in vitro replicating system to the selection pressure for fast growth and show what happens to the amplified molecules within this replication system. Our emphasis is on methodology, on the monitoring and the automation of experiments in molecular evolution. In order to perform in vitro studies on the evolution of RNA molecules, a modified self-sustained sequence replication (3SR) method was used. In the first step of the 3SR reaction, the RNA template is reversely transcribed by HIV-1 reverse transcriptase, followed by a second strand synthesis and the transcription of the resulting dsDNA by T7 RNA polymerase. The selection pressure (fast growth) was achieved by applying the principle of serial transfer pioneered in the laboratories of Sol Spiegelman and Leslie Orgel. At the end of the exponential growth phase of the 3SR reaction, an aliquot of the reaction mixture is transferred into a new sample containing only buffer, nucleotides and enzymes while RNA template molecules are provided by the transfer. The conditions in the exponential growth phase allow the RNA molecules to be amplified in a constant environment; all enzymes (HIV-1 reverse transcriptase and T7 RNA polymerase) and nucleotides are present in large excess. Therefore, transferring reproducibly within the exponential growth phase is equivalent to selecting for fast growth; those molecules which can replicate faster will displace others after several transfers. The experiments were performed using a serial transfer apparatus (STA) which allows the nucleic acid concentration to be monitored on-line by measuring the laser-induced fluorescence caused by intercalation of thiazole orange monomers into the RNA/DNA amplification products. The serial transfer experiments were carried out with an RNA template (220b RNA) that represents a 220-base segment of the HIV-1 genome and comprises the in vivo primer binding site (PBS) for the HIV-1 reverse transcriptase. It could be shown that after only two serial transfers two RNA species (EP1 and EP2) emerged that were much shorter. EP1 (48b) and EP2 (54b) were formed by deletion mutations within the original 220b RNA template in the very beginning of the serial transfer experiment; due to their higher replication rate (calculated from the growth curves derived on-line) these two deletion mutants displaced the original 220b RNA template in the course of the following thirty transfers. We assume that these two RNA species evolved independently of each other. Their formation was probably induced by a strand-transfer reaction of HIV-1 reverse transcriptase. Sequence analyses of these two evolution products seem to confirm such a presented pathway. 30 years after Spiegelman's experiment, the study described here is another answer to the question he posed: 'How do molecules evolve if the only demand is the biblical injunction: multiply?'. The answer, derived from a modified 3SR amplification system (mimicking a part of the HIV-1 replication cycle in vitro), is the same as thirty years ago: The RNA molecules adapt to the new conditions by throwing away any ballast not needed for fast replication. Clearly, this is only one aspect of molecular evolution; however, it shows that we should be careful in designating unidentified genetic material as 'junk DNA'.