Selection for Replicases in Protocells

Ginestra Bianconi; Kun Zhao; Irene A. Chen; Martin A. Nowak

doi:10.1371/journal.pcbi.1003051

Abstract

We consider a world of nucleotide sequences and protocells. The sequences have the property of spontaneous self-replication. Some sequences - so-called replicases - have enzymatic activity in the sense of enhancing the replication rate of all (or almost all) sequences. In a well-mixed medium, natural selection would not favor such replicases because their presence equally benefits sequences with or without replicase activity. Here we show that protocells can select for replicases. We assume that sequences replicate within protocells and that protocells undergo spontaneous division. This leads to particular population structures which can augment the abundance of replicases. We explore various assumptions regarding replicase activity and protocell division. We calculate the error threshold that is compatible with selecting for replicases.

Author Summary

The origin of life, proceeding from chemical reactions to cells, must have included a critical transitional period in which catalytically active sequences arose. A fundamental problem exists for the first catalytic sequences: their activity would not enhance their own fitness directly, and might even decrease their own fitness relative to that of other molecules. Catalytic sequences are constantly encumbered by mutation and drift, limiting the amount of information that can be maintained. Population structures, such as cells, are known to be able to counter this problem. Here we introduce a simple model of the earliest cells to understand limits on information for catalysts with different properties. We find some parallels to information limits on replicators in free solution. Conditions that keep replicases together, or enhance their effect as their abundance increases, permit the evolution of catalytically active sequences.

Citation: Bianconi G, Zhao K, Chen IA, Nowak MA (2013) Selection for Replicases in Protocells. PLoS Comput Biol 9(5): e1003051. https://doi.org/10.1371/journal.pcbi.1003051

Editor: Michael Doebeli, University of British Columbia, Canada

Received: November 24, 2012; Accepted: March 20, 2013; Published: May 9, 2013

Copyright: © 2013 Bianconi et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: Support from the John Templeton Foundation (http://www.templeton.org/) and from the Foundational Questions in Evolutionary Biology Fund (http://www.fas.harvard.edu/~fqeb/grants/) - grant RFP-12-05 - is acknowledged. Publication fees were supported by the UCSB Open Access Fund Pilot Program (http://www.library.ucsb.edu/scholarly-communication/ucsb-open-access-fund-pilot-program). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

The origin of life must have required a series of transitions building new levels of molecular interaction. However, a tension often exists between the fitness of an individual sequence and the fitness of the collective [1], [2]. This tension would be important for the earliest replicase enzymes (i.e., replicases), which would help other individuals replicate without helping themselves directly [3]. Indeed, replicase activity cannot be selected in a thoroughly mixed solution, as natural selection favors the evolution of sequences that parasitize the replicases. The proposed solution to this problem is to essentially create small groups of interactors, either by compartmentation or a lattice-like structure [4]–[12]. Selection among individuals in the group favors parasites, but selection at the level of the group favors groups with more replicases, thus allowing ‘altruistic’ replicases to survive [13], [14].

Compartments, in the form of membrane vesicles, have become an important experimental model for protocells [15]–[18]. Amphiphilic molecules, such as fatty acids, that can form membrane boundaries can be produced abiotically [19]–[23] and are found in samples from carbonaceous chondrite meteorites [24]–[27]. Indeed, vesicles can be formed from meteoritic organic extracts dissolved in water [28]. Recent work on model protocell membranes has demonstrated that vesicles can grow through filamentous structures and divide spontaneously by mild shear forces or photochemical stimulation, a robust ‘pearling’ mechanism that produces many small daughter vesicles [29], [30]. Interestingly, experimental studies of cell division mutants in bacteria also suggest that cells divide by pearling when the cell division machinery is eliminated [31]. Pathways for vesicle fission into two daughter vesicles have also been observed, again stimulated by growth [32]–[34]. Ribozyme reactions and non-enzymatic polymerization reactions can be encapsulated inside experimental protocells [35], [36]. Supramolecular assemblies might have a role in promoting polymerization, as demonstrated by the observation that ribozyme-catalyzed RNA polymerization is more efficient if confined to micelles [37]. Inspired by these promising protocell experiments, we focus on vesicles in the theoretical study that follows.

Previous models of compartmentation by vesicles have studied the ability of vesicles to enhance information storage and affect replicase selection. Prior models have usually assumed that the encapsulated genotypes influence vesicle replication (i.e., growth, survival, or division), causing selection among vesicles. Encapsulation has been shown to increase information capacity if vesicle survival depends on the simultaneous presence of multiple self-replicating (i.e., not necessarily replicase) ‘genes’ [4], [10]. In a model by Hogeweg and Takeuchi [7], encapsulation could increase information capacity if the best self-replicators also enhanced vesicle replication, but not if vesicle replication was neutral (i.e., division occurred when the molecular population size reached a certain number). With respect to the evolution of enzymatic activity, replicase dynamics were studied in spatial grids [6], where replicases were found to evolve greater fidelity and information capacity, essentially due to reciprocal altruism in local clusters. However, the generality of this model is unclear, as certain tradeoffs were assumed to exist between replication fidelity, efficiency, and templating ability, and vesicular protocells were not studied. Takeuchi and Hogeweg studied the survival of replicase enzymes (and their parasites) in vesicles, in which parasites were also assumed to contribute to vesicle growth [11]. The dynamics were complicated, but in general selection at the compartment level could counter selection among replicases. Furthermore, stochastic fluctuations have been shown to be important for switching from a ribozyme-poor to a ribozyme-rich regime, a situation that could be enabled by compartmentation into protocells [38], [39].

While recent progress has been made in evolving an RNA enzyme that can copy another RNA sequence [40]–[42], the difficulty of this task has prompted several suggestions for simpler enzymatic activities that might have preceded the polymerase. Any activity that could promote replication would be considered a replicase. For example, RNA sequences that catalyze ligation could stitch together short oligos in a template-directed manner [43]–[46]; an exonuclease could enhance speed and fidelity by removing dangling mismatched ends [47]; a permease could increase the rate of heterotrophic uptake [36]. Cooperative phenotypes may also characterize early autocatalytic replicator cycles, such as systems of ligases or recombinases [43], [48]–[51]. Broadly speaking, in even simpler terms, a replicase might act through colligative properties rather than sequence-specific interactions. For example, an osmolyte might reduce evaporative loss, or a charged polymer might trap useful oppositely charged species. Osmotic pressure has already been shown to drive membrane growth [52]. Such simple chemical activities, while not enzymatic, are weakly altruistic in the sense that they help themselves and other molecules equally.

In light of recent experimental progress, we re-examine the conditions under which enzymatic activity can be selected, using a simple but plausible model of encapsulated replicases and inactive molecules. We first consider a scenario, in which the replicase helps all molecules within a protocell to replicate and is not itself impaired as a template. Then we consider a more altruistic enzyme, which can help other molecules but not itself directly. Vesicle division in our model occurs when the encapsulated population size reaches a certain threshold, but the replicases and vesicles are otherwise unlinked. We calculate the conditions under which altruistic enzymatic activity can be selected.

Results

We consider two types of sequences. Type can act as replicase, potentially enhancing the replication of sequences of any type, but type cannot. All sequences undergo spontaneous self-replication, and moreover all sequences are targets of replicase activity. Thus all sequences benefit equally from the presence of type sequences. Type does not have an intrinsic preference to catalyze the replication of other type sequences; it treats all targets equally. It is evident that natural selection would not augment the abundance of type sequences in a well-mixed population. At best, the type sequences would have the same fitness as all other molecules, so they have no selective advantage. However, sequences can be erroneously copied to produce sequences, which causes the population to drift toward an all- state. Back mutation from to can be neglected, because a specific sequence is needed for replicase activity. Type represents a small fraction of possible sequences, while all other sequences are of type .

The probability that a type sequence replicates without mutation is given by . If a type A sequence replicates with mutation, the offspring will be a type sequence; this happens with probability . We can think of a point mutation rate, , and a number of positions, , which must remain unchanged in order to retain replicase activity. For example, has been estimated to be roughly 75% of the physical length of a functional RNA molecule [53]. Then we have . Replication of type sequences always results in type ; thus we neglect back-mutation. In a well-mixed population type sequences would become extinct for any positive mutation rate, .

Let us now study the evolutionary dynamics of and sequences within protocells. Denote by a protocell, which contains sequences of type and sequences of type . If an sequence replicates within this protocell without mutation we obtain . If an sequence replicates with mutation, or if a sequence replicates, we obtain .

We explore four different replicases that enhance the replication rate of the molecules within the protocell in different ways. In each case the sequence represent a different type of replicase, which we label , , and (see Figure 1).

Download:

Figure 1. Effect of the replicase in different models.

Three possible protocells are shown for each model, each containing four sequences, including 0, 1, or 2 sequences of type A (red) and the remainder being type B (black). The replication rate of each sequence is shown in brackets under the sequence. Sequences that receive benefit from the replicase(s) are shown in bold type (i.e., replication rate ). As in the main text, and . In and , type A sequences enhance replication of all A and all B, such that all sequences in the cell have the same replication rate. In and , type A molecules enhance replication of other molecules but not themselves. In and , the effect of a single A is maximal. In and , the presence of multiple As increases the rate enhancement.

https://doi.org/10.1371/journal.pcbi.1003051.g001

Replicase has the following property: the presence of at least one sequence inside a protocell enhances the replication rate of all sequences within that protocell to a value , which is greater than 1. In a protocell that contains only type sequences the replication rate is 1.
Replicase has the following property: the presence of an sequence within a protocell augments the replication rates of all other sequences in this protocell, but not its own. Thus, if there is only a single sequence present in a protocell, then all other sequences have an increased replication rate, , while the sequence has replication rate 1. If at least two sequences are in a protocell, then all sequences in that protocell have an increased replication rate, .
Replicase has the following property: the replication rate increases with the number of sequences inside a protocell. In particular, we assume that if there are sequences inside a protocell, the replication rate of all sequences within that protocell is , where . In a protocell that contains only type sequences the replication rate is 1.
Replicase has the following property: the replication rate increases with the number of sequences inside a protocell, but a single sequence does not enhance its own replication rate. In particular, we assume that if there are many sequences inside a protocell, the replication rate of all A sequences within that protocell is , and the replication rate of all B sequences within that protocell is , where . For , A sequences receive less advantage than B sequences, as might be expected if the replicase acts directly on other sequences.

In Figure 2 we show the reaction kinetics for all four types of replicases.

Download:

Figure 2. Reaction kinetics for protocells of different composition for the four replicases considered in this paper.

The sequences of type A indicate the replicases. All sequences undergo spontaneous self-replication and are targets of replicase activity. The sequences of type B, in absence of sequences of type A in the protocell, replicate at rate 1. A type A sequence replicates with mutation with probability , and the offspring will be a type B sequence. If the sequences encode the replicase , it is sufficient that at least one sequence of type A is present in the protocell for enhancing the replication of every sequence in the same protocell to . If the sequences encode for the replicase , the sequences enhance the rate of replication of all the other sequences to . If the sequences encode the replicase , and there are A sequences in the protocell, the rate of all the sequences is given by with . If the sequences encode the replicase , and there are A sequences in the protocell, the rate of the A sequences is given by while the rate of replication of the B sequences is with α>0.

https://doi.org/10.1371/journal.pcbi.1003051.g002

Replication within a protocell increases the number of sequences inside the protocell. We assume that the cell divides once a certain maximum number, , of sequences has been reached. We consider two types of cell division. (i) Division into two: each sequence of the parent cell is given at random to one of the two daughter cells. (ii) Division into many: each daughter cell contains exactly one sequence. In both cases we do not need to keep track of empty cells. In Figure 3 we show how the different mechanisms for cell division work for a protocell of maximal size .

Download:

Figure 3. Division mechanism.

When a protocell reaches the maximum size , it splits. Here we consider two splitting mechanisms. In the first case the protocell splits into two daughter protocells, of random composition, with each protocell containing at least one sequence. In the second case, the protocell splits into daughter protocells, and each daughter protocell contains a sequence.

https://doi.org/10.1371/journal.pcbi.1003051.g003

For replicase we obtain the following, surprisingly simple result irrespective of the number and irrespective of whether cells divide into two or into many. sequences can be maintained in the population if whereIf the probability of error-free replication, , is greater than , then replicases can be selected within protocells. The result is reminiscent of the error-threshold of quasispecies theory, which describes the selection of a master sequence (not a replicase) in a well-mixed medium [54]–[56].

For replicase it is harder to select for sequences. The reason is that an sequence can only help other sequences to reproduce but not itself. Again we find an error threshold, but this time we do not obtain a simple closed form expression. We derive a numerical solution, which is shown in Figure 4. We observe that division into two daughter cells leads to less restrictive conditions (for given ) than division into many. In this case if protocells divide into many daughter cells, then each sequence starts off alone within a cell; here single sequences have no advantage over single sequences. On the other hand, if protocells divide into two, then for larger it is typically the case that each sequences is together with other sequences after cell division and immediately benefits from the enzymatic activity.

Download:

Figure 4. Error threshold for the four replicases under study.

In the left panels the protocells of maximal size divide into two daughter cells. In the right panels the protocells of maximal size divide into many () daughter cells. Curves were generated by numerical simulation as described in the text.

https://doi.org/10.1371/journal.pcbi.1003051.g004

For replicase , we can prove (see Materials and Methods and Text S1) that the error threshold satisfies the following inequalityOur numerical solution of the error threshold shown in Figure 4 demonstrates that this upper limit is tight for large values of . These results are valid when we consider division into two as well as division into many.

Replicase can only help other sequences to reproduce but not themselves. Therefore we find that is more difficult to select than (see Figure 4). We observe that division into two leads to less restrictive conditions (for given ) than division into many. We can explain this phenomenon with the same argument used to explain why it is more difficult to select for than for (see above).

We have conducted numerical calculations of the error threshold for values of between and . We observe that for the error threshold is a decreasing function of the maximum number of encapsulated sequences . We find a similar behavior of the error threshold for and as long as the protocells split into many daughter cells. In this case, for larger it is easier to select for these replicases. But if the protocells divide into two, we observe for and that the error threshold for a given (or ) does not always decrease with . Instead there is an optimum cell size which favors selection of the replicase.

Discussion

We have studied the constraints on the information content of a replicase arising in protocells. Mutations that produce inactive variants of the replicase are an inevitable consequence of molecular replication, creating parasitic or commensal sequences that derive benefit from the presence of the replicase. The population structure imposed by the protocell membranes can prevent loss of the replicase. We investigated four types of replicases and two types of division. Table 1 summarizes our results, showing the maximum genome length (i.e., number of invariant, informative sites), given experimental parameters for error rates and a prebiotically plausible replication enhancement from the presence of the replicase. The experimental error rates cover a reasonable range, from the misincorporation rate of non-enzymatic RNA replication (representing the lowest fidelity reaction one might consider) to the error rate of an RNA polymerase replicase producing full-length copies (a recently reported replicase with relatively high fidelity) [40], [57]. The results also depend on the value of or . In Table 1, a low value was chosen (, ) to represent early, relatively poor replicases, but the absolute numbers would increase with greater replicase activity (See Table S1 in Text S1 for analogous calculations for ). It is also important to note that is the number of invariant sites, so the physical length of the molecule could be greater [53]. In addition, very small replicases have been reported (as small as 5 nt; [58]), so it is conceivable that low-information sequences could potentially act as weak replicases.

Download:

Table 1. Maximal length of the selected replicase

.

https://doi.org/10.1371/journal.pcbi.1003051.t001

There are many possible chemical functions that could enhance molecular replication within the cell. Two major categories of replicases are those whose presence helps all molecules in the cell, including itself (a commensal situation; replicases and ), and those whose presence helps other molecules in the cell but not itself (an altruistic situation; replicases and ). Commensal ‘replicases’ might have beneficial colligative properties. These represent a very early stage of evolution, in which sequences did not necessarily perform specific functions and could be poorly folded. For example, this situation might apply to the selection of the chemical backbone (e. g., RNA) itself. On the other hand, altruistic replicases might perform any number of specific functions, and indeed any RNA that folded into a stable structure would have a compromised fitness for template replication compared to poorly folded RNAs. Intuitively, it is therefore more difficult for an altruistic replicase to survive, so less information can be maintained, as we observe in our results (Table 1).

One analytical result of particular interest is the form of the error threshold for in protocells (). This form is identical to the form of the classical error threshold considering a ‘master’ replicator sequence with fitness competing with its mutants () [59], [60]. If enzymes are encapsulated in protocells, it seems that selection has effectively moved up to the next level, from competition among individual replicator sequences to competition among protocells based on the encapsulated genotypes. The collective advantage takes the place of the individual advantage , and the survival of the enzyme depends on the mutation rate just like a ‘master’ sequence would in free solution.

The dependence of replication enhancement on the number of replicases is likely to increase linearly initially, and then to saturate at some point. We examined these two regimes separately. To examine the saturated regime, we assumed that a single copy of (commensal) or (altruistic) produced the maximal effect on replication rates. (commensal) and (altruistic) represent the analogous initial regimes, respectively. These two regimes give similar limits on information, particularly at large values of , but slightly more information could be maintained in the initial, non-saturated regime. Intuitively, if protocells containing multiple replicases have greater advantage, the overall benefit from the presence of the replicase is greater, allowing more information to be maintained at the same mutation rate.

Cell division typically proceeds via binary fission, or division into two daughter cells. In addition, some model protocells divide by fissioning into many daughter vesicles as described earlier. Bacteria lacking cell division machinery also appear to divide by fissioning into many small cells [31]. We therefore modeled two limiting scenarios for division mechanisms: division into two daughter vesicles, and division into many daughter vesicles (i.e., more daughter vesicles than encapsulated replicators, Figure 3). In general, binary fission is better in terms of maintaining genetic information. Intuitively, binary fission can keep replicases together so they benefit from one another, while division into many vesicles immediately isolates the replicases from each other.

Like previous theoretical models [7], we assume that division occurs upon reaching a particular size (a number of encapsulated sequences). In general, larger is more permissive to the replicases, allowing more information to be stored because replicases can group together more of the time, enhancing the mutual benefit. In our case, for R1, there is no disadvantage for isolated single replicase molecules, and we obtain that group size is irrelevant to the error threshold. For R2, the replicase is disadvantaged compared to the mutant sequences, but the addition of mutant sequences does not further decrease the fitness of the replicase; in addition, if two replicases are present, then the replicases do not suffer the disadvantage in the protocell.

The effect of cell size, , is in contrast with group selection models based on cooperator-defector games, in which larger group size makes selection of the cooperator trait more difficult [9]. In those models, larger groups are more likely to generate defectors (by mutation), which then take over the entire group because of their intrinsic selective advantage. In our current model, larger cells are also more likely to produce non-catalytic (type ) sequences by mutation, but they do not have a selective advantage; they rely on mutation pressure and drift to take over a cell.

To summarize, an RNA replicase arising during the origin of life would be most able to resist mutational pressure under the following conditions: the ability to enhance its own fitness, compartmentalization (which permits selection of the enzymatic behavior), additive enhancement from multiple replicases, larger cell size, and binary fission of compartments. The replicases might correspond to a number of different possible chemical activities. For example, and could correspond to a bulk chemical activity (e.g., charged polymer) that enhances replication for all encapsulated sequences (e.g., by attracting oppositely charged ‘food’ molecules) without impacting its own replication. and could correspond to a ribozyme with a specific folded structure, which benefits other sequences but not itself directly, such as an RNA polymerase or a membrane transporter.

In conclusion, we have attempted to present the simplest possible models for the selection of enzymatic activity that are inspired by experimental protocells. We estimate the conditions that enable survival of the replicase trait. We focused on simple models in order to understand the underlying dynamics. However, this work could potentially be extended to include more realistic chemical detail, as found in other recent modeling [61]. Other processes could also be included, such as exchange of genetic material among protocells [62]. Another important consideration is that our modeling is deterministic, as a first step in understanding the system. Although the number of RNAs per protocell is small, the number of protocells may be large, justifying a deterministic approach. However, a stochastic approach would be more realistic and could highlight interesting phenomena [38], [39]. Also, in our model, we assume that some A is present in the initial pool, and therefore survival of A depends on the error criterion. Because we neglect back-mutation of B into A, A cannot be generated de novo in our model; a more realistic model would include the possibility of back-mutation. In addition, our model includes the decay or degradation of protocells (and thus the replicases contained within them), but not of individual sequences within the protocells. This corresponds to the assumption that the removal of protocells (e. g., by dilution), rather than destruction of individual sequences, is the dominant process of decay. Thus, a system containing A's could transition to an all-B system through loss of protocells containing A's. A more realistic model would include differential decay of molecules within the protocells as well. Further studies would be needed to test the effects of such realistic modifications to the models. Notwithstanding additional complexities, we find that replicases can be selected under a variety of assumptions. In the simplest case we observe an error threshold arising from protocell competition, in striking analogy to replicator competition. That is, the condition for replicase selection in protocells mirrors the classical condition for replicator selection [54], [59], suggesting the emergence of a new level of selection in which protocells are a mathematical analog to replicators. In addition, we find that conditions that tend to keep replicases together, or enhance their effect as their abundance increases, permit evolution of more information.

Materials and Methods

The mutation-selection-cell division (MSCD) equations

We indicate with the frequency of protocells of composition . In the Text S1 we describe the mutation-selection-cell division (MSCD) equations for the general case. Here we show how the model reads for replicase . The reaction kinetics are described in Figure 2. The MSCD equations for replicase readIn these equations denotes the rate at which protocells of composition are formed as a consequence of the splitting of protocells of size . For splitting into two daughter cells, can be written asFor splitting into many () daughter cells, can be written aswhere the dissociation rates of protocells with are given by

The error threshold for replicase

The frequency of sequences A () evolves according to the MSCD equations and can be written asTherefore ifthe number of protocells with sequences A increases. On the other side the total number of sequences evolves according to the MSCD equation and it can be proved that independently of the splitting mechanism, it satisfies the following equation:By setting we obtain the value for that is needed to preserve the total number of sequences ( i.e. ). We find thereforeTherefore if . Substituting in the relation , we find that the configuration with is not stable and protocells with sequences A will be selected ifThis result is proved here for the case in which we assume that the number of sequences in the system remains constant. Nevertheless the error threshold of the model remains the same if we impose that the number of protocells in the system is fixed. In the Text S1 we give full details of this derivation and we show how to solve the MSCD equations for the other replicases considered in this paper.

Supporting Information

Text S1.

Detailed description of model and calculations.

https://doi.org/10.1371/journal.pcbi.1003051.s001

(PDF)

Author Contributions

Conceived and designed the experiments: GB MAN. Performed the experiments: GB KZ MAN. Analyzed the data: GB KZ IAC MAN. Wrote the paper: GB IAC MAN.

References

1. Lewontin RC (1970) The units of selection. Annu Rev Ecol Syst 1: 1–18.
- View Article
- Google Scholar
2. Nowak MA (2006) Five rules for the evolution of cooperation. Science 314: 1560–1563.
- View Article
- Google Scholar
3. Szostak JW, Bartel DP, Luisi PL (2001) Synthesizing life. Nature 409: 387–390.
- View Article
- Google Scholar
4. Szathmary E, Demeter L (1987) Group Selection of Early Replicators and the Origin of Life. Journal of theoretical biology 128: 463–486.
- View Article
- Google Scholar
5. Nowak MA, May R (1992) Nature 359: 826–829.
- View Article
- Google Scholar
6. Szabo P, Scheuring I, Czaran T, Szathmary E (2002) In silico simulations reveal that replicators with limited dispersal evolve towards higher efficiency and fidelity. Nature 420: 340–343.
- View Article
- Google Scholar
7. Hogeweg P, Takeuchi N (2003) Multilevel selection in models of prebiotic evolution: Compartments and spatial self-organization. Origins of Life and Evolution of the Biosphere 33: 375–403.
- View Article
- Google Scholar
8. Scheuring I, Czaran T, Szabo P, Karolyi G, Toroczkai Z (2003) Spatial models of prebiotic evolution: soup before pizza? Origins of life and evolution of the biosphere 33: 319–355.
- View Article
- Google Scholar
9. Traulsen A, Nowak MA (2006) Evolution of cooperation by multilevel selection. Proceedings of the National Academy of Sciences 103: 10952–10955.
- View Article
- Google Scholar
10. Fontanari JF, Santos M, Szathmary E (2006) Coexistence and error propagation in pre-biotic vesicle models: A group selection approach. Journal of theoretical biology 239: 247–256.
- View Article
- Google Scholar
11. Takeuchi N, Hogeweg P (2009) Multilevel Selection in Models of Prebiotic Evolution II: A Direct Comparison of Compartmentalization and Spatial Self-Organization. Plos Computational Biology 5(10): e1000542.
- View Article
- Google Scholar
12. Hogeweg P, Takeuchi N (2012) Evolutionary dynamics of RNA-like replicator systems: A bioinformatic approach to the origin of life. Physics of Life Reviews 9: 219–263.
- View Article
- Google Scholar
13. Maynard Smith J and Szathmary E (1995) The Major Transitions in Evolution. New York: Oxford University Press.
14. Maynard Smith J and Szathmary E (1999) The Origin of Life. New York: Oxford University Press, New York.
15. Dzieciol AJ, Mann S (2012) Designs for life: protocell models in the laboratory. Chemical Society reviews 41: 79–85.
- View Article
- Google Scholar
16. Walde P (2010) Building artificial cells and protocell models: experimental approaches with lipid vesicles. Bio Essays 32: 296–303.
- View Article
- Google Scholar
17. Rasmussen S, Bedau M, Chen L, Deamer D, Krakauer D, et al.. (2009) Protocells: Bridging nonliving and living matter. Cambridge: MIT Press.
18. Deamer D, Szostak JW, editors (2010) The Origins of Life. Cold Spring Harbor: Cold Spring Harbor Laboratories Press.
19. Allen WV, Ponnamperuma C (1967) A possible prebiotic synthesis of monocarboxylic acids. Currents in modern biology 1: 24–28.
- View Article
- Google Scholar
20. Dworkin J, Deamer D, Sandford S, Allamandola L (2001) Self-assembling amphiphilic molecules: Synthesis in simulated interstellar/precometary ices. Proceedings of the National Academy of Sciences of the United States of America 98: 815–819.
- View Article
- Google Scholar
21. Rushdi AI, Simoneit BR (2001) Lipid formation by aqueous Fischer-Tropsch-type synthesis over a temperature range of 100 to 400 degrees C. Origins of life and evolution of the biosphere 31: 103–118.
- View Article
- Google Scholar
22. Yuen GU, Lawless JG, Edelson EH (1981) Quantification of monocarboxylic acids from a spark discharge synthesis. J Mol Evol 17: 43–47.
- View Article
- Google Scholar
23. McCollom TM, Ritter G, Simoneit BR (1999) Lipid synthesis under hydrothermal conditions by Fischer-Tropsch-type reactions. Origins of life and evolution of the biosphere 29: 153–166.
- View Article
- Google Scholar
24. Yuen GU, Kvenvolden KA (1973) Monocarboxylic acids in Murray and Murchison carbonaceous meteorites. Nature 246: 301–303.
- View Article
- Google Scholar
25. Yuen G, Blair N, Des Marais DJ, Chang S (1984) Carbon isotope composition of low molecular weight hydrocarbons and monocarboxylic acids from Murchison meteorite. Nature 307: 252–254.
- View Article
- Google Scholar
26. Lawless JG, Yuen GU (1979) Quantification of monocarboxylic acids in the Murchison carbonaceous meteorite. Nature 282: 396–398.
- View Article
- Google Scholar
27. Naraoka H, Shimoyama A, Harada K (1999) Molecular distribution of monocarboxylic acids in Asuka carbonaceous chondrites from Antarctica. Origins of life and evolution of the biosphere 29: 187–201.
- View Article
- Google Scholar
28. Deamer DW (1985) Boundary structures are formed by organic components of the Murchison carbonaceous chondrite. Nature 317: 792–794.
- View Article
- Google Scholar
29. Zhu TF, Adamala K, Zhang N, Szostak JW (2012) Photochemically driven redox chemistry induces protocell membrane pearling and division. Proceedings of the National Academy of Sciences of the United States of America 109: 9828–9832.
- View Article
- Google Scholar
30. Zhu TF, Szostak JW (2009) Coupled growth and division of model protocell membranes. J Am Chem Soc 131: 5705–5713.
- View Article
- Google Scholar
31. Leaver M, Domínguez-Cuevas P, Coxhead JM, Daniel RA, Errington J (2009) Life without a wall or division machine in Bacillus subtilis. Nature 457: 849–853.
- View Article
- Google Scholar
32. Kurihara K, Tamura M, Shohda KI, Toyota T, Suzuki K, Sugawara T (2011) Self-reproduction of supramolecular giant vesicles combined with the amplification of encapsulated DNA. Nature chemistry 3: 775–781.
- View Article
- Google Scholar
33. Markvoort AJ, Pfleger N, Staffhorst R, Hilbers PA, Van Santen RA, et al. (2010) Self-reproduction of fatty acid vesicles: A combined experimental and simulation study. Biophysical journal 99: 1520–1528.
- View Article
- Google Scholar
34. Stano P, Wehrli E, Luisi PL (2006) Insights into the self-reproduction of oleate vesicles. Journal of Physics: Condensed Matter 18: S2231.
- View Article
- Google Scholar
35. Chen IA, Salehi-Ashtiani K, Szostak JW (2005) RNA catalysis in model protocell vesicles. J Am Chem Soc 127: 13213–13219.
- View Article
- Google Scholar
36. Mansy SS, Schrum JP, Krishnamurthy M, Tobé S, Treco DA, et al. (2008) Template-directed synthesis of a genetic polymer in a model protocell. Nature 454: 122–125.
- View Article
- Google Scholar
37. Müller UF, Bartel DP (2008) Improved polymerase ribozyme efficiency on hydrophobic assemblies. RNA 3: 552–62.
- View Article
- Google Scholar
38. Wu M, Higgs PG (2009) Origin of self-replicating biopolymers: autocatalytic feedback can jump-start the RNA world. J Mol Evol 69: 541–54.
- View Article
- Google Scholar
39. Higgs PG, Wu M (2012) The Importance of Stochastic Transitions for the Origin of Life. Orig Life Evol Biosph 42(5): 453–7.
- View Article
- Google Scholar
40. Wochner A, Attwater J, Coulson A, Holliger P (2011) Replicase-catalyzed transcription of an active replicase. Science 332: 209–212.
- View Article
- Google Scholar
41. Johnston WK, Unrau PJ, Lawrence MS, Glasner ME, Bartel DP (2001) RNA-catalyzed RNA polymerization: accurate and general RNA-templated primer extension. Science 292: 1319–1325.
- View Article
- Google Scholar
42. Zaher HS, Unrau PJ (2007) Selection of an improved RNA polymerase replicase with superior extension and fidelity. Rna 13: 1017–1026.
- View Article
- Google Scholar
43. Lincoln TA, Joyce GF (2009) Self-sustained replication of an RNA enzyme. Science 323: 1229–1232.
- View Article
- Google Scholar
44. Doudna JA, Usman N, Szostak JW (1993) Replicase-catalyzed primer extension by trinucleotides: A model for the RNA-catalyzed replication of RNA. Biochemistry 32(8): 2111–2115.
- View Article
- Google Scholar
45. James KD, Ellington AD (1999) The fidelity of template-directed oligonucleotide ligation and the inevitability of polymerase function. Origins of Life and Evolution of Biospheres 29: 375–390.
- View Article
- Google Scholar
46. Jain SS, Anet FA, Stahle CJ, Hud NV (2004) Enzymatic Behavior by Intercalating Molecules in a TemplateDirected Ligation Reaction. Angewandte Chemie International Edition 43(15): 2004–8.
- View Article
- Google Scholar
47. Szostak JW (2011) An optimal degree of physical and chemical heterogeneity for the origin of life? Philosophical Transactions of the Royal Society B: Biological Sciences 366: 2894–2901.
- View Article
- Google Scholar
48. Kim DE, Joyce GF (2004) Cross-catalytic replication of an RNA ligase ribozyme. Chem Biol 11(11): 1505–12.
- View Article
- Google Scholar
49. Paul N, Joyce GF (2002) A self-replicating ligase ribozyme. Proc Natl Acad Sci U S A 99(20): 12733–40.
- View Article
- Google Scholar
50. Vaidya N, Manapat ML, Chen IA, Xulvi-Brunet R, Hayden EJ, et al. (2012) Spontaneous network formation among cooperative RNA replicators. Nature 491(7422): 72–7.
- View Article
- Google Scholar
51. Vasas V, Fernando C, Santos M, Kauffman S, Szathmáry E (2012) Evolution before genes. Biol Direct 7: 1.
- View Article
- Google Scholar
52. Chen IA, Roberts RW, Szostak JW (2004) The emergence of competition between model protocells. Science 305: 1474–1476.
- View Article
- Google Scholar
53. Kun A, Santos M, Szathmáry E (2005) Real ribozymes suggest a relaxed error threshold. Nat Genet 37(9): 1008–11.
- View Article
- Google Scholar
54. Eigen M, Schuster P (1977) the Hypercycle. A principle of Natural Self-Organization. Part A: Emergence of the Hypercycle. Naturwissenschaften 64: 541–565.
- View Article
- Google Scholar
55. Nowak M, Schuster P (1989) Error thresholds of replication in finite populations. Mutation frequencies and the onset of Muller's ratchet. J theor Biol 137: 375–395.
- View Article
- Google Scholar
56. Nowak MA (1992) What is a quasispecies? Trends Ecol Evol 7: 118–121.
- View Article
- Google Scholar
57. Leu K, Obermayer B, Rajamani S, Gerland U, Chen IA (2011) The prebiotic evolutionary advantage of transferring genetic information from RNA to DNA. Nucl Acids Res 39: 1–13.
- View Article
- Google Scholar
58. Turk RM, Chumachenko NV, Yarus M (2010) Multiple translational products from a five-nucleotide replicase. Proceedings of the National Academy of Sciences 107: 4585–4589.
- View Article
- Google Scholar
59. Eigen M (1971) Selforganization of matter and the evolution of biological macromolecules. Die Naturwissenschaften 58: 465–523.
- View Article
- Google Scholar
60. Nowak MA (2006) Evolutionary Dynamics: Exploring the Equations of Life. Harvard University Press.
61. Mavelli F (2012) Stochastic simulations of minimal cells: the Ribocell model. BMC Bioinformatics 33: S10.
- View Article
- Google Scholar
62. Zenisek SF, Hayden EJ, Lehman N (2007) Genetic exchange leading to self-assembling RNA species upon encapsulation in artificial protocells. Artif Life 13 279–89.
- View Article
- Google Scholar

[ref1] 1. Lewontin RC (1970) The units of selection. Annu Rev Ecol Syst 1: 1–18.
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. Nowak MA (2006) Five rules for the evolution of cooperation. Science 314: 1560–1563.
View Article
Google Scholar

[5] View Article

[6] Google Scholar

[ref3] 3. Szostak JW, Bartel DP, Luisi PL (2001) Synthesizing life. Nature 409: 387–390.
View Article
Google Scholar

[8] View Article

[9] Google Scholar

[ref4] 4. Szathmary E, Demeter L (1987) Group Selection of Early Replicators and the Origin of Life. Journal of theoretical biology 128: 463–486.
View Article
Google Scholar

[11] View Article

[12] Google Scholar

[ref5] 5. Nowak MA, May R (1992) Nature 359: 826–829.
View Article
Google Scholar

[14] View Article

[15] Google Scholar

[ref6] 6. Szabo P, Scheuring I, Czaran T, Szathmary E (2002) In silico simulations reveal that replicators with limited dispersal evolve towards higher efficiency and fidelity. Nature 420: 340–343.
View Article
Google Scholar

[17] View Article

[18] Google Scholar

[ref7] 7. Hogeweg P, Takeuchi N (2003) Multilevel selection in models of prebiotic evolution: Compartments and spatial self-organization. Origins of Life and Evolution of the Biosphere 33: 375–403.
View Article
Google Scholar

[20] View Article

[21] Google Scholar

[ref8] 8. Scheuring I, Czaran T, Szabo P, Karolyi G, Toroczkai Z (2003) Spatial models of prebiotic evolution: soup before pizza? Origins of life and evolution of the biosphere 33: 319–355.
View Article
Google Scholar

[23] View Article

[24] Google Scholar

[ref9] 9. Traulsen A, Nowak MA (2006) Evolution of cooperation by multilevel selection. Proceedings of the National Academy of Sciences 103: 10952–10955.
View Article
Google Scholar

[26] View Article

[27] Google Scholar

[ref10] 10. Fontanari JF, Santos M, Szathmary E (2006) Coexistence and error propagation in pre-biotic vesicle models: A group selection approach. Journal of theoretical biology 239: 247–256.
View Article
Google Scholar

[29] View Article

[30] Google Scholar

[ref11] 11. Takeuchi N, Hogeweg P (2009) Multilevel Selection in Models of Prebiotic Evolution II: A Direct Comparison of Compartmentalization and Spatial Self-Organization. Plos Computational Biology 5(10): e1000542.
View Article
Google Scholar

[32] View Article

[33] Google Scholar

[ref12] 12. Hogeweg P, Takeuchi N (2012) Evolutionary dynamics of RNA-like replicator systems: A bioinformatic approach to the origin of life. Physics of Life Reviews 9: 219–263.
View Article
Google Scholar

[35] View Article

[36] Google Scholar

[ref13] 13. Maynard Smith J and Szathmary E (1995) The Major Transitions in Evolution. New York: Oxford University Press.

[ref14] 14. Maynard Smith J and Szathmary E (1999) The Origin of Life. New York: Oxford University Press, New York.

[ref15] 15. Dzieciol AJ, Mann S (2012) Designs for life: protocell models in the laboratory. Chemical Society reviews 41: 79–85.
View Article
Google Scholar

[40] View Article

[41] Google Scholar

[ref16] 16. Walde P (2010) Building artificial cells and protocell models: experimental approaches with lipid vesicles. Bio Essays 32: 296–303.
View Article
Google Scholar

[43] View Article

[44] Google Scholar

[ref17] 17. Rasmussen S, Bedau M, Chen L, Deamer D, Krakauer D, et al.. (2009) Protocells: Bridging nonliving and living matter. Cambridge: MIT Press.

[ref18] 18. Deamer D, Szostak JW, editors (2010) The Origins of Life. Cold Spring Harbor: Cold Spring Harbor Laboratories Press.

[ref19] 19. Allen WV, Ponnamperuma C (1967) A possible prebiotic synthesis of monocarboxylic acids. Currents in modern biology 1: 24–28.
View Article
Google Scholar

[48] View Article

[49] Google Scholar

[ref20] 20. Dworkin J, Deamer D, Sandford S, Allamandola L (2001) Self-assembling amphiphilic molecules: Synthesis in simulated interstellar/precometary ices. Proceedings of the National Academy of Sciences of the United States of America 98: 815–819.
View Article
Google Scholar

[51] View Article

[52] Google Scholar

[ref21] 21. Rushdi AI, Simoneit BR (2001) Lipid formation by aqueous Fischer-Tropsch-type synthesis over a temperature range of 100 to 400 degrees C. Origins of life and evolution of the biosphere 31: 103–118.
View Article
Google Scholar

[54] View Article

[55] Google Scholar

[ref22] 22. Yuen GU, Lawless JG, Edelson EH (1981) Quantification of monocarboxylic acids from a spark discharge synthesis. J Mol Evol 17: 43–47.
View Article
Google Scholar

[57] View Article

[58] Google Scholar

[ref23] 23. McCollom TM, Ritter G, Simoneit BR (1999) Lipid synthesis under hydrothermal conditions by Fischer-Tropsch-type reactions. Origins of life and evolution of the biosphere 29: 153–166.
View Article
Google Scholar

[60] View Article

[61] Google Scholar

[ref24] 24. Yuen GU, Kvenvolden KA (1973) Monocarboxylic acids in Murray and Murchison carbonaceous meteorites. Nature 246: 301–303.
View Article
Google Scholar

[63] View Article

[64] Google Scholar

[ref25] 25. Yuen G, Blair N, Des Marais DJ, Chang S (1984) Carbon isotope composition of low molecular weight hydrocarbons and monocarboxylic acids from Murchison meteorite. Nature 307: 252–254.
View Article
Google Scholar

[66] View Article

[67] Google Scholar

[ref26] 26. Lawless JG, Yuen GU (1979) Quantification of monocarboxylic acids in the Murchison carbonaceous meteorite. Nature 282: 396–398.
View Article
Google Scholar

[69] View Article

[70] Google Scholar

[ref27] 27. Naraoka H, Shimoyama A, Harada K (1999) Molecular distribution of monocarboxylic acids in Asuka carbonaceous chondrites from Antarctica. Origins of life and evolution of the biosphere 29: 187–201.
View Article
Google Scholar

[72] View Article

[73] Google Scholar

[ref28] 28. Deamer DW (1985) Boundary structures are formed by organic components of the Murchison carbonaceous chondrite. Nature 317: 792–794.
View Article
Google Scholar

[75] View Article

[76] Google Scholar

[ref29] 29. Zhu TF, Adamala K, Zhang N, Szostak JW (2012) Photochemically driven redox chemistry induces protocell membrane pearling and division. Proceedings of the National Academy of Sciences of the United States of America 109: 9828–9832.
View Article
Google Scholar

[78] View Article

[79] Google Scholar

[ref30] 30. Zhu TF, Szostak JW (2009) Coupled growth and division of model protocell membranes. J Am Chem Soc 131: 5705–5713.
View Article
Google Scholar

[81] View Article

[82] Google Scholar

[ref31] 31. Leaver M, Domínguez-Cuevas P, Coxhead JM, Daniel RA, Errington J (2009) Life without a wall or division machine in Bacillus subtilis. Nature 457: 849–853.
View Article
Google Scholar

[84] View Article

[85] Google Scholar

[ref32] 32. Kurihara K, Tamura M, Shohda KI, Toyota T, Suzuki K, Sugawara T (2011) Self-reproduction of supramolecular giant vesicles combined with the amplification of encapsulated DNA. Nature chemistry 3: 775–781.
View Article
Google Scholar

[87] View Article

[88] Google Scholar

[ref33] 33. Markvoort AJ, Pfleger N, Staffhorst R, Hilbers PA, Van Santen RA, et al. (2010) Self-reproduction of fatty acid vesicles: A combined experimental and simulation study. Biophysical journal 99: 1520–1528.
View Article
Google Scholar

[90] View Article

[91] Google Scholar

[ref34] 34. Stano P, Wehrli E, Luisi PL (2006) Insights into the self-reproduction of oleate vesicles. Journal of Physics: Condensed Matter 18: S2231.
View Article
Google Scholar

[93] View Article

[94] Google Scholar

[ref35] 35. Chen IA, Salehi-Ashtiani K, Szostak JW (2005) RNA catalysis in model protocell vesicles. J Am Chem Soc 127: 13213–13219.
View Article
Google Scholar

[96] View Article

[97] Google Scholar

[ref36] 36. Mansy SS, Schrum JP, Krishnamurthy M, Tobé S, Treco DA, et al. (2008) Template-directed synthesis of a genetic polymer in a model protocell. Nature 454: 122–125.
View Article
Google Scholar

[99] View Article

[100] Google Scholar

[ref37] 37. Müller UF, Bartel DP (2008) Improved polymerase ribozyme efficiency on hydrophobic assemblies. RNA 3: 552–62.
View Article
Google Scholar

[102] View Article

[103] Google Scholar

[ref38] 38. Wu M, Higgs PG (2009) Origin of self-replicating biopolymers: autocatalytic feedback can jump-start the RNA world. J Mol Evol 69: 541–54.
View Article
Google Scholar

[105] View Article

[106] Google Scholar

[ref39] 39. Higgs PG, Wu M (2012) The Importance of Stochastic Transitions for the Origin of Life. Orig Life Evol Biosph 42(5): 453–7.
View Article
Google Scholar

[108] View Article

[109] Google Scholar

[ref40] 40. Wochner A, Attwater J, Coulson A, Holliger P (2011) Replicase-catalyzed transcription of an active replicase. Science 332: 209–212.
View Article
Google Scholar

[111] View Article

[112] Google Scholar

[ref41] 41. Johnston WK, Unrau PJ, Lawrence MS, Glasner ME, Bartel DP (2001) RNA-catalyzed RNA polymerization: accurate and general RNA-templated primer extension. Science 292: 1319–1325.
View Article
Google Scholar

[114] View Article

[115] Google Scholar

[ref42] 42. Zaher HS, Unrau PJ (2007) Selection of an improved RNA polymerase replicase with superior extension and fidelity. Rna 13: 1017–1026.
View Article
Google Scholar

[117] View Article

[118] Google Scholar

[ref43] 43. Lincoln TA, Joyce GF (2009) Self-sustained replication of an RNA enzyme. Science 323: 1229–1232.
View Article
Google Scholar

[120] View Article

[121] Google Scholar

[ref44] 44. Doudna JA, Usman N, Szostak JW (1993) Replicase-catalyzed primer extension by trinucleotides: A model for the RNA-catalyzed replication of RNA. Biochemistry 32(8): 2111–2115.
View Article
Google Scholar

[123] View Article

[124] Google Scholar

[ref45] 45. James KD, Ellington AD (1999) The fidelity of template-directed oligonucleotide ligation and the inevitability of polymerase function. Origins of Life and Evolution of Biospheres 29: 375–390.
View Article
Google Scholar

[126] View Article

[127] Google Scholar

[ref46] 46. Jain SS, Anet FA, Stahle CJ, Hud NV (2004) Enzymatic Behavior by Intercalating Molecules in a TemplateDirected Ligation Reaction. Angewandte Chemie International Edition 43(15): 2004–8.
View Article
Google Scholar

[129] View Article

[130] Google Scholar

[ref47] 47. Szostak JW (2011) An optimal degree of physical and chemical heterogeneity for the origin of life? Philosophical Transactions of the Royal Society B: Biological Sciences 366: 2894–2901.
View Article
Google Scholar

[132] View Article

[133] Google Scholar

[ref48] 48. Kim DE, Joyce GF (2004) Cross-catalytic replication of an RNA ligase ribozyme. Chem Biol 11(11): 1505–12.
View Article
Google Scholar

[135] View Article

[136] Google Scholar

[ref49] 49. Paul N, Joyce GF (2002) A self-replicating ligase ribozyme. Proc Natl Acad Sci U S A 99(20): 12733–40.
View Article
Google Scholar

[138] View Article

[139] Google Scholar

[ref50] 50. Vaidya N, Manapat ML, Chen IA, Xulvi-Brunet R, Hayden EJ, et al. (2012) Spontaneous network formation among cooperative RNA replicators. Nature 491(7422): 72–7.
View Article
Google Scholar

[141] View Article

[142] Google Scholar

[ref51] 51. Vasas V, Fernando C, Santos M, Kauffman S, Szathmáry E (2012) Evolution before genes. Biol Direct 7: 1.
View Article
Google Scholar

[144] View Article

[145] Google Scholar

[ref52] 52. Chen IA, Roberts RW, Szostak JW (2004) The emergence of competition between model protocells. Science 305: 1474–1476.
View Article
Google Scholar

[147] View Article

[148] Google Scholar

[ref53] 53. Kun A, Santos M, Szathmáry E (2005) Real ribozymes suggest a relaxed error threshold. Nat Genet 37(9): 1008–11.
View Article
Google Scholar

[150] View Article

[151] Google Scholar

[ref54] 54. Eigen M, Schuster P (1977) the Hypercycle. A principle of Natural Self-Organization. Part A: Emergence of the Hypercycle. Naturwissenschaften 64: 541–565.
View Article
Google Scholar

[153] View Article

[154] Google Scholar

[ref55] 55. Nowak M, Schuster P (1989) Error thresholds of replication in finite populations. Mutation frequencies and the onset of Muller's ratchet. J theor Biol 137: 375–395.
View Article
Google Scholar

[156] View Article

[157] Google Scholar

[ref56] 56. Nowak MA (1992) What is a quasispecies? Trends Ecol Evol 7: 118–121.
View Article
Google Scholar

[159] View Article

[160] Google Scholar

[ref57] 57. Leu K, Obermayer B, Rajamani S, Gerland U, Chen IA (2011) The prebiotic evolutionary advantage of transferring genetic information from RNA to DNA. Nucl Acids Res 39: 1–13.
View Article
Google Scholar

[162] View Article

[163] Google Scholar

[ref58] 58. Turk RM, Chumachenko NV, Yarus M (2010) Multiple translational products from a five-nucleotide replicase. Proceedings of the National Academy of Sciences 107: 4585–4589.
View Article
Google Scholar

[165] View Article

[166] Google Scholar

[ref59] 59. Eigen M (1971) Selforganization of matter and the evolution of biological macromolecules. Die Naturwissenschaften 58: 465–523.
View Article
Google Scholar

[168] View Article

[169] Google Scholar

[ref60] 60. Nowak MA (2006) Evolutionary Dynamics: Exploring the Equations of Life. Harvard University Press.

[ref61] 61. Mavelli F (2012) Stochastic simulations of minimal cells: the Ribocell model. BMC Bioinformatics 33: S10.
View Article
Google Scholar

[172] View Article

[173] Google Scholar

[ref62] 62. Zenisek SF, Hayden EJ, Lehman N (2007) Genetic exchange leading to self-assembling RNA species upon encapsulation in artificial protocells. Artif Life 13 279–89.
View Article
Google Scholar

[175] View Article

[176] Google Scholar

Figures

Abstract

Author Summary

Introduction

Results

Discussion

Materials and Methods

The mutation-selection-cell division (MSCD) equations

The error threshold for replicase

Supporting Information

Text S1.

Author Contributions

References