- Research article
- Open Access
The effect of natural selection on the performance of maximum parsimony
© Hang et al; licensee BioMed Central Ltd. 2007
- Received: 12 September 2006
- Accepted: 25 June 2007
- Published: 25 June 2007
Maximum parsimony is one of the most commonly used and extensively studied phylogeny reconstruction methods. While current evaluation methodologies such as computer simulations provide insight into how well maximum parsimony reconstructs phylogenies, they tell us little about how well maximum parsimony performs on taxa drawn from populations of organisms that evolved subject to natural selection in addition to the random factors of drift and mutation. It is clear that natural selection has a significant impact on Among Site Rate Variation (ASRV) and the rate of accepted substitutions; that is, accepted mutations do not occur with uniform probability along the genome and some substitutions are more likely to occur than other substitutions. However, little is know about how ASRV and non-uniform character substitutions impact the performance of reconstruction methods such as maximum parsimony. To gain insight into these issues, we study how well maximum parsimony performs with data generated by Avida, a digital life platform where populations of digital organisms evolve subject to natural selective pressures.
We first identify conditions where natural selection does affect maximum parsimony's reconstruction accuracy. In general, as we increase the probability that a significant adaptation will occur in an intermediate ancestor, the performance of maximum parsimony improves. In fact, maximum parsimony can correctly reconstruct small 4 taxa trees on data that have received surprisingly many mutations if the intermediate ancestor has received a significant adaptation. We demonstrate that this improved performance of maximum parsimony is attributable more to ASRV than to non-uniform character substitutions.
Maximum parsimony, as well as most other phylogeny reconstruction methods, may perform significantly better on actual biological data than is currently suggested by computer simulation studies because of natural selection. This is largely due to specific sites becoming fixed in the genome that perform functions associated with an improved fitness.
- Natural Selection
- Maximum Parsimony
- Reward Structure
- Reconstruction Accuracy
- Phylogeny Reconstruction
One of the most important problems in systematic biology is phylogenetic tree reconstruction. The use of phylogenetic trees is a fundamental step in many biological problems, such as the inference of evolutionary relationships among genes, genomes and organisms, protein structure and function prediction, and drug design .
Because of the importance of phylogeny reconstruction, many different reconstruction techniques have been developed. One of the most popular and widely used techniques is maximum parsimony . The basic idea behind maximum parsimony is to find a most parsimonious phylogenetic tree; that is, a tree that requires the fewest mutations to explain the observed sequences. One drawback of maximum parsimony is its computational complexity. Finding a most parsimonious tree is an NP-hard problem , which means that it is unlikely any algorithm can find a most parsimonious tree quickly for all possible input sequences. One of the best implementations of maximum parsimony is that of  which can handle roughly 1000 taxa.
Evaluating how well maximum parsimony or any other technique reconstructs phylogenies is a difficult problem. Several different evaluation methodologies have been proposed  including computer simulation [6–9] and experiments with organisms with known phylogenies [10, 11]. Unfortunately, each of these techniques is handicapped by at least one of the following drawbacks. The true phylogeny is not known. The simulated taxa have no meaning and do not contain genes. The simulated taxa have been generated by simplifying the evolutionary processes to ignore important mechanisms such as natural selection. There is limited data from which to draw statistically robust conclusions about the relative performance of algorithms. The result is that existing evaluation methodologies have left us incapable of answering several fundamental questions about phylogeny reconstruction. What is the effect of natural selection on the performance of a phylogeny reconstruction technique such as maximum parsimony? What is the effect of using the wrong character substitution model on the performance of a phylogeny reconstruction technique such as maximum parsimony? What is the effect of using the wrong mutation location model on the performance of a phylogeny reconstruction model such as maximum parsimony?
For example, consider the evaluation method of generating synthetic data using computer simulation techniques [6–9]. This method has many advantages including that the true phylogeny is known and large amounts of data can be generated rapidly. To generate synthetic data using a computer simulated evolutionary process, the researcher typically specifies four model components: a tree topology, a character substitution model, a mutation location model, and a probability distribution for the ancestral root sequence. A specific ancestral sequence is generated from the probability distribution, and the simulation mutates the sequence down the given tree topology according to the given substitution and mutation location models until a sequence has been generated for each leaf of the tree. Two programs commonly used to generate sequences according to a given tree and substitution model are Seq-Gen and PSeq-Gen [12, 13]. The character substitution model is used to simulate varying probabilities of accepted mutations. In natural sequences, the probability of mutating from one character to another and having this mutation be accepted depends on the specific characters involved. Several different amino acid and nucleotide substitution models have been developed to partially account for the effects of biochemistry and natural selection [14–18]. The mutation location model is used to simulate Among Site Rate Variation (ASRV). In natural sequences, different sites undergo substitutions at different rates; that is, the mutation location model is not uniform. For example, portions of the genome that correspond to binding or catalytic sites of protein sequences will experience fewer mutations than the non-coding portions of the genome. ASRV affects estimation of distances between sequences, transition rate bias and phylogeny reconstruction. Several different ASRV models have been proposed [19, 20]. Usually a mathematical distribution, such as a gamma distribution, is used to model ASRV.
The key drawback of computer simulations is that despite the use of sophisticated models, the taxa are not collected from a natural evolutionary process. Instead, the taxa are simply random sequences of characters that have no meaning and do not include actual genes or functional components. Thus, no sequence can be "more fit" than another sequence, and the taxa are determined solely by mutation and drift but not natural selection. Therefore, computer simulation techniques cannot be used to assess the effect of natural selection on the performance of maximum parsimony.
Working with natural data with known phylogenies partially overcomes the limitations of computer simulation [10, 11]. However, even these data suffer from important limitations. First and foremost, the number of known phylogenies is relatively small. Furthermore, in experimental phylogenies, the mutation rates typically are manipulated to increase divergence with the potential side effect of overemphasizing genetic drift as compared to natural selection. Finally, while the major phylogenetic relationships will be known, there is a limit to the amount of data available to the researcher. In computer simulations, for example, all mutation events can be recorded at a level of detail impossible with real biological organisms. Thus, we are still incapable of answering many questions about the effect of natural selection on reconstruction accuracy.
In this work, we study exactly this question. What is the effect of natural selection on the performance of a reconstruction technique such as maximum parsimony? Does it improve or hinder reconstruction accuracy? Furthermore, assuming that natural selection does influence reconstruction accuracy, how does it affect reconstruction accuracy? More specifically, we know that natural selection creates both ASRV and non-uniform character substitution. What is the relative importance of ASRV and non-uniform character substitution on reconstruction accuracy?
The Avida digital evolution research platform
We study these questions using the Avida digital evolution research platform  to generate a collection of sequences that experience true Darwinian evolution from which we can attempt to reconstruct a phylogeny. In Avida, each sequence represents a self-replicating computer program. Like computer simulations, all information including the phylogeny of the sequences can be perfectly recorded. However, the Avida populations do not simulate evolution; they evolve subject to mutation, drift, and selection. We describe below how mutation and selection arise.
When a digital organism replicates, it copies its genome, one instruction at a time, into empty memory. Mutations arise due to a faulty copy command. When an instruction is copied, there is a small probability that it will be copied incorrectly. This probability or mutation rate is an experimental parameter set by the researcher. Typically, when a mutation occurs, an incorrect instruction is chosen uniformly at random from the remaining instructions, though we do consider other probability distributions as well.
Space is limited in an Avida population and death occurs when organisms are removed (at random) to make room for new offspring. The fitness of an organism is essentially its replication speed. One way for an organism to increase its fitness is for it to replicate using fewer instructions. An alternative is to perform specific Boolean logic tasks (akin to metabolic reactions) that are specified in the researcher-defined digital environment that give the organism extra energy that allows the organism to execute instructions more rapidly. For example, if NOR is a rewarded task, organisms can obtain extra energy by reading in two vectors of binary digits, performing NOR on each corresponding pair of bits in the two inputs, and outputting the resulting bit vector. There are many different ways to perform NOR and rarely, if ever, will evolution find identical solutions in replicate runs.
The Avida system and natural selection
A concern that we are faced with in using Avida as a data source for phylogeny reconstruction studies is the same credibility gap that computer simulation studies face. Specifically, how similar is data from Avida experiments to data found in the natural world?
We first emphasize that Avida is a widely used platform for studying evolution. Several dozen peer reviewed papers have been published based on Avida experimental data including several in Nature, Science, and the Proceedings of the National Academy of Sciences [22–26].
Biological communities have accepted Avida experimental data because populations of digital organisms undergo true Darwinian evolution where individuals have genomes that are expressed into phenotypes. Avida experiments do not simulate any specific biological process or system. Instead, Avida organisms are computer programs with actual meanings and fitness values. Thus, Avida organisms do evolve subject to natural selection.
For example, Avida organisms are highly contingent on previous events. Ofria and others have shown that complex traits can evolve in Avida  if simpler traits are rewarded by using the genetic code that performs the simpler traits as building blocks. On the other hand, sometimes the use of a particular gene in one way will constrain further evolution in other directions. A specific case of this is that the replication of an organism's genome can become over-optimized relying on that genome to be a specific length, thereby constraining all other genes to exist within a fixed number of instructions and thus limiting their evolution. Wagenaar and Adami showed that chance events are required to open gateways that allow further adaptation . Thus, Avida experiments show wide variation in the paths taken by evolution with replicate runs rarely finding the same solution. Epistasis also occurs in Avida  and the dynamics were essentially identical to those found in long term E. coli experiments .
It is true that Avida data does have some limitations. The genome length of an Avida organism in our experiments is 100 (with 26 possible instructions at each position). This implies that the genome of a typical Avida organism is less complex than that of most biological organisms, but is certainly comparable to that of short genes. Thus, Avida phylogenies can most easily be compared to gene phylogenies of biological organisms. While we could increase the length of the Avida organisms, it is not clear this increase would be meaningful. The information density of the longer organisms would be less than that of the length 100 organisms if both organisms perform the same set of tasks.
Another potential limitation is that Avida's basic life chemistry is distinct from that of natural organisms. However, while the specific chemistry may be different, we can still compare phylogeny reconstruction with and without natural selection to derive general principles about natural selection's effect on phylogeny reconstruction that should apply to any evolving system. Any such general principles should be robust across most biological systems.
We have previously used Avida to analyze the effect of natural selection on the performance of maximum parsimony and neighbor joining [29, 30]. In , we demonstrated that maximum parsimony and neighbor joining could reconstruct 4 taxa phylogenies surprisingly well when all branches are extremely long and no significant functionality is being acquired through evolution. In , we tested a wider range of branch lengths for 4 taxa tree topologies and showed that both maximum parsimony and neighbor joining can reconstruct data sets generated with natural selection more accurately than datasets generated without natural selection, particularly when the internal branch is long enough to allow the acquisition of a significant phenotypic trait. We also showed that incorporating a simplistic ASRV model significantly enhanced the quality of the computer simulation data.
In this paper, we perform a more detailed analysis to determine how natural selection impacts the performance of maximum parsimony. We isolate specific conditions where the presence of natural selection significantly improves the reconstruction accuracy of maximum parsimony. We then illustrate how selective pressures cause changes in both ASRV and instruction frequency (which is related to the character substitution model). Our results show that ASRV and non-uniform character substitutions are not sufficient to capture the effects of natural selection on the performance of maximum parsimony. However, the computer simulation data produced by accurately simulating ASRV is more similar to real, experimental data than the computer simulation data produced by accurately simulating character substitution probabilities. Finally, we corroborate these results using PSeq-Gen data.
We generate sequences that evolve subject to natural selection using Avida. We generate sequences that evolve without natural selection by using computer simulation techniques. Within Avida, we utilize different reward structures to vary the selective pressure. In a given reward structure, some set of tasks is rewarded along a given branch in the tree topology. The set of tasks rewarded might change from one branch to another.
Conditions where natural selection improves reconstruction accuracy
The effect of selective pressure on among site rate variation (ASRV) and instruction frequency
Our results clearly demonstrate that there are situations where natural selection improves MP's reconstruction accuracy. To help determine which factor, ASRV or non-uniform accepted substitution probabilities, is the more influential byproduct of natural selection on the performance of maximum parsimony, we plot the ASRV and instruction frequencies that result from a variety of selective pressures. We use instruction frequency as a proxy for accepted substitution percentage because instruction frequencies are easier to interpret given the 26 instructions in the Avida instruction set. If we were to compare substitution percentages directly, that would require comparing 262 = 676 numbers while comparing instruction frequencies requires only 26 comparisons. Our results indicate a stronger relationship between ASRV and reward structure than between instruction frequencies and reward structures. This implies that ASRV may be a more important factor than non-uniform character substitution. However, our results also indicate that ASRV and non-uniform character substitutions cannot account for the entire effect of natural selection on the performance of maximum parsimony.
We see that for the control data set with no selective pressure, the plot of the number of positions that experience a given number of mutations is, as expected, a normal distribution centered close to 6. Likewise for the no-task reward structure data set, once the positions with 0 mutations are deleted, the plot of the number of positions that experience a given number of mutations is also normally distributed with the center close to 7. This occurs because the main selective pressure in the no-task reward structure setting is to maintain the replication cycle. The instructions responsible for replication are the ones in positions with 0 mutations. On the other hand, in the non-overlapping and overlapping structure data sets, the plot of the number of positions that experience a given number of mutations is not a normal distribution but rather is close to uniform in the range from 1 mutation to 12 mutations with a significant tail for higher numbers of mutations. Thus, significant changes in ASRV do correlate with significant changes in MP's reconstruction accuracy. However, there is not a sharp difference in the mutation distribution plots for the overlapping and non-overlapping data sets. This suggests that ASRV alone is not sufficient to explain the improved performance of maximum parsimony on the data generated in the overlapping reward structure compared to the data generated in the non-overlapping reward structure.
We see that for the control data set with no selective pressure, the instruction frequency distribution is essentially uniform at 3.86%. However, the instruction frequencies for the three Avida data sets that experience natural selection are clearly not uniform. The frequencies for instructions critical to replication such as h-copy, nop-A, nop-B, and nop-C are significantly above 3.86% in all three Avida data sets. The instruction frequencies for nand and IO, both of which are critical for performing Boolean logic tasks, are also significantly above 3.86% in the overlapping and non-overlapping reward structure data sets where there is a selective pressure to perform Boolean logic tasks.
When comparing the instruction frequencies, we see very little difference between the two from the overlapping and non-overlapping reward structures despite the significant difference in MP's reconstruction accuracy. Furthermore, there is a significant difference between the no-task reward structure instruction frequencies and the control data instruction frequencies while MP reconstructs both data sets with essentially the same accuracy. This data suggests that while non-uniform instruction frequencies and non-uniform character substitutions are a significant result of natural selection, they may not explain why natural selection improves the performance of phylogeny reconstruction algorithms such as maximum parsimony in some cases.
The effect of among site rate variation (ASRV) and non-uniform character substitutions on the performance of maximum parsimony
The previous data implied that ASRV is more likely to have an effect on maximum parsimony's performance than non-uniform character substitutions. In order to study this question more carefully, we augment our computer simulation program in order to perfectly mimic either the location of mutations that occurred in an Avida experiment or the substitutions that occurred in an Avida experiment. When the computer simulation program mimics the locations of mutations, we define this as location simulation. When the computer simulation model mimics the substitutions that occur, we define this as substitution simulation. When using location simulation, the character substitutions are chosen at random. When using substitution simulation, the mutation location is chosen uniformly at random among available locations. Note that in normal computer simulation, both mutation location and character substitution are chosen uniformly at random. We describe this in more detail in our methods section.
As Figure 11 shows, MP's performance on the location simulation data is very similar to its performance on the Avida data, even when the Avida data is generated using the biased F and L character substitution processes. These results suggest that one reason natural selection improves the performance of maximum parsimony in some cases is its introduction of ASRV.
To further test the impact of ASRV and character substitution models on the performance of maximum parsimony, we performed comparable experiments using data from PSeq-Gen. For each of the four character substitution models (uniform, JTT, PAM, and mtREV), we generated 1000 replicates using both α = 1, which corresponds to significant ASRV, and α = 100, which corresponds to essentially no ASRV. For each data set, we computed MP's performance.
Maximum parsimony may perform significantly better on actual biological data than is currently suggested by computer simulation studies due to the effects of natural selection. In sequences that evolve subject to natural selection and which experience a geographic separation, specific sites in the genome that perform critical functions become resistant to accepted mutations. As there are typically many distinct ways to perform a function, the solution derived by one population is likely to be different than the solution derived by the second population. The sites associated with these different solutions provide a signal that aids in the reconstruction of phylogenies. As this phenomenon is more strongly associated with locations rather than the specific substitutions that occur, ASRV appears to have a stronger impact on phylogeny reconstruction than character substitution probabilities.
It is important to note, however, that natural selection led to improved reconstruction accuracy for Maximum Parsimony only when there were changes in rewarded tasks that led to intermediate ancestors acquiring significant adaptations. This would suggest that natural selection will only help in reconstructing phylogenies from taxa that diverged due to new selective pressures. The prevalence of this phenomenon in the natural history of our world will determine to some extent the significance of this finding.
It is also important to note that we performed all our experiments using symmetric tree topologies. Maximum parsimony is known to perform poorly when the topologies are not symmetric [31–33]. It is a natural question to ask how the effects of natural selection interact with the issue of long branch attraction.
In future work, we plan to test whether our results and conclusions still hold when applied to larger phylogenies, to smaller character sets, or when our techniques are applied to tree reconstruction algorithms other than Maximum Parsimony. Furthermore, we plan to evaluate how well Maximum Parsimony performs on asymmetric tree topologies.
Our basic methodology is simple. We first generate a set of four taxa with a known phylogeny that evolves subject to natural selection using Avida. We label the four taxa as A, B, C, and D and the three internal ancestors at bifurcation points as X, Y, and Z. See figure 1 for an illustration. Next, we generate three sets of computer simulation data based on our known phylogeny. We work with 4 taxa trees because we can compute the most parsimonious tree quickly and we can simplify the problem of determining if a tree is correct. Specifically, there are 3 distinct topologies that can be produced by a reconstruction algorithm; the correct one, which pairs A with B and C with D, or two possible false answers that incorrectly pair A with C and B with D, or incorrectly pair A with D and B with C.
We assess the performance of maximum parsimony for a given data set as follows. If maximum parsimony outputs only the correct tree topology, it is given a score of 1 since the correct answer is given unambiguously. If maximum parsimony outputs two possible tree topologies, one correct and one incorrect, it is given a score of 1/2 since the correct answer is given but an incorrect answer is given as well. If maximum parsimony outputs all three possible tree topologies, it is given a score of 1/3. If maximum parsimony fails to output the correct tree topology, it is given a score of 0. Note that randomly selecting a topology (or a combination of topologies) would have an expected accuracy of 1/3.
Generation of known phylogenies with Avida
We set the copy command to fail with a uniform probability of 0.75%, which means that for a typical replication, .75 (out of the 100) instructions would be copied incorrectly. When a copy command fails, a random instruction is written in its place, each with equal probability in our default setting. For some Avida experiments, we used two non-uniform character substitution processes F and L, which emphasize the first 13 instructions and the last 13 instructions, respectively. When the copy command fails with the F (L) character substitution process, each of the first (last) 13 instructions is written in its place with probability 4/65 and each of the last (first) 13 instructions is written in its place with probability 1/65.
After running for L1 = 200 generations, we identified the most abundant genotype S2 (or X from Figure 1) and placed S2 into a new environment E2. We executed two parallel experiments of S2 in E2 for 1.08 × 1010 cycles, which is approximately 104 generations. In each of the two experiments, we then sampled genotypes at L2 equal to 3, 30, and 100 along the line of descent from S2 to the most abundant genotype at the end of the execution. Let S3a-x denote the sampled descendant in the first experiment for L2 = x while S3b-x denotes the same descendant in the second experiment. Note that S3a-x and S3b-x correspond to internal ancestors Y and Z from Figure 1.
Next, for each value x of L2, we took S3a-x and S3b-x and put them each into a new environment E3. Again, we executed two parallel experiments for each organism. In each of the four experiments, we then sampled genotypes at L3 equal to a set of values from 10 through 600 along the line of descent from S3a-x or S3b-x to the most abundant genotype at the end of the execution. For each value of L3, four taxa A, B, C and D were used for reconstruction. Organisms A and B share the same ancestor S3a-x while organisms C and D share the same ancestor S3b-x.
Within the environments E1, E2, and E3, there were energy bonuses associated with ten different Boolean logic tasks which, in order of complexity, are ECHO, NOT, NAND, AND, ORNOT, OR, ANDNOT, NOR, XOR, and EQUAL. We use many different reward structures for our Avida experiments. Our default reward structure is the overlapping reward structure where tasks ECHO, NOT, NAND, AND, and ORNOT are rewarded in E1, tasks AND, ORNOT, OR, and ANDNOT are rewarded in E2, and tasks ANDNOT, NOR, XOR, and EQUAL are rewarded in E3; note that there are tasks shared between E1 and E2 and between E2 and E3. We also consider the no-task reward structure where none of the ten logical tasks are rewarded in environments E1, E2 and E3; the non-overlapping reward structure where tasks ECHO, NOT, and NAND are rewarded in E1, tasks AND, ORNOT, and OR are rewarded in E2, and tasks ANDNOT, NOR, XOR, and EQUAL are rewarded in E3; the 3-tasks reward structure where tasks ECHO, NOT, and NAND are rewarded in environments E1, E2 and E3; and the 10-tasks reward structure where all 10 Boolean logic tasks are rewarded in environments E1, E2, and E3.
The internal branch length of our tree structure is twice the value of L2, for which we used values 3, 30 and 100. Note that L2 = 3 means that, for example, genotype S2 is genotype S3a-3's great grandparent. Typically, the number of mutations that differentiate a parent from a child is exactly one, but occasionally the number can be two or more. Furthermore, it is possible that two mutations that occur in the line of descent from genotype S2 to S3a-x may affect the same genomic position. Thus, L2 does not necessarily represent the Hamming distance between genotypes S2 and S3a-x. Similar observations apply to L3. The external branch length of our structure is simply L3, which ranged in value between 10 and 600. For each environmental model and each setting of L2 and L3, we produced 100 4 taxa phylogenies.
Generation of Computer Simulation Data
Given the known phylogeny, which includes the exact sequence information of all internal ancestors, we perform several computer simulations that mimic the actual population with varying degrees of accuracy. In all the simulations, we follow the actual phylogeny exactly in terms of number of mutations. That is, if there were exactly 5 mutations from X to Y in the actual phylogeny, there will be exactly 5 mutations from X to Y in the simulated phylogeny. The computer simulations differ only in the mutation location and/or the character substitution models employed.
The control model uses both a uniform mutation location model and a uniform character substitution model. The location simulation model uses a uniform character substitution model but emulates exactly the position of all mutations. That is, if the 5 mutations occurred in (for example) positions 3, 15, 23, 47, and 98 of sequence Y in the actual phylogeny, they will also occur in positions 3, 15, 23, 47, and 98 of sequence Y in the simulated phylogeny, though the specific characters involved may differ. Finally, the substitution simulation model uses a uniform mutation location model but emulates exactly the substitutions that occur. That is, if the 5 mutations of sequence Y in the actual phylogeny were (a, f), (e, z), (f, t), (s, a), and (z, u) where the first entry of each order pair is the original character in sequence X and the second entry of each order pair is the character after mutation in sequence Y, then we enforce that the same changes occur in the simulated phylogeny, though at potentially different positions.
For each of the 100 Avida trees, we generated a new dataset using each simulation model, resulting in a total of 400 trees (the 100 originals plus 300 simulated trees).
Generation of PSeq-Gen Data
The PSeq-Gen tool is widely used to simulate the evolution of protein sequences along evolutionary trees. Three substitution models are implemented in PSeq-Gen: JTT, PAM and mtREV. We introduced a uniform substitution model where all the substitutions are equally likely. The only mutation location model implemented in PSeq-gen is the Gamma distribution. A small value for α simulates a large degree of site-specific rate heterogeneity, and as this value increases, the simulated data becomes more rate-homogeneous. We used two α values, 1 and 100. Thus we had a total of 8 unique parameter settings: four substitution models combined with two alpha values. Based on our four taxa model tree, for each parameter setting, we generated 1000 independent replicates. All the simulations use sequence length 100.
This work was supported in part by NSF grants EIA-0219229 and CCF-0523449, and the Quantitative Biology and Modeling Initiative at Michigan State University. The authors also thank Wei Huang and Matthew Rupp for their helpful comments.
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