Logo of plosonePLoS OneView this ArticleSubmit to PLoSGet E-mail AlertsContact UsPublic Library of Science (PLoS)
PLoS One. 2012; 7(1): e30591.
Published online Jan 25, 2012. doi:  10.1371/journal.pone.0030591
PMCID: PMC3266278

Mutational Robustness of Gene Regulatory Networks

Stefan Maas, Editor

Abstract

Mutational robustness of gene regulatory networks refers to their ability to generate constant biological output upon mutations that change network structure. Such networks contain regulatory interactions (transcription factor – target gene interactions) but often also protein-protein interactions between transcription factors. Using computational modeling, we study factors that influence robustness and we infer several network properties governing it. These include the type of mutation, i.e. whether a regulatory interaction or a protein-protein interaction is mutated, and in the case of mutation of a regulatory interaction, the sign of the interaction (activating vs. repressive). In addition, we analyze the effect of combinations of mutations and we compare networks containing monomeric with those containing dimeric transcription factors. Our results are consistent with available data on biological networks, for example based on evolutionary conservation of network features. As a novel and remarkable property, we predict that networks are more robust against mutations in monomer than in dimer transcription factors, a prediction for which analysis of conservation of DNA binding residues in monomeric vs. dimeric transcription factors provides indirect evidence.

Introduction

Transcription factors (TFs) regulate gene expression by binding to DNA adjacent to target genes. In addition, TF proteins often physically interact with each other and form protein dimers, which in combination with regulatory interactions gives rise to an intricate network of interactions. Aspects of TF-TF protein-protein interactions and how these change during evolution have been studied [1], [2], [3], and dimerization is known to be important for various TF families [4]. Known or presumed biological roles of TF dimerization include potential effects at the level of DNA recognition, such as facilitated proximity and enhancement of DNA-binding specificity. Roles at the level of the network output include that dimerization might function to dampen noise due to fluctuations in monomer concentrations [5], or might be important in attaining multistability in certain types of networks [6]. Dimerization could also serve as a means to generate ultrasensitive responses via molecular titration, which occurs when an active subunit is sequestered into an inactive heterodimer complex by a titrating molecule [7]. Depending on interaction strength, dimerization also influences the kinetics of the TF-DNA search process [8].

Perturbations of gene regulatory networks, either through input concentrations, parameters of the interactions, or the network topology, can result in changes in network output, i.e. the resulting expression pattern. Robustness refers to the stability of this output in response to perturbations, and although robustness against perturbations of concentrations or against parameter changes has obtained a lot of attention [9], [10], [11], [12], [13], [14], [15], [16], [17], [18], the effect of evolutionary tinkering with network structure via changes in the sequences of the underlying components has received less attention [18], [19], [20], [21], [22]. This is true in general, but in particular for networks which contain dimerizing TFs. Given the biological importance of TF dimerization as explained above, better understanding of robustness of such networks would be valuable.

Computational studies of the effects of network rewiring have been performed mainly using discrete approaches such as Boolean Networks (BNs) or related models. Robustness and evolvability of a BN under the process of gene duplication followed by divergence was studied, and it was found that networks operating close to the ‘critical regime’, which depends on the network connectivity, exhibit the maximum robustness and evolvability simultaneously [23]. Several studies focused on the relation of robustness to mutations with robustness to noise [19], [20]. These two were shown to be highly correlated [24]. In addition, nearly all networks can evolve toward greater robustness through gradual changes in topology. It was also shown that two networks with exactly the same phenotype may produce very different innovations, depending on their topology [22].

Importantly, various experimental analyses indicate that gene regulatory networks can be highly robust against network rewiring [25], [26], [27]. However, network properties influencing it are not clearly understood. Here, we analyze the relation between network properties and mutational robustness using a computational approach, in combination with an integrative analysis of various experimental datasets.

Results

We investigated robustness against mutations in large ensembles of simulated network models (Figure 1). In these networks, two types of interactions were present: TF-target gene (regulatory) interactions, and TF-TF protein-protein interactions. In contrast with previous studies of robustness and evolvability that used discrete models, we used ordinary differential equations to simulate networks. Each ensemble was constructed using specified topology parameters and within ensembles, TF-TF and TF-target gene interaction parameters were sampled. We applied two types of mutations: protein-protein interaction mutations and mutations of regulatory interactions. These mutations were designed such that, for a protein interaction mutation, all regulatory interactions were retained, and for a regulatory interaction mutation, all protein interactions were retained. The difference between the resulting expression pattern (network output) of mutated vs. wildtype networks was represented by the metric Dmut; thresholds for “small” and “large” differences, Dsmall and Dlarge, were derived from experimental data and are described in the first part of the Results section. After that, we describe the observations from our simulations, followed by comparison with experimental data.

Figure 1
Overview of our study of evolutionary robustness.

Expression data analysis and Dmut cutoffs

In our analysis of robustness of gene regulatory networks against network rewiring, we want to characterize whether differences in expression between two network variants are ‘large’ or ‘small’. We use a metric Dmut to compute the difference between two such expression patterns. An important methodological question is how to determine a suitable cutoff for Dmut such that the difference between the expression patterns is “small” or “large”. The need for a threshold value to define whether a mutation has a large influence on network output arises because we use a continuous instead of the previously used discrete approaches to study robustness. In the latter, one typically finds the stable states of wildtype and mutated networks and compares those to see whether they are exactly identical or not. This is however not directly applicable in our case.

To answer the question how to define threshold values for Dmut, we computed Dmut values obtained by analyzing a number of different gene expression datasets. We performed two inter-species comparisons, where we compared expression data for four different wine yeast strains [28] and for two Drosophila species [29], as well as two intra-species comparisons (comparing different cell types) within Arabidopsis thaliana [30] and within human [31] (Figure 2). To define a cutoff for ‘large effect’, we reasoned that at least some of the differences in expression of network components between species must be responsible for differences between those species. We obtained the Dmut observed in the cross-species set such that 99% of the cases have a lower Dmut. For the wine yeast strains, 99% of the cases have a Dmut below 0.92, and for the two Drosophila species (which are at a larger evolutionary distance) this is 1.7. We take a value between those two values as a cutoff for “large effect” and set this cutoff at Dlarge = 1.0.

Figure 2
Histogram of Dmut for experimental datasets.

To obtain a lower limit for Dmut below which we could say that the effect is likely to be small, we reasoned that at least some networks would be expected not to change between various conditions or tissues within one species. Hence, we analyzed the two datasets of expression between various conditions/tissues within one species. Here, in the human dataset, 99% of the cases had Dmut above 0.1, and for the Arabidopsis dataset 99% had Dmut above 0.5. Note that the Arabidopsis dataset is more targeted (a small number of factors known to be involved in the process of flowering was analyzed, for which the different tissues selected from the dataset are the relevant ones). We take again a value in between and set this cutoff at Dsmall = 0.2. For the wineyeast set a cutoff based on similar reasoning would be 0.11, and for Drosophila 0.33, which are compatible with this value.

We are aware of the fact that our analysis here does not give a definite answer on how to define whether a gene regulatory network mutation has a “large” effect. However, to a certain extent we circumvent the associated problems by comparing different types of changes with each other, which means that we analyze relative Dmut values instead of their absolute values. Importantly, the main conclusions from our analysis were robust against the exact value of the defined cutoffs (Text S1, Table S1).

Simulation results

To simulate gene regulatory networks, systems of ordinary differential equations (ODEs) were used, which describe TF-TF dimerization and TF-target gene regulation (via Hill functions). To investigate the stability upon network rewiring, for each network, one ‘wildtype’ simulation was done, and two simulations of mutated versions. One mutated network was obtained with a protein-protein interaction change, where a dimer A–B is changed to dimer A–C (that did not occur yet in the protein-protein interaction network). All other dimers are preserved, and this new dimer preserves the regulatory interactions of the original dimer. A second mutated version of the network was obtained with a regulatory change where for one specific dimer, one of the genes that it regulates is changed to another gene (which it did not yet regulate). In this case, none of the protein-protein interactions is changed. For monomeric networks, only a mutation in a regulatory interaction was applied. The way in which these mutations are constructed ensures that the number of interactions does not change, which allows a more fair comparison between wildtype and mutated system than in case this number would change. The resulting stable state concentrations after simulating the mutated networks were compared with the wildtype concentrations using Dmut. If networks with certain properties obtain in most cases a low Dmut upon certain types of mutations, then these networks have a high robustness against that particular type of mutations, and vice versa.

Theoretical results for e.g. Boolean Networks or related models are often reported with densely connected networks (many regulatory interactions per gene) but this means that adding spurious interactions is rewarded in the sense that mutating such interactions will not lead to phenotypic changes, resulting in an artificially increased robustness. Because of that, we chose values for fractions of regulatory interactions that are close to what was found in various experimental networks [32]. We also distinguish ensembles of networks based on their connectivity, making a proper comparison between networks with similar connection density. The fraction of dimers (Fdim) in our networks equaled 0.0 (monomeric networks), 0.3, or 0.6, and the fraction of regulatory interactions (Fregint) equaled 2.0 or 4.0. Here Fdim was defined as the fraction of dimers out of all putatively possible dimers, and Fregint as the average number of TFs regulating the expression of a given target. We also separately analyzed networks with different fractions of activating interactions (0.25, 0.5, and 0.75) but because these resulted in overall similar observations (Supporting Information Figure S1), the analysis below focusses on networks with fraction activating interactions 0.5.

We made five key observations on network robustness (Table 1). First, protein interaction mutations are more likely to have a large effect than mutations in regulatory interactions, especially in case of a low fraction of dimers (Figure 3A). Using a randomization procedure, this difference in robustness was statistically significant (p<0.001) for three of the four cases shown; only for the case with Fdim 0.6, Fregint 4.0 it was not significant (p~0.1). Second, repressive interactions are associated with a higher robustness against protein-protein interaction mutations as well as regulatory interaction mutations, compared to activating interactions. This was assessed by counting the number of repressive vs. activating interactions that the regulator affected by the mutation was involved in. In particular, when the regulator was only involved in repressive interactions, averaged over the different ensembles, the average (standard deviation) of Dmut was only 0.39+/−0.47, whereas when the regulator was only involved in activating interactions, it was 0.62+/−0.46. Similar but more pronounced differences were obtained when analyzing this effect for each of the different values of Fdim and Fregint separately (Text S1, Table S2).

Figure 3
Variation of gene regulatory network robustness.
Table 1
Predicted effects of various network characteristics on robustnessa.

Third, to explore the interdependency of mutations, we tested for possible compensatory effects, i.e. two subsequent mutations that in combination result in a small net change to the original expression pattern although the first mutation has a large effect. Because protein interaction mutations had the largest effect, our starting point was protein interaction mutations with high impact (Dmut>Dlarge). When the follow-up mutation is again a protein interaction mutation, the overall robustness for the combination of the two mutations does not depend much on the fraction of activating interactions. When the next mutation is a regulatory mutation, however, the percentage of compensatory mutations increases with increasing amount of activating interactions; at the highest fraction of activating interactions, a given regulatory mutation has a ~3.5% chance of ‘rescuing’ a previous large-effect protein interaction mutation (Figure 3B). The exact value of this percentage depends on the value of the thresholds for Dmut defined above (for example, with a stricter threshold it is ~1%) but the trend observed in Figure 3B stays the same. The fact that we find computational evidence for such compensatory mutations is novel, and as discussed below, there are various experimental indications that compensatory mutations indeed exist. Fourth, networks without dimers are much more robust against changes in regulatory interactions (Figure 3A). Using a randomization procedure, this difference in robustness was statistically significant (p<0.001) for each of the comparisons between monomeric and dimeric networks with the same fraction of regulatory interactions. Finally, when the number of autoregulatory interactions increases, the robustness against protein interaction mutations decreases, but against regulatory mutations increases (Figure 3C).

Integration with biological data

The best way to validate our predictions would be to compare gene regulatory networks across different species. In combination with expression patterns, this would shed light on how evolutionary changes of network structure do or do not result in changes in network output. In the absence of sufficient amounts of such data, we obtained indirect evidence from data on biological networks. Three of the five predictions summarized in Table 1 are consistent with such data. For two of these, our reasoning was that network features which are less robust upon changes should be more conserved. First, we predicted that networks are more robust against regulatory mutations than against protein interaction mutations. This is consistent with the observation that protein-protein interactions are more conserved than regulatory interactions [33], [34], and although this is well-known, the fact that our simulations reproduce it is reassuring for our approach. Second, we predicted more robustness against changes in repressive interactions; indeed it has been reported that activators are somewhat more frequently conserved among bacterial genomes than repressors [35]. That same study also reported that mixed activators/repressors have the highest conservation, which would suggest the lowest robustness upon mutation, following the reasoning that network features which are less robust upon changes should be more conserved. Indeed we observed in part of our network ensembles, although not in all of them, that mixed regulators lead to lowest robustness, depending on the topology parameters. However, in our analysis indeed mixed regulators appeared to have lower robustness than pure repressors for all topology parameters (details are reported in Text S1, Table S2). Third, the existence of compensatory mutations is supported by various lines of evidence [27], [36], [37], [38]. For example, the evolution of alternative transcriptional circuits with identical output logic has been described [36], and a study on combinatorial gene regulation reported turnover of cis-acting sequence and the formation of new protein-protein interactions [37]. Similarly, analysis of allele-specific expression in parental and hybrid strains revealed the existence of compensating mutations in various species [38], [39]. In this last example, contrary to the first two examples, it is known that the individual mutations indeed have significant effects.

For our prediction about autoregulatory interactions, where we found an opposite dependence of robustness against protein interactions mutations or against regulatory mutations on the number of such autoregulatory interactions, we did not find data for falsification or verification. However, if our prediction is correct, it could be an important aspect of gene regulatory network evolution that robustness against different types of mutations requires a different optimal fraction of autoregulatory interactions. In general, autoregulatory interactions are known to be important for various aspects of regulatory networks, including speeding up response times [40] and providing robustness against fluctuations in concentrations [41], and hence how mutational robustness of gene regulatory networks is influenced by autoregulatory interactions is an important issue.

Finally, a novel and remarkable prediction is that mutations in regulatory interactions lead to larger changes in networks with dimeric TFs compared to networks with monomers. Given the importance of TF-TF protein-protein interactions as explained above, this difference in robustness could be an important aspect of regulatory interaction network evolution. For this predicted difference in robustness, we obtained indirect validation by analyzing differences in conservation of DNA-contacting residues in monomeric and dimeric TFs. Here we followed again the reasoning that features which are connected to lower robustness should be more conserved. Hence, based on our prediction, we expect on average more conservation of dimeric DNA-contacting residues, compared to the conservation of such residues in monomeric TFs. To test this hypothesis, we analyzed the distributions of sequence entropy values for DNA-contacting residues in both types of TFs, using a set of 57 monomeric and 228 dimeric human TFs for which structural information was available (Figure 4). Indeed, these were significantly different as tested using a Kolmogorov-Smirnov test (p<10−15). Dimeric DNA-contacting residues display lower entropy, i.e. higher conservation, in accordance with our hypothesis. Such differences were not observed for residues in those TFs that do not contact DNA.

Figure 4
Cumulative histogram of sequence conservation of DNA contacting residues in human TFs.

Discussion

Robustness in biological networks can have various origins. First, redundancy of gene functions is important, as genes with overlapping functions will be able to compensate for each other. A second source is robustness that has its origin in interactions between genes with unrelated functions, i.e. different positions in the network, not having the same set of interactions. Such robustness is a property of the network as a whole and not solely of some of the components. Some studies indicated that such “distributed robustness” would be more important than redundancy for robustness against mutational loss in yeast [42], [43], although this has been challenged [44]. In our analysis this second type of robustness is what we look at. Our model is relatively simple; in particular, there is no explicit coupling between dimerization and DNA interaction specificity. However, compared to existing approaches using Boolean Networks or related approaches our use of ODEs means that we can study more biological relevant aspects, in particular explicit dimerization.

We focused on obtaining evidence for factors influencing robustness against mutations of network structure. The results of our analysis provide several clues towards such factors. An important follow-up would be to investigate in detail the mechanistic aspects of why certain types of networks are more robust than others. Although we will leave that question to a large extent to be addressed by future work, we briefly discuss two relevant issues. One is related to the observation that regulatory mutations in dimer networks have larger effect than in monomeric networks. This might be related to the fact that in dimeric networks, the change in expression of a target gene caused by a regulatory mutation will not only influence other genes via regulatory interactions of that target, but also via protein interactions that it is involved in. We obtained evidence for this by analyzing whether the regulatory mutation mainly had a direct effect (changing expression level of the target gene targeted by the mutation) or mainly an indirect effect (changing expression levels of other genes). In dimeric networks, the indirect effect was much larger than the direct effect, whereas for monomeric networks, the indirect effect was somewhat smaller than the direct effect. Comparing dimeric and monomeric networks, the direct effects were roughly comparable, whereas the indirect effect was much larger in the dimeric network (data not shown). Although this should be analyzed in more detail, this analysis indicates a causal mechanism for the observed differences in robustness between dimeric and monomeric networks. A second point is related to the fact that repressive interactions confer more robustness; here one could argue that the effects of a mutation in an interaction which tends to switch off expression of a target gene, will be less easily transferred to other parts of the network, compared to a mutation in an interaction that activates a target gene, because in the latter case the product that has been upregulated might have all kinds of additional effects.

In addition to regulatory interactions, protein-protein interactions are an important type of connections in gene regulatory networks [4]. Our analysis provides insight into how mutations of both types of interactions can shape network evolution. We studied compensation between protein-protein and regulatory mutations; such compensatory mutations have indeed been observed experimentally, as mentioned above. These observations so far constituted isolated examples, but our results highlight the potential general importance of this type of interplay between protein-protein interaction mutations and regulatory mutations, providing a framework for further study of such effects. In addition, based on observed differences in robustness in our simulations, we predicted differential conservation of DNA-contacting residues in monomeric vs. dimeric TFs, a prediction which we validated using protein structure and sequence data.

The integration and comparison with biological data that we perform is based to some extent on the hypothesis that network features which induce lower robustness upon mutations to network structure should be more conserved. Obviously, this hypothesis needs not always hold, because for some processes and in some circumstances evolutionary change and not robustness will be favorable and will be selected. Nevertheless, the trends we find are consistent with biological datasources. For one of those, the fact that TF-DNA interactions are less conserved than protein-protein interactions, it is important to realize that this does not necessarily mean that DNA binding domains of TFs are less conserved than protein interaction domains. In fact, the opposite has been observed in an analysis that focused on conservation of DNA binding domains (although not specifically on residues involved in DNA binding) [4]. However, because of rapid turnover of TF-binding cis-motifs [33], [34], [45], at the network level the net effect is still that regulatory interactions are less conserved than protein-protein interactions [33], [34].

Our results clearly demonstrate the importance of taking protein-protein interactions into account when studying the robustness of gene regulatory networks. Although much attention in studying gene regulatory networks and their evolution has been focused on regulatory interactions, recently data is coming available which integrates TF-TF interactions within the context of such networks [46]. In addition, powered by the ongoing revolution in sequencing technologies and their application in e.g. ChIP-seq experiments, large amounts of data on transcriptional regulatory interactions and the evolution of network connections are being generated [47], [48], [49]. Our analysis provides a framework for further study of these networks and their evolution. In particular, previous studies indicated the importance of functional constraints on network topology, such as the importance of different types of topologies to obtain either multistationarity or homeostasis [50]. Our results implicate the existence of additional evolutionary constraints.

Methods

Simulations of network models

Network models were simulated using ordinary differential equations (ODEs) where monomer and dimer concentrations were represented explicitly. The rate of change of the dimer concentrations consists of the association rate of monomers into dimers minus the dissociation rate of dimers into monomers, minus the dimer decay rate. Denoting by xi the concentration of monomer i and by xij the concentration of a dimer consisting of proteins i and j, we have the following equation in case of a single dimer:

equation image

Here kon, koff are the forward and backward dimerization rate constants and γdim is the dimer decay rate. Extensions in the more general case where multiple dimers are formed are presented in Text S1.

For the monomer dynamics, activating or repressing Hill functions were used to model gene regulation, which are combined with dimerization reactions and monomer decay. In the case of regulation by one particular dimer, for a protein involved in one dimerization reaction, we have the following equations:

equation image

for activation and repression, respectively. Here bik and Kik are Hill function parameters for the regulation of gene i by dimer k (in a more general setting one could also include a cooperativity parameter but we set this to 1). γmono is the monomer decay rate. Extensions for more general cases are shown in Text S1.

In order to compare the simulated systems with dimeric protein-protein interactions, also networks were simulated with only monomeric proteins. These monomers directly regulate transcription, again via Hill functions (equations for monomeric systems are provided in Text S1)

Parameters that occur in those equations were randomly chosen in various network realizations, but were limited to certain ranges or values (Table 2). These were based on literature values [7], [51], [52]. Parameters that describe the topology of the systems are shown in Table 2 as well. The fraction of dimers is calculated as follows: fdim = ndim/(0.5*nprot2+0.5*nprot). Here ndim is the number of dimers present in the network. The fraction of regulatory interactions (Freg) is the average number of dimers or monomers regulating a gene.

Table 2
Network model parameters and network topology parameters.

We investigated how the robustness of the network output depends on the topology parameters in randomly generated networks. To analyze this, two test sets were generated: 1) set1, with a limited number of networks where a large number of ODE parameter assignments could be tested, and 2) set2, with a much larger number of networks, without sampling of the ODE parameters for each network. For set1, 20 different networks were generated with random topology for each combination of parameters in Table 2, except that Fregint was only set equal to 2.0, giving 120 networks in total (2×3×20). The network topology was generated using the selected values of interaction densities as probabilities for each possible protein-protein interaction or regulatory interaction, ensuring however that each gene is regulated by at least one dimer or monomer. For each of these networks, 1,000 random assignments were generated for Hill parameters, kon and starting concentrations. This set was used for the analysis of compensatory mutations.

Set2 was used for the other analyses; here, much larger ensembles of networks were generated, using all possible combinations of network parameters shown in Table 2. In each such ensemble, 25,000 different topologies were generated, all with the same number of proteins, same fraction of dimers and same fraction of regulatory interactions, but each with different connections. For each such network, parameters were initialized randomly within the boundaries indicated in Table 2.

Simulations were started using only monomers present; their values were set to randomly chosen values within the range of 1 nM–100 nM. The simulation time was 15,000 min. ODEs were solved using Biocham [53] with the fourth-order Runge-Kutta method, adapting the step size to a maximum error of 1E-10 and using the default initial step size of 0.01.

To investigate the stability upon network rewiring, the following simulations were performed. For each parametrized system of ODEs, one ‘wildtype’ simulation was done. Then, independently from each other, two mutations were performed changing network structure: (1) a protein-protein interaction change, where a dimer A–B is changed to dimer A–C (that did not occur yet in the protein-protein interaction network); this new dimer keeps exactly the same regulatory interactions as were previously attached to the deleted dimer; (2) a regulatory change where for one specific dimer, one of the genes that it regulates is changed to another gene (which it did not yet regulate). All parameters remain unchanged when performing those mutations; the ‘new’ interaction takes over the parameters from the ‘old’ interaction. Figure 1 provides a graphical illustration of the mutations. The way in which these mutations were constructed ensures that the number of interactions does not change, which allows a more fair comparison between wildtype and mutated system than in case this number would change. The mutated systems were simulated as well, and the resulting concentrations were compared with the wildtype concentrations.

To assess the change after mutation, a relative change was defined as follows (Dmut):

equation image

Here the summation goes over all concentrations (i.e. n equals the number of monomers plus the number of dimers), Cwt is the wildtype concentration and Cmut the value observed in the mutated system.

Expression data analysis

An important methodological question is how to determine a suitable cutoff for Dmut such that the difference between the expression patterns is “small” or “large”, i.e. a cutoff Dsmall and a cutoff Dlarge. To answer this question, we calculated values obtained for Dmut by analyzing a set of different gene expression datasets. These included two inter-species comparisons, using expression data for four different wine yeast strains [28] and for two Drosophila species [29], and two intra-species comparisons (comparing different cell types) within human [31] and within Arabidopsis thaliana [30]. For the latter, a focused set of factors involved in flowering and floral organ determination was used: AG, AP3, PI, AP1, SHP1, SEP3, WUS, LFY, UFO, miR172, SUP, LUG, SEU, SAP, RBE, YUC2, YUC6, YUC1, YUC4, PIN1, NPY1, BLR, CUC1, whereas for human the dataset consisted of genome-wide expression data across several tissue. For all datasets, we randomly selected 6 proteins 1,000 times and computed their Dmut values between two different conditions (different species or different tissues).

Note that multiplicative normalization of microarray data does not influence the calculated Dmut. However, log transformation does, so in case of the Drosophila data we back-transformed the log transformed data.

Statistical significance of observed differences in network robustness

Statistical significance of the observed differences in robustness between protein interaction vs. regulatory changes was assessed using a randomization procedure. Here, the observed values of Dmut for the mutated networks were randomly reassigned to ‘protein interaction’ or ‘regulatory interaction’ mutation. Next, the percentage of rewired networks with only a small change (Dmut<Dsmall) was calculated for these randomized datasets, and the difference between those percentages for protein interaction vs. regulatory interaction mutations in the randomized datasets was compared to the observed difference obtained with the input dataset. This was repeated 1,000 times. A p-value was obtained as the number of cases in which this difference was at least as large in the randomized datasets as compared to what was obtained with the input datasets. In a similar way, the significance for the difference in robustness observed for regulatory changes in monomeric vs. dimeric networks was assessed.

Compensatory mutations

For mutations that produced a large change (Dmut>Dlarge) we tested if compensatory mutations could be found that to a large extent rescued the phenotype of the network. A second mutation was applied, and all parameter values remained unchanged. This was tested with set1 described above, applying 1,000 regulatory and 1,000 protein interaction mutations as secondary mutations to each primary high-effect mutation.

Network properties

The network ensembles we generated were based on ‘simple’ topological parameters (number of proteins, number of interactions). More involved parameters might offer a more comprehensive description of network properties of relevance for mutational stability. One example is regulation entropy, which was calculated as described in ref. [18]. Briefly, first all regulatory paths between two nodes are obtained (for which we simply did an exhaustive search which is very fast in our small networks). Next, each path is scored as positive if the number of repressing interactions is even, and negative if this number is odd. The entropy of the regulation of one node by another node is the entropy calculated using the fractions of positive and negative paths. The regulation entropy of a given node is the average of its regulation entropies with respect to all the other nodes.

For the networks without dimerization this calculation is identical to that in ref. [18]. However, for the dimeric systems, one has to choose how to treat dimers when finding regulatory paths between two nodes. We simply used the most straightforward approach, consisting of ‘splitting’ each dimer such that for each dimeric regulatory interaction, the path finding in fact finds two branches. Regulation entropy did not show clear relationship with robustness and is not presented in the Results section.

In addition to regulation entropy, we also used the number of autoregulatory interactions as a characteristic of the network. In this case, only direct interactions are used. As with regulation entropy, for each dimer we ‘splitted’ the regulatory interaction such that if a dimer A–B regulates both A and B, there would be two autoregulatory interactions.

As a third parameter, redundancy of interactions was calculated as a proxy for gene function redundancy. Here, we calculated interaction similarity, for dimer interactions, for regulatory interactions and for both types of interactions. Interaction similarity was defined as the number of similar interactions divided by the number of different interactions plus the number of similar interactions. We analyzed both average and maximum interaction similarity. This did not result in any clear dependence of robustness on redundancy; hence, this analysis is not presented in the Results section.

Structure analysis

To test the hypothesis that DNA-contacting residues in dimeric TFs are more conserved than those in monomeric TFs, a set of human dimeric and monomeric TFs was assembled using information from the HPRD database [54]. We compared TFs (obtained by using the GO term 0003700, transcription factor activity) that at least interact with one other TF according to the HPRD data with those TFs that do not interact with any other TF. The TFs were mapped to available protein structures, as obtained from the GTOP database [55]. DNA contacting residues were defined using a cutoff of 10 Å (using 5 Å instead did not change the results). Conservation was assessed on sequences obtained by using blast [56] vs. the NR database and keeping one randomly chosen sequence per species (with a blast E-value cutoff of 1E-25). As a measure of conservation, sequence entropy was calculated.

Supporting Information

Text S1

Contains information about simulation setup and details of results.

(PDF)

Figure S1

Percentage of networks whose output does not change upon mutation (Dmut<Dsmall). Fraction of dimers (Fdim) equals 0.0, 0.3 or 0.6, and fraction regulatory interactions (Fregint) equals 2.0 or 4.0. Blue, protein interaction mutations (only for cases with Fdim>0); red, regulatory mutations. (A) Fraction activating interactions 0.25. (B) Fraction activating interactions 0.5. (C) Fraction activating interactions 0.75.

(TIF)

Table S1

Robustness against protein interaction vs. regulatory interaction mutation.

(PDF)

Table S2

Robustness against mutations in repressive vs. activating regulators.

(PDF)

Footnotes

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

Funding: This work was carried out within the research programme of the Netherlands Consortium for Systems Biology (NCSB), which is part of the Netherlands Genomics Initiative/Netherlands Organization for Scientific Research. This work was also supported by the Netherlands Organization for Scientific Research (NWO, VENI Grant 863.08.027 to ADJvD). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

References

1. van Dijk AD, Morabito G, Fiers M, van Ham RC, Angenent GC, et al. Sequence motifs in MADS transcription factors responsible for specificity and diversification of protein-protein interaction. PLoS computational biology. 2010;6:e1001017. [PMC free article] [PubMed]
2. van Dijk AD, ter Braak CJ, Immink RG, Angenent GC, van Ham RC. Predicting and understanding transcription factor interactions based on sequence level determinants of combinatorial control. Bioinformatics. 2008;24:26–33. [PubMed]
3. Grigoryan G, Reinke AW, Keating AE. Design of protein-interaction specificity gives selective bZIP-binding peptides. Nature. 2009;458:859–U852. [PMC free article] [PubMed]
4. Amoutzias GD, Robertson DL, de Peer YV, Oliver SG. Choose your partners: dimerization in eukaryotic transcription factors. Trends in Biochemical Sciences. 2008;33:220–229. [PubMed]
5. Bundschuh R, Hayot F, Jayaprakash C. The role of dimerization in noise reduction of simple genetic networks. Journal of Theoretical Biology. 2003;220:261–269. [PubMed]
6. Smolen P, Baxter DA, Byrne JH. Mathematical modeling of gene networks. Neuron. 2000;26:567–580. [PubMed]
7. Buchler NE, Louis M. Molecular Titration and Ultrasensitivity in Regulatory Networks. Journal of Molecular Biology. 2008;384:1106–1119. [PubMed]
8. Geisel N, Gerland U. Physical Limits on Cooperative Protein-DNA Binding and the Kinetics of Combinatorial Transcription Regulation. Biophysical Journal. 2011;101:1569–1579. [PMC free article] [PubMed]
9. Kauffman S, Peterson C, Samuelsson B, Troein C. Genetic networks with canalyzing Boolean rules are always stable. Proceedings of the National Academy of Sciences of the United States of America. 2004;101:17102–17107. [PMC free article] [PubMed]
10. Pomerance A, Ott E, Girvan M, Losert W. The effect of network topology on the stability of discrete state models of genetic control. Proceedings of the National Academy of Sciences of the United States of America. 2009;106:8209–8214. [PMC free article] [PubMed]
11. Kwon YK, Cho KH. Analysis of feedback loops and robustness in network evolution based on Boolean models. Bmc Bioinformatics. 2007;8 [PMC free article] [PubMed]
12. Munteanu A, Sole RV. Neutrality and Robustness in Evo-Devo: Emergence of Lateral Inhibition. Plos Computational Biology. 2008;4 [PMC free article] [PubMed]
13. Prill RJ, Iglesias PA, Levchenko A. Dynamic properties of network motifs contribute to biological network organization. Plos Biology. 2005;3:1881–1892. [PMC free article] [PubMed]
14. Hornung G, Barkai N. Noise propagation and signaling sensitivity in biological networks: A role for positive feedback. Plos Computational Biology. 2008;4 [PMC free article] [PubMed]
15. Morishita Y, Kobayashi TJ, Aihara K. Evaluation of the performance of mechanisms for noise attenuation in a single-gene expression. Journal of Theoretical Biology. 2005;235:241–264. [PubMed]
16. Kwon YK, Choi SS, Cho KH. Investigations into the relationship between feedback loops and functional importance of a signal transduction network based on Boolean network modeling. Bmc Bioinformatics. 2007;8 [PMC free article] [PubMed]
17. Daniels BC, Chen YJ, Sethna JP, Gutenkunst RN, Myers CR. Sloppiness, robustness, and evolvability in systems biology. Current Opinion in Biotechnology. 2008;19:389–395. [PubMed]
18. Wu YL, Zhang XM, Yu JL, Ouyang Q. Identification of a Topological Characteristic Responsible for the Biological Robustness of Regulatory Networks. Plos Computational Biology. 2009;5 [PMC free article] [PubMed]
19. Sakata A, Hukushima K, Kaneko K. Funnel Landscape and Mutational Robustness as a Result of Evolution under Thermal Noise. Physical Review Letters. 2009;102 [PubMed]
20. Kaneko K, Furusawa C. Relevance of phenotypic noise to adaptation and evolution. Iet Systems Biology. 2008;2:234–246. [PubMed]
21. Kitano H. Biological robustness. Nature Reviews Genetics. 2004;5:826–837. [PubMed]
22. Ciliberti S, Martin OC, Wagner A. Innovation and robustness in complex regulatory gene networks. Proceedings of the National Academy of Sciences of the United States of America. 2007;104:13591–13596. [PMC free article] [PubMed]
23. Aldana M, Balleza E, Kauffman S, Resendiz O. Robustness and evolvability in genetic regulatory networks. Journal of Theoretical Biology. 2007;245:433–448. [PubMed]
24. Ciliberti S, Martin OC, Wagner A. Robustness can evolve gradually in complex regulatory gene networks with varying topology. Plos Computational Biology. 2007;3:164–173. [PMC free article] [PubMed]
25. Isalan M, Lemerle C, Michalodimitrakis K, Horn C, Beltrao P, et al. Evolvability and hierarchy in rewired bacterial gene networks. Nature. 2008;452:840–U842. [PMC free article] [PubMed]
26. Homann OR, Dea J, Noble SM, Johnson AD. A Phenotypic Profile of the Candida albicans Regulatory Network. Plos Genetics. 2009;5 [PMC free article] [PubMed]
27. Hinman VF, Yankura KA, McCauley BS. Evolution of gene regulatory network architectures: Examples of subcircuit conservation and plasticity between classes of echinoderms. Biochimica Et Biophysica Acta-Gene Regulatory Mechanisms. 2009;1789:326–332. [PubMed]
28. Townsend JP, Cavalieri D, Hartl DL. Population genetic variation in genome-wide gene expression. Molecular Biology and Evolution. 2003;20:955–963. [PubMed]
29. Nuzhdin SV, Wayne ML, Harmon KL, McIntyre LM. Common pattern of evolution of gene expression level and protein sequence in Drosophila. Molecular Biology and Evolution. 2004;21:1308–1317. [PubMed]
30. Schmid M, Davison TS, Henz SR, Pape UJ, Demar M, et al. A gene expression map of Arabidopsis thaliana development. Nature Genetics. 2005;37:501–506. [PubMed]
31. Wu C, Orozco C, Boyer J, Leglise M, Goodale J, et al. BioGPS: an extensible and customizable portal for querying and organizing gene annotation resources. Genome Biology. 2009;10 [PMC free article] [PubMed]
32. Leclerc RD. Survival of the sparsest: robust gene networks are parsimonious. Molecular Systems Biology. 2008;4 [PMC free article] [PubMed]
33. Tan K, Shlomi T, Feizi H, Ideker T, Sharan R. Transcriptional regulation of protein complexes within and across species. Proceedings of the National Academy of Sciences of the United States of America. 2007;104:1283–1288. [PMC free article] [PubMed]
34. Shou C, Bhardwaj N, Lam HYK, Yan KK, Kim PM, et al. Measuring the Evolutionary Rewiring of Biological Networks. Plos Computational Biology. 2011;7 [PMC free article] [PubMed]
35. Balaji S, Babu MM, Aravind L. Interplay between network structures, regulatory modes and sensing mechanisms of transcription factors in the transcriptional regulatory network of E-coil. Journal of Molecular Biology. 2007;372:1108–1122. [PMC free article] [PubMed]
36. Tsong AE, Tuch BB, Li H, Johnson AD. Evolution of alternative transcriptional circuits with identical logic. Nature. 2006;443:415–420. [PubMed]
37. Tuch BB, Galgoczy DJ, Hernday AD, Li H, Johnson AD. The evolution of combinatorial gene regulation in fungi. Plos Biology. 2008;6:352–364. [PMC free article] [PubMed]
38. McManus CJ, Coolon JD, Duff MO, Eipper-Mains J, Graveley BR, et al. Regulatory divergence in Drosophila revealed by mRNA-seq. Genome Research. 2010;20:816–825. [PMC free article] [PubMed]
39. Tirosh I, Reikhav S, Levy AA, Barkai N. A Yeast Hybrid Provides Insight into the Evolution of Gene Expression Regulation. Science. 2009;324:659–662. [PubMed]
40. Rosenfeld N, Elowitz MB, Alon U. Negative autoregulation speeds the response times of transcription networks. Journal of Molecular Biology. 2002;323:785–793. [PubMed]
41. Becskei A, Serrano L. Engineering stability in gene networks by autoregulation. Nature. 2000;405:590–593. [PubMed]
42. Wagner A. Robustness against mutations in genetic networks of yeast. Nature Genetics. 2000;24:355–361. [PubMed]
43. Ihmels J, Collins SR, Schuldiner M, Krogan NJ, Weissman JS. Backup without redundancy: genetic interactions reveal the cost of duplicate gene loss. Molecular Systems Biology. 2007;3 [PMC free article] [PubMed]
44. Gu Z, Steinmetz LM, Gu X, Scharfe C, Davis RW, et al. Role of duplicate genes in genetic robustness against null mutations. Nature. 2003;421:63–66. [PubMed]
45. Doniger SW, Fay JC. Frequent gain and loss of functional transcription factor binding sites. PLoS computational biology. 2007;3:e99. [PMC free article] [PubMed]
46. Ravasi T, Suzuki H, Cannistraci CV, Katayama S, Bajic VB, et al. An Atlas of Combinatorial Transcriptional Regulation in Mouse and Man. Cell. 2010;140:744–752. [PMC free article] [PubMed]
47. Chen L, Wu G, Ji H. hmChIP: a database and web server for exploring publicly available human and mouse ChIP-seq and ChIP-chip data. Bioinformatics. 2011;27:1447–1448. [PMC free article] [PubMed]
48. Schmidt D, Wilson MD, Ballester B, Schwalie PC, Brown GD, et al. Five-Vertebrate ChIP-seq Reveals the Evolutionary Dynamics of Transcription Factor Binding. Science. 2010;328:1036–1040. [PMC free article] [PubMed]
49. Muino JM, Hoogstraat M, van Ham RC, van Dijk AD. PRI-CAT: a web-tool for the analysis, storage and visualization of plant ChIP-seq experiments. Nucleic Acids Research. 2011;39:W524–527. [PMC free article] [PubMed]
50. Guelzim N, Bottani S, Bourgine P, Kepes F. Topological and causal structure of the yeast transcriptional regulatory network. Nature Genetics. 2002;31:60–63. [PubMed]
51. Cavelier G, Anastassiou D. Data-based model and parameter evaluation in dynamic transcriptional regulatory networks. Proteins-Structure Function and Bioinformatics. 2004;55:339–350. [PubMed]
52. Buchler NE, Gerland U, Hwa T. Nonlinear protein degradation and the function of genetic circuits. Proceedings of the National Academy of Sciences of the United States of America. 2005;102:9559–9564. [PMC free article] [PubMed]
53. Calzone L, Fages F, Soliman S. BIOCHAM: an environment for modeling biological systems and formalizing experimental knowledge. Bioinformatics. 2006;22:1805–1807. [PubMed]
54. Prasad TSK, Goel R, Kandasamy K, Keerthikumar S, Kumar S, et al. Human Protein Reference Database-2009 update. Nucleic Acids Research. 2009;37:D767–D772. [PMC free article] [PubMed]
55. Kawabata T, Fukuchi S, Homma K, Ota M, Araki J, et al. GTOP: a database of protein structures predicted from genome sequences. Nucleic Acids Research. 2002;30:294–298. [PMC free article] [PubMed]
56. Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ. Basic Local Alignment Search Tool. Journal of Molecular Biology. 1990;215:403–410. [PubMed]

Articles from PLoS ONE are provided here courtesy of Public Library of Science
PubReader format: click here to try

Formats:

Related citations in PubMed

See reviews...See all...

Cited by other articles in PMC

See all...

Links

Recent Activity

Your browsing activity is empty.

Activity recording is turned off.

Turn recording back on

See more...