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Genetic Redundancy Advanced article Article Contents David C Krakauer, Santa Fe Institute, Santa Fe, New Mexico, USA . The Organizational Levels of Genetic Redundancy Genetic redundancy typically relates to the duplication of an open reading frame within a genome. Genetic redundancy is often inferred when the modification or deletion of a portion of genetic material in a duplicated genome results in minimal changes in trait or organismal phenotype in reference to the nonduplicated wildtype. This invariance has been attributed to buffering mechanisms promoted by duplicates and to a number of compensatory pathways independent of the duplicate. Most duplicates are rapidly lost from genomes by mutation and drift. . Modifiers and Networks . Mechanism versus Function of Genetic Redundancy . Two Functionalist Perspectives . Mechanisms Allowing the Evolutionary Preservation of Redundancy . Incidence of Genetic Redundancy . Genetic Redundancy and its Close Conceptual Cognates . Open Questions and the Future of Redundancy Online posting date: 15th July 2008 The Organizational Levels of Genetic Redundancy Biologists frequently describe genetic redundancy, also referred to as functional redundancy, in relation to the knockout of one or more genetic transcripts. Subsequent to the elimination of a transcript, the absence of a scoreable change in phenotype, is the marker for genetic redundancy. It is assumed that a second genetic locus, or group of genetic loci, can compensate for the loss. Geneticists also speak of redundancy in the genetic code. This refers to the many to one mapping of codons to amino acids, allowing for the possibility of silent or synonymous nucleotide substitutions in a sequence. Redundancy in the genetic code is typically thought of as involving separate mechanisms to those producing redundancy at the level of the gene, and hence these concepts are kept separate. However, redundancy can also be present at levels above that of the gene. Whole sets of co-localized genes (syntenic blocks), or more frequently, whole chromosomes (polyploidy) can be redundant. In each case, the mechanisms buffering the phenotype from change are likely to be different. Modifiers and Networks In an effort to understand the underlying mechanics of redundancy, biologists have explored several working models. For all models, redundancy first emerges through a stochastic process of duplication of a locus, either by unequal crossing over, or by transcription and ribonucleic acid (RNA) splicing. By far most duplicates are rapidly silenced and lost by degenerative mutation (Lynch and Conery, 2000). The role of models of redundancy is to ELS subject area: Evolution and Diversity of Life How to cite: Krakauer, David C (July 2008) Genetic Redundancy. In: Encyclopedia of Life Sciences (ELS). John Wiley & Sons, Ltd: Chichester. DOI: 10.1002/9780470015902.a0006116.pub2 account for how redundancy can be preserved for long enough to be observed. In one set of models, genetic redundancy arises as a consequence of a secondary locus or set of secondary loci, whose role is to substitute or compensate for damage to a primary locus or loci. Frequently, this involves duplicate sets of a reading frame expressing identical proteins. In a second set of models, redundancy arises out of the network structure of genetic regulatory pathways, or metabolic circuits. In the first model, redundancy is the product of transcripts related in structure and function or through direct interactions among duplicates; we call these loci modifiers of functional redundancy. In the second model, nominally, unrelated genes interact through complex pathways to produce a stable phenotype; we call these functionally redundant networks (see Figure 1 for a toy model of network redundancy). An example of redundancy through modifiers that interact directly with damaged proteins but differ in structure and function is the role played by heat shock proteins in suppressing phenotypic variation. The heat shock protein Hsp90 is not required for the maturation or maintenance of most proteins in vivo. The targets of Hsp90 are predominantly signal transduction proteins, with which it interacts repeatedly, identifying protein structures indicative of misfolding, and stabilising the wild-type conformation. At low temperatures, or when there are no mutations to its target proteins, Hsp90 is functionally redundant. However, at high temperatures producing developmental noise, or when there is extensive polymorphism among signal transduction proteins, Hsp90 plays an essential buffering role. Homozygous mutations to Hsp90 are lethal. Rutherford and Lindquist (1998) explored three hypotheses to explain the role of Hsp90: (1) loss of Hsp90 increases susceptibility to developmental noise, (2) loss of Hsp90 increases the rate of mutation and (3) loss of Hsp90 exposes cryptic variation buffered in the wildtype. A series of cross breeding experiments established that the third, followed by the first hypotheses were most consistent with the data. Rutherford and Lindquist were able to selectively breed for defective flies, by crossing flies heterozygous for mutations to Hsp83 (a related heat shock protein) starting from a small population. It is unlikely that new mutations arose during the breeding experiment, it is more likely that formerly ENCYCLOPEDIA OF LIFE SCIENCES & 2008, John Wiley & Sons, Ltd. www.els.net 1 Genetic Redundancy A B C Figure 1 Convergent activation and nonspecific negative feedback can lead to functional redundancy in a gene regulatory network. Proteins A and B are transcription factors produced at an equal rate and capable of activating the expression of gene C. Gene A activates C at a rate ka and gene B activates C at a rate kb. Gene C can be thought to work according to three different negative feedback mechanisms: (1) encode a protein capable of inhibiting the production of A and B, (2) encode a protein inhibiting the activation of C by A and B or (3) increase the decay of A and B mRNA. In all three cases the inhibitory influence of C is given by the rate constant kc. All three proteins are degraded at an equal rate d. We are interested in the steady state concentration of C following the knockout of A in comparison with the steady state concentration of C in the wildtype (in which A and B are both present). The ratio of mutant to wild-type concentration of C assuming feedback pffiffiffiffiffipffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi mechanisms (1) and (2) is given by kb ka þ kb . If we assume that ka = kb, then the reduction in steady state concentration of C is about 30%. The steady state ratio assuming feedback mechanism (3) depends on the rate of protein decay d. When the decay rate is very small (d ! 0), then the ratio is equal to 1. In other words, the circuit is completely redundant with respect to the loss of A. When the decay rate is very fast (d ! 1) then for ka = kb, the ratio of mutant to wildtype is 0.5. For realistic rates of decay the ratio remains approximately equal to 1. This toy model shows that for a range of negative feedback mechanisms, this network structure produces a degree of functional redundancy greater than the additive contribution of individual genes. buffered mutations were masked by functioning Hsp83, and revealed in its absence. Hsp90 is highly pleiotropic and interacts with many kinds of misfolded protein. At any one time it is likely that Hsp90 will be redundant with respect to one of its targets, and will play an essential role with another. Thus, Hsp90 is a modifier of genetic redundancy that works through direct interaction with the perturbed protein. Examples of redundancy through modifiers that are similar in structure and function but do not interact directly with damaged protein, are the members of the Cyclin D/INK4/pRB/E2F signal transduction cascade and the a-actin proteins. The genetic analysis of human tumours has revealed that many of the genes damaged in cancer cells are involved in the G1/S transition of the cell cycle. Around 80% of all human cancers have damage to the Cyclin D/INK4/pRB/ E2F signal transduction cascade. for a cell to progress from G1 to S phase of the cell cycle, the retinoblastoma proteins (pRB) must be inactivated (phosphorylated) by the D-type cyclin-dependent kinases: Cdk4 and Cdk6. In Drosophila and in mice ablation of the Cdk4 locus results in a minimal change in phenotype, even though the cyclin-dependent kinases play an essential role in cell cycle (Ortega et al., 2002). It is suggested that Cdk6 can compensate for the loss of Cdk4. Similar functional redundancy is observed upon selective mutation to the INK4 cell cycle inhibitors (ink4a,b,c,d), and the D-type cyclins (D1, D2 and D3). Thus, each component of the pathway demonstrates a degree of functional redundancy that arises through a shared structure and function. 2 The a-actins are actin-binding proteins forming a major structural component of the Z-lines in myofilaments. Early studies implicated the loss of ACTN3 (a-actinin-3) in muscular dystrophy, and other dystrophic, myopathic and neurogenic pathologies. Subsequent testing revealed that normal individuals very often shared the defective genotype, homozygous for a nonsense mutation to ACTN3. The data suggest that ACTN3 is functionally redundant in humans and its loss is compensated for by the closely related ACTN2 (North et al., 1999). An example of network redundancy, as opposed to modifer redundancy, is the negative regulation of RTK signalling by Src42A in Drosophila (Lu and Li, 1999). The receptor tyrosine kinases (RTK) respond to extracellular stimulation from a large number of different ligands, and transmit information about these ligands, into cells through autophosphorylation of tyrosine residues contained in their tails. These phosphotyrosine residues are then bounded by SH2 domains of Grb2 adaptor proteins. This leads to the activation of Sos, which in turn catalyses the formation of Ras-GTP (guanosine triphosphate) which binds to RAF initiating three protein kinase phosphorylation cascades. In parallel, the RTK recruit another set of SH2 domain proteins: members of the Src family of non-RTK. Extensive knockout experiments have revealed that many of these Src proteins (including Src42A) are functionally redundant. Lu and Li (1999) have found that the role of Src42A is to repress RTK signalling and function in a Ras-independent manner. The logic of the parallel pathway and the nature of Src42A redundancy are thought to operate as follows. Upon stimulation of RTK, with say growth factors, the primary stream of excitatory or activating signal transduction flows from Sos to RAF to mitogen activated protein kinase (MAPK). In parallel an inhibitory signal flows through the Src42A pathway. Under normal conditions, the influence of this inhibitory pathway is not felt, such that mutations to Src42A and stimulation of the RTK lead to a wild-type response. However, when the Ras/Mapk cascade is compromised, the removal of Src42A has severe phenotypic consequences. The Src42A is redundant in the wildtype but plays an important inhibitory role in the mutant. Redundancy is not achieved by backing up members of the Ras/Mapk cascade (as in the actin and cyclin examples) or through direct interactions among proteins (as in the heat shock example), but through properties of the parallel network structure. The inhibitory Src42A pathway acts as a sensitive indicator and suppressor of perturbations to the Ras/Mapk pathway. The many connections in the Ras/Mapk pathway make it particularly vulnerable to mutation and developmental noise. The high frequency of potential damage should be sufficient to maintain the redundant network. Mechanism versus Function of Genetic Redundancy When biologists ask why a given trait is genetically redundant, there are two possible interpretations to this ENCYCLOPEDIA OF LIFE SCIENCES & 2008, John Wiley & Sons, Ltd. www.els.net Genetic Redundancy question. The first question relates to the underlying mechanisms that buffer the effects of genetic modification (modifiers versus networks). The second question relates to the evolutionary origins and functions of those mechanisms promoting genetic redundancy. In other words, how does a given mechanism preserve the wild-type phenotype (mechanism), and what selective advantage is there for mechanisms that preserve the wild-type phenotype and how might they evolve (function). Studies on genetic redundancy can be classified according to which of these two approaches is adopted. In the previous section mechanistic studies were emphasized. A good example of the functional study of redundancy are Wagner’s 2000a, 2000b and Gu et al. (2003) statistical analyses of the relationship between sequence identity, gene expression pattern and phenotypic effects in yeast. In the first study, Wagner sought to determine whether redundancy is best explained by assuming that functional redundancy arises through the presence of multiple closely related genes (modifier model) that can compensate for one another, or whether alternatively, redundancy is better thought of as a network property of the genome involving multiple unrelated genes (network model). The analysis has three components. In the first, it was determined whether there was a positive correlation between the fitness effects of mutations to single genes within one of the six duplicated blocks on chromosome V, and sequence similarity to the 44 alternative duplicated genes within the blocks. In the second, sequence similarity among genes outside the duplicated blocks was correlated with fitness effects. And in the third, all genes in the study were categorized according to whether mutation leads to undetectable fitness effects, or severe fitness reductions. It was established how far these two groups of genes differed in mean similarity to other genes in the genome, and in similarity in gene expression pattern to other genes of the genome. In none of the three cases was there a significant association between the genetic similarity among genes, the expression profiles among genes and their ability to buffer the effects of mutation. The study concludes by suggesting that redundancy is most likely to have evolved as a network property of genetic circuits, rather than through duplication of existing genes. However, in the subsequent study by Gu et al., which was conducted with a larger sample of 1147 genetic loci, the results were the opposite from those of Wagner, and genetic similarity proved to be a strong predictor of robustness. These studies illustrate the heterogeneous nature of the underlying robustness mechanisms, and the requirement for large sample sizes in redundancy studies. Two Functionalist Perspectives There are at least two perspectives on the evolution of redundancy. Some hypothesize that redundancy is only apparent, and reflects ‘genetic uncertainty’ arising from detection constraints in artificial laboratory populations (Tautz, 1992, 2000). Population genetics tells us that a gene’s selective value need only exceed the reciprocal of population size to become fixed (Kimura, 1983). In other words, for a gene to become ubiquitous, it needs to have a better than random probability of surviving from one generation to the next. This suggests that the selective value of a gene expressed in an organism evolving in a very large population, can be very small and yet remain functional and nonredundant. Experimental or technological limitations in detection could feasibly be below than that achievable by natural selection and give rise to ‘effective redundancy’. Moreover, to obtain statistical significance for differences in phenotype following knockout even when they are detectable, the laboratory populations might have to approach the size of natural populations. Thus, ‘effective redundancy’ arises through weak selection in large populations. The alternative perspective is to accept that undetectable changes in phenotype or fitness are the result of true redundancy in redundancy promoting modifiers, and/or network properties of the genomic system that have been selected. The lack of a scoreable phenotype is not the result of very subtle changes in phenotype, but the outcome of effective mechanisms for buffering perturbations. In this case, the detection of redundancy does not require very large populations but the correct choice of perturbation. Consider the example of Hsp90. Mutations to the signal transduction proteins are very subtle, suggestive of redundant functions. In a suitably sensitive experiment, these subtle differences might have been detected. It would have been concluded that the redundancy was only apparent. However, the knockout of Hsp90 reveals that the redundancy is not in the signal transduction genes, but in the Hsp90 modifier of redundancy. This modifier, unlike the proteins with which it interacts, is likely to come under rather strong selection, as it interacts with a broad class of proteins. Further important evolutionary questions include whether redundancy has come under direct selection for its error-buffering benefit, or whether redundancy is expected to arise and persist as a side effect (epiphenomenon) of constraints and mutational processes acting within genetic sequences, protein structures or genetic circuits. Some degree of pleiotropy, arising through unanticipated overlap in protein structure (in a transcription factor or a receptor) or in genetic sequence (in a promoter or transfer RNA, tRNA) might lead to epiphenomenal redundancy. There is also the question of redundancy in hierarchically organized systems. Organisms are multilevelled, comprising genes, cells, tissues and organ systems. When we speak of mechanisms of redundancy they are likely to differ at each of these levels. Krakauer and Plotkin (2002) have shown using evolutionary models that often redundancy at a more inclusive level is achieved though it is inverse at a lower level. Thus, tissues can remain robust against mutations by eliminating defective cells. If the population of cells is sufficiently large, such a strategy is highly effective, as it prevents defective cell lineages from fixing within the tissue. This amplification of damage at more populous levels of organization has been called antiredundancy. ENCYCLOPEDIA OF LIFE SCIENCES & 2008, John Wiley & Sons, Ltd. www.els.net 3 Genetic Redundancy Mechanisms Allowing the Evolutionary Preservation of Redundancy Once a degree of redundancy has arisen and is detectable, there remains the problem of how it is maintained. This is a problem because random inactivation of one or more genes contributing to an overlapping function, will by definition, have minimal phenotypic effects. Selection does not act directly on the redundant function, but against those without it (Wagner, 2000a, 2000b). This implies that selection for redundancy is indirect and consequently rather weak. If a redundant gene is truly redundant, selection will be unable to prevent it from accumulating disabling mutations. In other words ‘Use it or Lose it!’. The difficulty of preserving redundant functions makes the epiphenomal view questionable. Different mechanisms for preserving redundancy have been hypothesized (Krakauer and Nowak, 1999). These include a cumulative benefit from multiple identical genes (doseage effects), robustness through overlapping functions subject to high rates of error (error buffering), genes that are pleiotropic with respect to an overlapping function and maintained by stabilising selection on their unique functions; shared theories and by temporal and spatial subfunctionalization. (1) Cumulative benefit theories: When increasing the quantity of a gene product increases fitness, genetic redundancy is only apparent, and reflects the genetic uncertainty of the laboratory (Thomas, 1993). All eukaryotic cells contain multiple copies of the mitochondrial genome, promoting efficient metabolism, and multiple copies of tRNA and messenger RNA (mRNA) genes for rapid translation. Eliminating copies reduces organismal fitness in large populations, hence redundancy is maintained by weak stabilizing selection acting on an ensemble of more or less identical transcripts. (2) Mutational error-buffering theories: Genetic error buffering is defined as any mechanism that reduces mutational load. Assuming that there are two identical genes contributing to a shared function with different mutation rates, the gene with the higher mutation rate will be lost from the population in due course. If mutation rates are equal, one of two genes will eventually become silenced by random drift. By allowing an asymmetry in how well each gene performs a shared function, then redundancy can be maintained whenever the more able gene has the higher rate of effective mutation (Nowak et al., 1997). This does not require that one gene mutate more frequently, but that the protein product of the more able gene is more sensitive to mutation. (3) Developmental error-buffering theories: Developmental error buffering is defined as any mechanism that reduces the deleterious effects of nonheritable perturbations of the phenotype during ontogeny. Developmental noise selects for genetic redundancy by increasing the effective 4 number genes damaged during a life time. Individuals carrying multiple redundant copies of a gene will be less compromised by the deleterious effects of noise than individuals carrying a single copy of a gene. (4) Pleiotropic theories: Pleiotropy describes instances where a single gene experiences selection in more than one context. Consider two genes with two independent specialist functions. Further assume that one of these genes can in addition to its own specialist function, perform as a generalist, the function of the other gene but less efficiently. Some mutations to the pleiotropic gene will eliminate its specialist function and others will eliminate its generalist function. Redundancy will be maintained whenever the rate of elimination of the generalist function is lower than the rate of elimination of the two specialist functions (Nowak et al., 1997). Once again the rate of elimination need not involve differences in rates of mutation but in rates of phenotypic change. In small populations pleiotropy has a very considerable influence on the preservation of partially redundant genes (Wagner, 2000a, 2000b). (5) Genetic regulatory element theories: There is redundancy not only among coding regions, but also among regulatory elements associated with structural genes. Indeed, redundancy is more prevalent in regulatory genes than structural genes. In part this can be the result of differences in specificity. During a duplication event structural genes and regulatory elements may be duplicated. In some cases each structural gene shares the same regulatory genes with its paralogue, and in other cases, the paralogous genes might acquire different regulatory genes from the initial set (Averof and Akam, 1995). In such a scenario there are two sources of redundancy. Redundancy in both the regulatory gene and structural gene, as both copies of the structural gene possess the same set of regulatory genes. And redundancy in the structural gene, as each structural gene can be accompanied by a different regulatory gene. Partial redundancy can be maintained in both cases if the regulatory genes respond to different spatio-temporal stimuli. Furthermore, redundancy in regulatory genes might persist for longer as a consequence of their small mutation target size. This process has been explored in some detail as a model of subfunction fission (Force et al., 1999). (6) Subfunctions and complementary degenerative mutation. The imperfect duplication of a genetic locus might prove to be essential to its maintenance. If we start with a transcript encoding a protein with multiple, modular subfunctions, and each copy degenerates a different subfunction upon duplication, then selection maintains two-loci where formally it required only a single locus (Force et al., 1999). Incidence of Genetic Redundancy The taxonomic incidence of genetic redundancy reflects a double sampling bias: firstly, genetic redundancy is best ENCYCLOPEDIA OF LIFE SCIENCES & 2008, John Wiley & Sons, Ltd. www.els.net Genetic Redundancy documented in those organisms favoured by experimental researchers in molecular genetics: Drosophila, Xenopus, mouse, Caenorhabditis elegans, Arabidopsis and Saccharomyces cerevisiae. Secondly, redundancy tends to be reported in studies involving development. This has led to a situation in which genetic redundancy has a patchy taxonomic distribution concentrated largely in developmental genes. This makes it difficult to identify true phylogenetic patterns in the incidence of genetic redundancy and to determine the sorts of biological function most likely to require genetic redundancy. Even with these constraints genetic redundancy has been reported in a very diverse group of genes including transcription factors, transcription enhancers, protein kinases, cytokines, cell adhesion proteins, receptors, growth factors, trafficking proteins, chaperones, neuropeptides, oncoproteins and promoters (see Table 1 for a few examples). It has been observed – subject to the inadequacy of the data – that redundancy is more common in regulatory genes than in structural genes. The explanation provided for this asymmetry is that regulatory genes tend to interact with a larger number of other genes than structural genes. This might suggest that, on average, more than one regulatory gene interacts with the same target (Cooke et al., 1997). Thus, pleiotropic interactions are more common among regulatory genes and this allows for greater redundancy. Table 1 A table of genes for which one or more duplicates exist classified according to primary gene function and species of provenance Gene function Examples Organisms Transcription factor Egr-1 SPT10 Hox genes Sgs-4 CD4 silencer TATA box HTF9 ILR TCR RAR MTMR2 Mouse S. cerevisiae Mouse D. melanogaster Transcription regulator Promoter Receptor Protein phosphatase Protein kinase Cytokine Cell cycle gene Enzyme Cell adhesion gene Genetic Redundancy and its Close Conceptual Cognates Genetic redundancy is closely related to the ideas of canalization neutrality and neutral networks. The principle of canalization was introduced by Waddington (1942) as a phenomenological means of explaining the constancy of tissues and organ types during development. Canalization refers to those mechanisms that have evolved to suppress phenotypic variation during development and thereby reduce the cumulative cost of deviations from a locally optimal trajectory (Gibson and Wagner, 2000). Waddington thought of deviations as the result of mutations or environmental insults. They are also likely to arise from the cascade of nonsynchronous network activities following cell stimulation. Genetic redundancy provides one set of mechanisms that could produce canalization of the phenotype, checkpoints in the cell cycle, another. The principle of neutrality is best known to biologists in relation to the selective neutrality of alleles in populations. The neutral theory (Kimura, 1983) rose to prominence as a means of explaining the higher than expected level of variation in electrophoretic data (Lewontin, 1974–1975). Neutrality refers to the selective equivalence of different phenotypes. The idea does not require that mutations to a wild-type sequence leave the phenotype unchanged (although phenotypic neutrality is possible), but that the phenotypic differences are beyond the detection limit for selection. Apoptotic gene Growth factor Chaperone Oncogene Cell structure gene Cell trafficking gene Vesicle fusion gene tRNA rRNA Cyclin-D Wee1, Mik1 Src-family IL15 IFN-gamma Cyclin A/B Cathepsin S Acetyltransferase Cysteine proteinase Desmoplakin Pecam-1 Bcl-2 Bcl-xl IGFBP-2 CAF1 Human Mouse C. elegans Mouse Mouse Mouse Mouse S. cerevisiae S. cerevisiae Human Mouse D. melanogaster Mouse Mouse Leishmania mexicana Mouse Mouse Mouse E1A ACTN2, ACTN3 Sec24p Mouse Dictyostelium discoideum Adenovirus Human S. cerevisiae DNSF1, DNSF2 D. melanogaster S. cerevisiae D. melanogaster Neutrality, unlike canalization, is not assumed to be an adaptive means of suppressing variability. Nor is neutrality concerned with the development of phenotypes. Neutrality is simply a measure of the selective equivalence of phenotypes, and is primarily concerned with finite population effects. Canalization through genetic redundancy or checkpoint mechanisms can produce neutrality. More recently, interest has turned to the discussion of neutral networks (Fontana and Shuster, 1998; Huynen et al., 1996). These networks are sets of selectively or structurally equivalent genotypes, connected via single mutational steps. Neutral networks span large volumes of genotype space and provide a natural buffering mechanism. As a result of mutation, sequences randomly walk through sequence space ENCYCLOPEDIA OF LIFE SCIENCES & 2008, John Wiley & Sons, Ltd. www.els.net 5 Genetic Redundancy and provide potential variation for evolutionary change. Work on neutral networks highlights the restrictions that genetic redundancy can place on evolvability by limiting phenotypic variance. Open Questions and the Future of Redundancy 1. As more knockout studies have been conducted, facilitated by increasingly efficient quantitative assays like high-throughput genetic interaction maps (see Ihmels et al., 2007), the data seem to become more ambiguous rather than more clear. The data suggest that selection for robustness can only account directly for some small percentage of duplicate loci (around 25%). Furthermore, duplicates rarely preserve the identical networks of interaction partners as their singleton ancestors, suggesting that even when transcripts are conserved their distributed functions need not be. Does this suggest that sequence similarity and functional role can be decoupled? 2. Theoretical models suggest that selection for phenotypic robustness against nonheritable errors in development, impose a stronger selection pressure than robustness to heritable mutations (de Visser et al., 2003) and it could be that these more diverse, phenotypic sources of noise are favouring redundancy. Perhaps, we should be looking to cellular stochasticity as an important factor preserving genetic redundancy. 3. Over the next few years, as molecular biology and genetics establish more efficient functional assays, and move away from an emphasis on sequence analysis, more nuanced positions on both redundancy and robustness are likely to emerge. It is likely that there will be a shift away from single locus redundancy to the redundancy of comparable network structures, whose single components might or might not be conserved. This raises questions about how we go about studying redundancy when we do not know which level we should be analysing. References Averof M and Akam M (1995) Hox genes and the diversification of insect and crustacean body plans. Nature 376(6539): 420– 423. 3 August. Cooke J, Nowak MA, Boerlijst M and Maynard-Smith J (1997) Evolutionary origins and maintenance of redundant gene expression during metazoan development. Trends in Genetics 13(9): 360–364. September. Fontana W and Schuster P (1998) Continuity in evolution: on the nature of transitions. Science 280(5368): 1451–1455. 29 May. Force A, Lynch M, Pickett FB et al. (1999) Preservation of duplicate genes by complementary, degenerative mutations. Genetics 151: 1531–1545. 6 Gibson G and Wagner G (2000) Canalization in evolutionary genetics: a stabilizing theory? BioEssays 22(4): 372–380. April. Gu Z, Steinmetz LM, Gu X et al. (2003) Role of duplicate genes in genetic robustness against null mutations. Nature 418: 387–391. Huynen MA, Stadler PF and Fontana W (1996) Smoothness within ruggedness: the role of neutrality in adaptation. Proceedings of the National Academy of Sciences of the USA 93(1): 397–401. 9 January. Ihmels J, Collins SR, Schuldiner M, Krogan NJ and Weissman JS (2007) Backup without redundancy: genetic interactions reveal the cost of duplicate gene loss. Molecular System Biology 3: 86. Kimura M (1983) The Neutral Theory of Molecular Evolution. Cambridge: Cambridge University Press. Krakauer DC and Nowak MA (1999) Evolutionary preservation of redundant duplicated genes. Seminars in Cell and Developmental Biology 10(5): 555–559. October. Krakauer DC and Plotkin JB (2002) Redundancy, antiredundancy, and the robustness of genomes. Proceedings of the National Academy of Sciences of the USA 99(3): 1405–1409. 5 February. Lewontin RC (1974–1975) The problem of genetic diversity. Harvey Lectures 70: Series: 1–Series: 20. Lu X and Li Y (1999) Related articles, nucleotide, protein Drosophila Src42A is a negative regulator of RTK signaling. Developmental Biology 208(1): 233–243. 1 April. Lynch M and Connery JS (2000) The evolutionary fate and consequences of duplicate genes. Science 290: 1151–1155. North KN, Yang N, Wattanasirichaigoon D et al. (1999) A common nonsense mutation results in alpha-actinin-3 deficiency in the general population. Nature Genetics 21(4): 353–354. April. Nowak MA, Boerlijst MC, Cooke J and Smith JM (1997) Evolution of genetic redundancy. Nature 388(6638): 167–171. 10 July. Ortega S, Malumbres M and Barbacid M (2002) Cyclin D-dependent kinases, INK4 inhibitors and cancer. Biochimica et Biophysica Acta 1602(1): 73–87. 14 March. Rutherford SL and Lindquist S (1998) Hsp90 as a capacitor for morphological evolution. Nature 396(6709): 336–342. 26 November. Tautz D (1992) Redundancies, development and the flow of information. BioEssays 14(4): 263–266. April. Tautz D (2000) A genetic uncertainty problem. Trends in Genetics 16(11): 475–477. Review. Nov. Thomas JH (1993) Thinking about genetic redundancy. Trends in Genetics 9(11): 395–399. Review. November. de Visser JGM, Hermisson J, Wagner GP et al. (2003) Perspective: evolution and detection of genetic robustness. Evolution 57: 1959–1972. Waddington CH (1942) Canalization of development and the inheritance of acquired characters. Nature 150: 563–565. Wagner A (2000a) The role of population size, pleiotropy and fitness effects of mutations in the evolution of overlapping gene functions. Genetics 154(3): 1389–1401. March. Wagner A (2000b) Robustness against mutations in genetic networks of yeast. Nature Genetics 24(4): 355–361. April. Further Reading Ihmels J, Collins SR, Schuldiner M, Krogan NJ and Weissman JS (2007) Backup without redundancy: genetic interactions reveal the cost of duplicated genes. Molecular System Biology 3: 1–11. ENCYCLOPEDIA OF LIFE SCIENCES & 2008, John Wiley & Sons, Ltd. www.els.net