A General Framework of Persistence Strategies for Biological Systems Helps Explain Domains of Life

Scope sizes and matter-energy budgets of organisms

Scope size measures how much of the external environment the individual can scan, or how many external signals it can potentially be exposed to. This exposure grows with the individual’s size, spatial range due to motility, and life span. The plots in Figure ​Figure22 recapitulate the known positive relationship between these variables (Harestad and Bunnell, 1979; Jenkins, 1981; Garland, 1983; McMahon and Bonner, 1983; Reich, 2001; Hedenstrom, 2003; Speakman, 2005). Based on these data and the factors contributing to budget, we arranged the six kingdoms in order of increasing scope size and budget (Figure ​(Figure3,3, left panel). Motility and nutrition appear to be the defining factors in this distribution.

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Figure 2

The tendencies for scope size evolution in the six kingdoms. In our theory, linear size and spatial range of individuals model spatial scope size. Life span models temporal scope size. By plotting these variables one against another, we demonstrate the differences in scope sizes among organismal kingdoms. Blue dots mark akarya, black dots – Protista, magenta dots – Fungi, green dots – Plants, and black stars – Metazoa. Vertical and horizontal lines indicate known ranges, not standard errors (see Datasheet S1 in Supplementary Material). Each datapoint displays measurements characteristic to individuals of a species, except for fungal data, which emphasize the spatio-temporal ranges of hyphae and mycelia (see text for explanation). It is notoriously difficult to measure the linear size and spatial range of individuals for some kingdoms, and their horizontal location on the graph should be taken with a grain of salt (see Text and Methods in Datasheet S4 in Supplementary Material). (A) This graph emphasizes the different strategies of spatial scope size evolution between Metazoa and Fungi/Plants. Sessile Plants and Fungi can grow to very large sizes (up to the largest known fungal genet of Armillaria ostoyae); while Metazoa achieve great motility speeds (man is the fastest). Thiovulum majus on top of the akaryal bar marks the fastest known bacterial species. (B) This graph demonstrates the different emphases in evolution of temporal and spatial scope size between Metazoa and Fungi/Plants. The kingdoms of Plants and Fungi evolve individuals with very long life spans (up to the longest-living known plant genet of Populus tremuloides), while Metazoa evolve individuals with very broad spatial ranges (man travels the farthest). Together parts (A,B) of this figure show the differences in tendencies for scope size evolution between Metazoa and Plants/Fungi: the former evolve wider spatial scope, while the latter evolve wider temporal scope, relative to one another. See Datasheet S4 in Supplementary Material for Methods.

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Figure 3

Organisms with a particular propensity toward greater economy, flexibility or robustness tend to segregate based on the sizes of matter-energy and information fluxes they process. The left panel of this cartoon shows that organisms segregate along the budgetary axis in the order of Archaea-Bacteria < Protista < Plants-Fungi < Metazoa. Once we add the information flux axis on the right panel, this segregation transforms into a triangle that resolves Archaea from Bacteria and Plants from Fungi based on their propensity toward robustness and flexibility. The very elongated Metazoan cloud arises from their trademark tendency to evolve lifestyles of traversing environmental gradients at high speeds. The resultant large and dense scope, coupled with principally predatory nutrition, requires that Metazoa process large information fluxes (have large umwelt). The size of umwelt progressively increases for the more evolved Metazoa, culminating in Man, who expands his own sensory and processing capabilities through manufacture, including production of sensors and computers.

The microbes of kingdoms Bacteria and Archaea, which we here denote collectively as “Akarya,” are the smallest and slowest organisms among the six kingdoms. Motility is costly, inefficient, and simply not very useful at their spatial scale (Berg and Purcell, 1977; Purcell, 1977), due to the substantial viscous drag (Berg, 1993) and susceptibility to the disorienting rotational diffusion caused by the Brownian motion (Berg, 1993). The minuscule cell sizes and speeds (Figure ​(Figure2A)2A) result in equally minuscule characteristic spatial scope and lifespan (Figure ​(Figure3,3, left, bottom of the axis). Protista include a wide range of organisms, some as small as akaryal microbes (e.g., Ostreococcus) and sessile, others orders of magnitude bigger and farther ranging than the biggest and fastest akarya (Datasheet S1 in Supplementary Material). Protista are better swimmers than Akarya, because their size makes them more resistant to Brownian disorientation. Their speeds (Datasheet S1 in Supplementary Material) are sufficiently high to attain Reynold’s numbers of ∼1, balancing the contributions of viscosity and inertia (Purcell, 1977). However, viscous drag also increases with cell size, making motility more expensive for Protista than for Akarya (Crawford, 1992). Consequently, protists have higher cell-specific (Glazier, 2009; Johnson et al., 2009), and mass-specific (Makarieva et al., 2008) metabolic rate compared to akaryotic microbes, encouraging bigger budget. Thus, Protista overlap with Akarya in terms of scope size, but extend far beyond them into the areas of bigger budget (Figure ​(Figure3,3, left).

A multicellular organism’s budget by definition includes, and is greater than, the individual budget of each unicell comprising it. Multicellular kingdoms are very diverse, and overlap with unicells in terms of scope size. For example, the multicellular Volvox colonies are ∼500 μm in diameter (Sharma, 2002), whereas the bacterium Thiomargarita namibiensis is ∼100–750 μm (Schulz and Jorgensen, 2001). Yet the extent of this overlap is negligible compared to the maximum scope size achievable by fungi, plants, and animals. The largest and longest-living organisms have evolved within Plants and Fungi (Figure ​(Figure2).2). However, overall they tend to have smaller budgets than Metazoa. First, they are sessile, which means they do not incur the high metabolic costs of motility characteristic of the highly mobile and far-ranging Metazoa (Datasheet S1 in Supplementary Material). Second, vacuoles can occupy up to 80% of cell volume in Plants and Fungi, yet they comprise a very small fraction of a cell’s metabolic budget (Miller, 1938; Klionsky et al., 1990; Veses et al., 2008), further reducing the metabolic costs. Third, Plants and Fungi adopt extended shapes of thin flat sheets and long filaments, which accommodate their absorptive mode of nutrient consumption (as opposed to the metazoan engulfment). This means they can span the same space and have the same surface area but less mass, compared to animals. Smaller mass concurrently results in smaller metabolic cost for the same body exposure to the elements, and therefore smaller budget. Additionally, the absorptive consumption creates the problem of local nutrient depletion in the environment immediately adjacent to a hypha or a root, which can limit the rate of matter-energy influx down to the rate of diffusion. Finally, the nutrients consumed by Plants and Fungi do not tend to yield as much matter-energy as those consumed by Metazoa. Fungi lead saprotrophic lifestyles, spending significant time within oxygen-poor substrates. These organisms make extensive use of fermentation, which is considerably less efficient than aerobic respiration characteristic of Metazoa (White, 2000). Plant photosynthesis is efficient compared to fermentation and aerobic respiration (Allen et al., 2011), but has a low yield per nutrient particle. Productivity is higher, the greater the influx of photons. Indeed, the incident number of light particles per unit area of an individual can be much higher compared to glucose, due to its molecular size and environmental distribution. However, this does not significantly improve nutrient availability for plants. First, only a fraction of total spectrum of solar radiation is photosynthetically active. Second, illuminance is subject to considerable variation annually (Papaioannou et al., 1993; Byun and Cho, 2006), diurnally (Wang et al., 2005), and due to cloudiness and overshadowing by objects (Young and Smith, 1983). Thus, while plants regularly receive some light every day, the exact amount can be highly variable, from fairly little (e.g., in forest understory) to saturation. The matter-energy flux achievable by plants is also constrained by the fact that their various nutrients are not co-localized: light and CO₂ must be obtained from above ground, but water and minerals from below ground. Combining all these factors together, we placed the kingdoms of Plants and Fungi in the budgetary stratum between Protista and Metazoa (Figure ​(Figure3,3, left).

Metazoan nutrition consists, with very rare exceptions (Pierce et al., 1996; Danovaro et al., 2010), exclusively of other organisms, be they live (predation, grazing), or dead (saprotrophy). Predation provides the greatest matter-energy yield using the known biochemical pathways. First, large amounts of energy can be extracted efficiently using aerobic respiration on organic material (White, 2000). Second, organic substances can simultaneously serve as sources of carbon and energy. Finally, Metazoa engulf food in large quantities, sometimes much bigger than their own body (e.g., boa constrictors, Owen, 1866). Consequently, Metazoa tend to process large fluxes of matter-energy, as evidenced by their nutrition alone. Many other factors associated with predatory lifestyle increase budgets of Metazoa far beyond those of other kingdoms. Speed and endurance (useful for both predators and prey) are determined by muscle performance, which is temperature-dependent. Homeothermy quite possibly evolved to provide the thermal conditions necessary for better muscle performance (Bennett, 1985; Carrier, 1987), but is maintained at high metabolic cost (Bennett and Ruben, 1979; Robinson et al., 1983). In addition to elevated temperature, increased running speed requires elevated oxygen consumption (McMahon and Bonner, 1983). Greater mass in mammals permits larger mitochondrial and capillary volumes, which improves oxygen supply to locomotory musculature (McMahon and Bonner, 1983; Weibel et al., 2004), at the cost of higher metabolic rate. Finally, the skeleton is essential for maintenance of high motility speeds, as it provides attachment points for muscles, stores elastic energy, transmits forces from the limbs, and helps ventilate lungs (Koob and Long, 2000). The stress imposed by motile activities upon the skeleton results in structural costs. This stress is reflected even in the chemical composition of the skeleton, which in vertebrates evolved to be dominated by calcium phosphate (instead of calcium carbonate used by the rest of Metazoa) to withstand dissolution due to systemic acidosis caused by intense muscular activity (Ruben and Bennet, 1987).

We can represent kingdoms in a cartoon form as clouds of different lineages that comprise them, aligned in order of increasing budget (Figure ​(Figure3,3, left). In this representation, the kingdoms form overlapping strata along the budgetary axis, supported by the data on metabolic rate, structural costs, spatial scope size, and lifespan. Some kingdoms remain unresolved within their strata, such that they appear in the following order: Archaea-Bacteria < Protista < Fungi-Plants < Metazoa.

Patterns of flexibility

Short of enumerating all the flexibility mechanisms, it would be difficult to prove that one organism is more flexible than another. However, we defined relative flexibility by the number of signals an organism can use to exploit, avoid or adapt to an environmental change. Thus, we can make a reasonable case by integrating the comparisons of scope content characteristic of organisms in each kingdom, with the most obvious features of flexibility. We illustrate this in Figure ​Figure33 (right panel) by adding the information processing dimension to the budgetary axis.

Akarya clearly have the smallest scope size. Most environmental signals vary at spatio-temporal scales significantly greater than that of the Akarya and thus appear constant through their scope window. Social and nutritive chemical signals are an important exception: akarya can detect binding of a single molecule, and alter their behavior numerous times throughout the life depending on the chemical signals they receive. The most obvious difference between bacterial and archaeal scope content seems to lie in their nutrition. Archaea prefer energy-stressed environments (Valentine, 2007), where matter-energy yield of nutrients is low and growth is slow. Bacteria are present in almost all niches where Archaea are present, but not the other way around. Many bacterial species are exposed to and subsist on substantially more nutritious elements (White, 2000). They likely process greater fluxes of matter-energy and have bigger budgets than Archaea. This is illustrated in Figure ​Figure33 (right) by contracting the Archaeal cloud and stretching the Bacterial cloud along the budgetary axis. In addition, the stressed environments favored by Archaea tend to be fairly stable, such as when stagnant sediments become anoxic, or when still ponds evaporate. Archaea tend to be largely absent from the more variable environments (we describe the examples and argue this point in detail in Datasheet S2 in Supplementary Material). Thus, Archaea appear to have sparser scope and are exposed to fewer signals and less information than Bacteria. Consequently, they are likely to evolve fewer flexibility mechanisms than Bacteria. In contrast, many bacteria are mixotrophic, able to switch between nutrients depending on their availability in the environment (Oren, 2006). These Bacteria are flexible with respect to nutrient kinds and availability. For example, Rhodopseudomonas palustris can use thiosulfate, hydrogen gas, sulfur compounds, and possibly CO and formate as electron donors in respiration (Larimer et al., 2004). Rhodopseudomonas sp. can use lactate, lamate, butyrate, or acetate as sources of carbon (Barbosa et al., 2001). Allochromatium vinosum is able to use hydrogen, sulfide, thiosulfate, sulfur, and sulfite as electron donors, and formate, propionate, furamate, succinate, malate, and glyconate as sources of carbon (Kumar et al., 2008). These Bacteria must process the information associated with the changing nutrient content of the environment. We found no examples of such metabolic flexibility (and metabolic information processing) among archaeons. Table ​Table22 gives examples of archaeal and bacterial species for each strictotrophic and a number of mixotrophic categories. It demonstrates the greater metabolic diversity of the bacterial kingdom as a whole, compared to Archaea. This was illustrated in Figure ​Figure33 (right) by rotating and stretching the bacterial cloud further along the information flux axis, compared to the archaeal cloud. Thus, we separated Bacteria and Archaea within their budgetary stratum.

Protista are substantially more flexible than Akarya. In addition to manipulating chemical stimuli, they can process gradients of light, while Akarya can only tell light from dark (Sackett et al., 1997). Metabolic flexibility in Protista is limited to photoorganotrophy. However, they make up for it with other diverse behaviors. Complex, coordinated ciliary, and flagellar beating, modulated by a number of chemical and light stimuli, yields steered locomotion (Jahn and Votta, 1972; Laybourn-Parry, 1984). Many protists, both free-living and parasitic, have complex lifecycles, where each step has its own scope, and the transitions between them can be regulated by a number of environmental signals (e.g., in Plasmodium, Dictyostellium, Trypanosoma, and diatoms). We illustrate Protista as a cloud that overlaps with Akarya but stretches noticeably along the information flux axis (Figure ​(Figure3,3, right).

Separating fungi from plants was complicated, as their environmental niches largely overlap. However, we noticed that these niches appeared different through the scope window of the organisms themselves. Specifically, scope density is greater for Fungi than Plants due to the nature of their nutrient sources. Plants use light – a periodically available nutrient. If a plant can survive through the night, nutrients will be available again in the morning. Fungi are saprotrophs and generally consume dead organic matter, which can be in fairly steady supply under dense vegetation due to regular shedding of leaves. Outside of that, dead organisms are not renewable sources of nutrients. The food for Fungi is therefore more ephemeral than food for plants, and therefore it contributes more information to the fungal scope window (Boddy, 1999). Soil fungi constantly explore their environment by degrading starved hyphae and moving the material into those that are actively growing. Thereby the mycelium essentially relocates away from unproductive habitats (Bessey, 1950; Alexopoulos and Mims, 1979; Pollack et al., 2008). This is a complex behavior driven by a number of signals from soil and within the hyphae. It is evidence of flexibility. Plant roots also move through the soil in search of better substrate. However, “whole organism relocation” does not seem to be their innate feature. We illustrate these differences by stretching the fungal cloud along the information flux axis, similar to the case of Archaea-Bacteria separation (Figure ​(Figure3,3, right).

Metazoa as a kingdom have the widest spatial dimension of scope, which for some species encompasses spatial variations on a tremendous scale. Traversing environmental gradients, frequently at high speeds (Figure ​(Figure2)2) is the trademark of metazoan lifestyle, which endows them with rich, dense scope content. They shuttle through steep thermal and chemical gradients across the landscapes of oceanic and continental vents, sometimes invading areas dangerously close to their thermal death point (Brues, 1927; Mason, 1939; VanDover et al., 2002; Kelley et al., 2005; Tarasov et al., 2005). They traverse wide ranges of thermal, aerobic, and pressure gradients during diving and vertical migration in the ocean (Carey and Scharold, 1990; Takami et al., 1997; Hooker and Baird, 1999; Smith and Brown, 2002; Pearre, 2003; Rex et al., 2006; Jamieson et al., 2009). They process much of this information using sophisticated multicellular sensory organs. Organisms throughout almost the entire Metazoan clade process visual, tactile, auditory, chemical, olfactory, and gravitational signals (Dusenbery, 1992). Clearly, the diversity among metazoan species is tremendous. Most will agree that earthworms probably process fewer signals than lions, and exhibit fewer behaviors. However, the extent to which flexibility has evolved in this kingdom trumps all others. Man transcended the capabilities of his own body by using tools and devices that allow him to explore the deepest trenches of the sea, climb the tallest mountains, and fly through the air and into space! We illustrated this propensity for evolving flexibility by stretching the metazoan cloud far across the information flux axis (Figure ​(Figure3,3, right).

What makes metazoan information processing particularly interesting is that they make heavy use of the correlation between different physical signals that are generated by the same source. For example, ground surface temperature and illuminance are correlated. Temperature and pH in the same location of a geothermal pond are correlated. This makes it possible to use one signal (a “proxy”) to make predictions about another, enabling the flexible Metazoa to clamp some of the “important” signals (like temperature) in their optimum range, by using proxy signals to generate the necessary responses. For example, migratory animals cross a wide range of latitudes, and could potentially be exposed to a wide range of temperatures, as expected from the local seasonal variations. However, those animals do not wait for the temperature variations to arrive before they migrate away from the affected area. They use proxy signals, such as the changes in diurnal illumination patterns, to detect the imminent arrival of the climatic change, and move out before it happens. These organisms evolve to be exposed only to a fraction of all temperatures that can potentially occur within their scope size. The use of proxies is facilitated by the large size of metazoan bodies, which literally serve as spatial projection palettes for the diverse patterns of proxy signals, thereby enabling a larger fraction of umwelt in the scope.

Coevolution of the two trios

Because scope content, and its division into umwelt and gap, depend on the way individuals explore their environment, it is fair to presume that the elements of the scope/umwelt/gap trio coevolve. At birth an individual is endowed with a certain set of evolved sensory organs and behaviors (and whatever unique mutations it might have) that predispose it to having a particular scope content. The individual samples the set of possible signals over the course of its lifetime, populating its umwelt and gap. The individual’s unique experience due to its own mutations, unique behavior, or local changes in the environment stemming from natural geological, climatic, and other variations, deviates from the scope that might have been expected at birth. As the genotypes of individuals evolve, their interaction with the environment changes. So do the scope content and its division into umwelt and gap. Let us consider, for example, the evolution of proxies. Animals avoid exposure to forest fires by using olfactory (combinations of chemical signals), visual (patterns of illumination wavelengths and intensity), and auditory (pressure variations) cues. The more flexible organisms evolve more sophisticated sensors (e.g., eye) as well as behaviors (e.g., sniffing), to extract more information from the proxy signals. As flexibility mechanisms evolve, some of the scope signals that are outside the organism’s optimum physiological range can become replaced with their proxies. This enriches the umwelt with the patterns of changes and combinations of different proxy signals, and shrinks the gap.

The correspondence between the scope/umwelt/gap and economy/flexibility/robustness is dynamic, not static. They coevolve together. Larger, more mobile organisms that have bigger scope are exposed to more signals. Such organisms are under greater selective pressure to evolve mechanisms of flexibility and robustness. Simultaneously, having more diverse mechanisms of flexibility and robustness should make it possible for organisms to venture into new territories, and be exposed to even more signals. This can result in progressively expansive evolution, which trades economy for flexibility, and robustness. Because flexibility and robustness mechanisms compete for matter-energy, organisms are expected to evolutionarily branch out into lineages that trade one for another within this expansive trend (Figure ​(Figure9B).9B). The branching is also expected within the process of reductive evolution. Organisms with smaller scope are also exposed to fewer signals, which reduce the selective pressure to evolve mechanisms of flexibility and robustness. Those strategies are evolutionarily traded for economy. This can result in progressively reductive evolution, to enable higher reproductive rates required to persist under the influence of now less predictable and less avoidable (though more rare) environmental signals. Within the same small budget, however, organisms will still branch out to evolve mechanism of flexibility and robustness with respect to some of the few signals to which they do get exposed. Does the persistence triangle have a boundary between the initial states that predispose toward expansive and reductive evolution?

We hypothesize that protist-like unicellular organisms form a kind of saddle manifold in the persistence triangle (Figure ​(Figure9B),9B), and thus represent such boundary. Organisms tend to evolve reductively on the economy side of this manifold, and expansively on the opposite side. We believe that viscosity of water historically set up the manifold. Viscosity sets the critical organism size (viscosity barrier) at which motility becomes useful for nutrient acquisition: about 100 μm. Below that size, there is negative selection pressure on motility speed due to its high energetic cost. This pressure results in small scope size and a lack of positive selection for the mechanisms of flexibility and robustness. These organisms can neither predict nor escape environmental disturbances. That, plus predation by bigger organisms, puts them on the path of reductive evolution toward the economy vertex (i.e., Akarya). Above the critical organism size, it becomes possible to chase and engulf other organisms. Bigger spatio-temporal range and predatory lifestyle expand and enrich the scope, putting a positive selection pressure on evolution of flexibility and robustness. This sets organisms on the path of expansive evolution with the divergence into those evolving toward enhanced flexibility (i.e., Metazoa) or robustness (i.e., Plants).

The described processes of reductive and expansive evolution along the budgetary axis have been previously discussed in the literature as the trends of evolution within the r/K continuum (e.g., Reznick et al., 2002). R-selected organisms have high growth rate, short lifespan, and produce many offspring with a low survival rate. K-selected organisms operate close to their environment’s carrying capacity. They live longer and produce fewer offspring with higher survival rate due to high parental investment. The economy vertex is a cognate of the r-selected extreme on the once-popular r/K continuum. Our framework adds a new dimension to this continuum: the axis of flexibility/robustness, which turns the r/K continuum into a branching structure (Figure ​(Figure9B),9B), more congruent with the usual depiction of the tree of life. Our depiction of branching evolutionary pathways within the persistence triangle is based on the function of an individual’s physical components and parts, as opposed to their structure, which formed the basis for building most trees of life to-date. The two approaches are complementary. Let us further discuss the molecular aspects of evolution of persistence strategies.

Molecular constraints on evolutionary movements within the persistence triangle

The persistence triangle embeds two tradeoff relationships. First, economy is in a tradeoff relationship with both flexibility and robustness. Second, flexibility and robustness are in a tradeoff with each other. If flexibility and robustness could be measured directly, we could draw the persistence triangle (Figure ​(Figure9A)9A) as it has been done for plant life strategies (discussed below; Grime, 1974). This persistence triangle is asymmetric, for three reasons. First, flexibility mechanisms tend to cost more matter-energy than robustness properties. All molecular constituents of an organism must be manufactured and maintained, regardless of their purpose. However, most of the elements conferring robustness just “sit there,” incurring no further cost (e.g., bark, thorns). In contrast, the information processing pathways that confer flexibility with respect to a particular signal use extra matter-energy when they process that signal. This difference in costs means that evolving an additional flexibility mechanism can expand budget more than evolving an additional robustness mechanism from the same location on the triangle. Consequently, the flexibility edge of the triangle is longer than the robustness edge (Figures ​(Figures33 and ​and9).9). Second, the space of possibilities for evolving flexibility is greater than that for robustness. Flexibility is correlated with the diversity of an organism’s building blocks. Organisms generate that diversity by evolving new building blocks, and by combining them with each other in various permutations, thereby creating multiple nested levels of complexity. Therefore, each additionally evolved building block creates opportunities to manufacture not one, but many new internal subsystems, potentially conferring flexibility against many different signals. Each of these new flexibility mechanisms can then serve as a starting point for further evolution. In contrast, robustness is correlated with redundancy of building blocks. Each additionally evolved building block that is robust against a particular signal confers robustness to the organism only with respect to that signal alone. Fewer uses for a robust mechanism translate into fewer opportunities for further evolution, compared to flexibility mechanisms. Third, evolution of flexibility begets more flexibility, and evolution of robustness begets more robustness. Flexibility is brought forth through information processing subsystems, e.g., sensors, transduction channels, and deciders. Through mutational modification, sensors are likely to generate more sensors (as, for example, is the case for cellular membrane ion channels; Anderson and Greenberg, 2001; Pohorille et al., 2005). Deciders are likely to generate more deciders, e.g., genetic regulatory elements (Ludwig, 2002) and neural networks (Bullock, 2002). Similarly, the molecular components that confer robustness tend to generate more components that contribute to robustness (e.g., collagens; Exposito et al., 2002). Combined with the greater space of evolutionary possibilities for flexibility, these processes result in the asymmetry of the persistence triangle. The flexibility edge is longer than the robustness edge. We hypothesize that the outlined self-reinforcement of flexibility and robustness results in evolutionary positive feedback loops that funnel lineages preferentially into those strategies. These loops must operate synergistically with the processes of expansive and reductive evolution.

Gray areas in the persistence triangle

The nice picture of the separating positive feedback loops for flexibility and robustness is somewhat muddied by economic constraints. Indeed, the division between umwelt and gap is exclusive: the same signal can be in either part of the scope, but not in both. However, the dominions of flexibility and robustness over signals overlap. Furthermore, multiple flexibility and robustness mechanisms can exist for the same signal. Here are three examples of managing signals at high cost:

• An organism may have more than one flexibility mechanism with respect to a single signal. This increases the expense of processing that signal. For example, we withdraw a hand from fire, and then blow on it to ease the pain – both responses to the same signal of pain.
• An organism may have more than one mechanism of robustness with respect to the same signal. This increases the expense of exposure to that signal. For example, both thick fur and layer of subcutaneous fat serve to make the arctic fox less vulnerable to cold.
• An organism may have both flexibility and robustness mechanisms with respect to the same signal. For example, fawns are both robust and flexible with respect to proximity to a predator. Coloration makes them difficult to see (robustness), and they freeze in response to the sight of predator (flexibility).

There are also ways of managing signals at lower cost:

• Applying a single blanket mechanism that works against multiple signals can decrease the costs of managing signals. For example, the avoidance behavior in Metazoa (a flexibility mechanism) can be used against the sight of a predator, a noxious smell, or extreme heat. Tree bark (a feature imparting robustness) provides protection against excessive evaporation as well as against mechanical damage. The problem is, a single blanket mechanism may not be optimal in every case it is used. Thus, blanket mechanisms promote economic use of resources while sacrificing survivability.
• A single body part or feature can be used to enhance both flexibility and robustness: two persistence strategies for the price of one body part. For example, a peacock’s tail can be fanned to attract females – a flexible response to the sight of a potential mate (Loyau et al., 2007). Its conspicuous coloration pattern may also serve as anti-predator robustness mechanism (Baker and Parker, 1979).

Finally, there are intermediate mechanisms that are difficult to classify as either flexibility or robustness. For example, repair processes are usually initiated in response to an internal stimulus indicating that damage occurred. On the one hand, repair is a mechanism of flexibility with respect to internal signals of damage. On the other hand, repair contributes to robustness with respect to external signals that are causing the damage. It allows the organism to remain under the influence of that signal without processing it, but withstanding it by constant repair of whatever damage it might have induced. Similarly indeterminate is the case of sporulation in unicells, which is a flexible response to external stimuli of starvation and desiccation, and which induces the state of heightened robustness. Repair and sporulation are also blanket mechanisms. Repair works with respect to any signal that induces damage in the organism. Sporulation works with respect to a wide range of stresses.

These overlaps between flexibility and robustness create gray areas in the persistence triangle. First, because blanket mechanisms work against a number of signals, evolution of one such blanket mechanism can move the organism laterally far away from the economy axis, without much increase in the budget. Second, co-option of a single mechanism into both flexibility and robustness improves the organism’s survivability without much impact on the budget (True and Carroll, 2002). Third, flexible responses can evolve by capitalizing on pre-existing information processing pathways, again preserving budget (e.g., sensory drive Wyatt, 2003). Thus, two organisms may occupy the same location (or at least the same stratum) in the triangle, but have different degrees of flexibility and robustness.

These ways of improving flexibility and robustness without much impact on budget create an evolutionary “room to expand” within any single budgetary (economic) stratum. Exploration of this gray area yields economically comparable organisms with diverse mechanisms of flexibility and robustness, perhaps resultant from adopting inhomogeneities within the same environmental niche. For example, the beak shape in Darwin’s famous Galapagos finches is related to the beak’s robustness with respect to food manipulation. The strength and timing of expression of the bone morphogenic protein four and of calmodulin during bird embryonic development seem to account for the wide diversity of beak shapes (Abzhanov et al., 2004, 2006; Wu et al., 2004). Thus, the diversity in beak robustness results from evolutionary exploration of the expression patterns of only two genes, without much impact on economy of the individuals.

At some point during exploration of this gray area, a lineage may break into the next economic stratum. A substantial loss of flexibility or robustness mechanisms will cause the organism to undergo reductive evolution and enter the economic stratum with lower budget. Invention of a new, more costly mechanism of flexibility or robustness causes the organism to undergo expansive evolution and enter the economic stratum further away from the economy vertex of the persistence triangle. This process is congruent with the theory of punctuated equilibrium (Gould and Eldredge, 1993). The gray areas of lateral evolution on the triangle within the same economic stratum correspond to the periods of “stasis”. The jumps to the adjacent economic stratum, via expansive or reductive evolution that result from a significant change in flexibility/robustness mechanisms correspond to the “punctuated change.”

These hypotheses allow us to propose a model for evolutionary separation of LUCA into the three cellular superkingdoms, as follows.

Persistence triangle is a complete and universal model of persistence strategies

Economy, flexibility, and robustness are both necessary and sufficient to describe the full set of persistence strategies. This trio was derived based on the division of scope into umwelt and gap. The umwelt and gap cover scope completely. Any signal is either processed by an organism, or not. If it is processed, it is part of the umwelt, and a flexibility mechanism is in place to process it. If the signal is not processed, then it is part of the gap, and there is not a flexibility mechanism in place for it. Depending on the budget, there may or may not be a robustness property in place to withstand the effects of that signal. Thus, flexibility and robustness completely describe what an organism does with information it encounters. Economy takes into account competition between organisms for matter/energy. Hence, the economy/flexibility/robustness trio is necessary and sufficient to fully describe an organism’s persistence strategy. Other factors, such as resilience, adaptivity, and vulnerability, have been considered in the literature, but they are either synonymous with or tangential to economy/flexibility/robustness. Unfortunately, the terms robustness, resilience, flexibility, and others, are used differently in mechanical engineering, computer engineering, software design, and biology. One has to follow the definitions when comparing our framework and conclusions to the models that are based on observations in those disciplines.

We believe that our framework is universally applicable to all classes of organisms. It works at the level of kingdoms, can be generalized to superkingdoms, and is able to resolve closely related organisms, such as Darwin’s finches.

Research was supported in part with funds from the University of Illinois and grants from the National Science Foundation (MCB-0749836), CREES-USDA, the Soybean Disease Biotechnology Center, and the United Soybean Board, all to Gustavo Caetano-Anollés. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the funding agencies. We thank Klaus Høiland for the suggested parallel with Grime’s theory of plant phenotypes and for the discussion with Gustavo Caetano-Anollés that prompted this study, and Charles G. Kurland for fruitful discussions of the predatory nature of Eukarya. Many thanks are extended to John Mainzer for useful discussions and suggestions on the manuscript text.