4.1 Phylogeny and Evolution
35
d Subscript normal upper H Baseline left parenthesis bold s comma bold s Superscript prime Baseline right parenthesis equals sigma summation Underscript i equals 1 Overscript upper N Endscripts StartFraction left parenthesis s Subscript i Baseline minus s prime Subscript i right parenthesis squared Over 4 EndFraction commadH(s, s,) =
N
Σ
i=1
(si −s,
i)2
4
,
(4.5)
and the overlap between two genomes bold ss and bold s primes, is given by the related parameter
omega left parenthesis bold s comma bold s Superscript prime Baseline right parenthesis equals StartFraction 1 Over upper N EndFraction sigma summation Underscript i equals 1 Overscript upper N Endscripts s Subscript i Baseline s Subscript i Superscript prime Baseline equals 1 minus StartFraction 2 d Subscript normal upper H Baseline left parenthesis bold s comma bold s Superscript prime Baseline right parenthesis Over upper N EndFraction periodω(s, s,) = 1
N
N
Σ
i=1
sis,
i = 1 −2dH(s, s,)
N
.
(4.6)
omegaω is an order parameter analogous to magnetization in a ferromagnet. If the mutation
rate is higher than an error rate threshold, then the population is distributed uniformly
over the whole genotype space (“wandering” régime) and the average overlaptilde 1 divided by upper N∼1/N
(see Sect. 14.7.2); below the threshold, the population lies a finite distance away from
the fittest genotype and omega tilde 1 minus script upper O left parenthesis 1 divided by upper N right parenthesisω ∼1 −O(1/N). 17 Intermediate between these two cases
(none and maximal epistatic interactions) are the rugged landcapes studied by Kauff-
man (1984). 18 More realistic models need to include changing fitness landscapes,
resulting from interactions between species—competition (one species inhibits the
increase of another), exploitation (A inhibits B but B stimulates A), or mutualism
(one species stimulates the increase of another; i.e., coevolution).
As presented, the models deal with asexual reproduction. Sex introduces compli-
cations but can, in principle, be handled within the general framework.
These models concern microevolution (the evolving units are individuals); if the
evolving units are species or larger units such as families, then one may speak of
macroevolution. There has been particular interest in modelling mass extinctions,
which may follow a power law (i.e., the number nn of extinguished families tilde n Superscript gamma∼nγ,
withgammaγ equal to aboutnegative 2−2 according to current estimates). Bak and Sneppen (1993) 19
invented a model for the macroevolution of biological units (such as species) in
which each unit is assigned a fitness upper FF, defined as the barrier height for mutation
into another unit. At each iteration, the species with the lowest barrier is mutated—
implying assigned a new fitness, chosen at random from a finite range of values.
The mean fitness of the ecosystem rises inexorably to the maximum value, but if
the species interact and a number of neighbours are also mutated, regardless of their
fitnesses (this simulates the effect of, say, the extinction of a certain species of grass
on the animals feeding exclusively on that grass 20), the ecosystem evolves such that
almost all species have fitnesses above a critical threshold; that is, the model shows
self-organized criticality. Avalanches of mutations can be identified and their size
follows a power law distribution, albeit withgamma tilde negative 1γ ∼−1. Hence, there have been various
attempts to modify the model to bring the value of the exponent closer to the value
(negative 2−2) believed to be characteristic of Earth’s prehistory. 21
17 See Peliti (1996) for a comprehensive treatment.
18 Cf. Sect. 12.2; see Jongeling (1996) for a critique.
19 See also Flyvbjerg et al. (1995).
20 For example, the takahe feeds almost exclusively on snow grass.
21 Newman (1996).