Biology:Effective population size

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Short description: Ecological concept

The effective population size (Ne) is size of an idealised population would experience the same rate of genetic drift or increase in inbreeding as in the real population. Idealised populations are based on unrealistic but convenient assumptions including random mating, simultaneous birth of each new generation, constant population size. For most quantities of interest and most real populations, Ne is smaller than the census population size N of a real population.[1] The same population may have multiple effective population sizes for different properties of interest, including genetic drift and inbreeding.

The effective population size is most commonly measured with respect to the coalescence time. In an idealised diploid population with no selection at any locus, the expectation of the coalescence time in generations is equal to twice the census population size. The effective population size is measured as within-species genetic diversity divided by four times the mutation rate [math]\displaystyle{ \mu }[/math], because in such an idealised population, the heterozygosity is equal to [math]\displaystyle{ 4N\mu }[/math]. In a population with selection at many loci and abundant linkage disequilibrium, the coalescent effective population size may not reflect the census population size at all, or may reflect its logarithm.

The concept of effective population size was introduced in the field of population genetics in 1931 by the United States geneticist Sewall Wright.[2][3]

Overview: Types of effective population size

Depending on the quantity of interest, effective population size can be defined in several ways. Ronald Fisher and Sewall Wright originally defined it as "the number of breeding individuals in an idealised population that would show the same amount of dispersion of allele frequencies under random genetic drift or the same amount of inbreeding as the population under consideration". More generally, an effective population size may be defined as the number of individuals in an idealised population that has a value of any given population genetic quantity that is equal to the value of that quantity in the population of interest. The two population genetic quantities identified by Wright were the one-generation increase in variance across replicate populations (variance effective population size) and the one-generation change in the inbreeding coefficient (inbreeding effective population size). These two are closely linked, and derived from F-statistics, but they are not identical.[4]

Today, the effective population size is usually estimated empirically with respect to the sojourn or coalescence time, estimated as the within-species genetic diversity divided by the mutation rate, yielding a coalescent effective population size.[5] Another important effective population size is the selection effective population size 1/scritical, where scritical is the critical value of the selection coefficient at which selection becomes more important than genetic drift.[6]

Empirical measurements

In Drosophila populations of census size 16, the variance effective population size has been measured as equal to 11.5.[7] This measurement was achieved through studying changes in the frequency of a neutral allele from one generation to another in over 100 replicate populations.

For coalescent effective population sizes, a survey of publications on 102 mostly wildlife animal and plant species yielded 192 Ne/N ratios. Seven different estimation methods were used in the surveyed studies. Accordingly, the ratios ranged widely from 10-6 for Pacific oysters to 0.994 for humans, with an average of 0.34 across the examined species. Based on these data they subsequently estimated more comprehensive ratios, accounting for fluctuations in population size, variance in family size and unequal sex-ratio. These ratios average to only 0.10-0.11.[8]

A genealogical analysis of human hunter-gatherers (Eskimos) determined the effective-to-census population size ratio for haploid (mitochondrial DNA, Y chromosomal DNA), and diploid (autosomal DNA) loci separately: the ratio of the effective to the census population size was estimated as 0.6–0.7 for autosomal and X-chromosomal DNA, 0.7–0.9 for mitochondrial DNA and 0.5 for Y-chromosomal DNA.[9]

Variance effective size

In the Wright-Fisher idealized population model, the conditional variance of the allele frequency [math]\displaystyle{ p' }[/math], given the allele frequency [math]\displaystyle{ p }[/math] in the previous generation, is

[math]\displaystyle{ \operatorname{var}(p' \mid p)= {p(1-p) \over 2N}. }[/math]

Let [math]\displaystyle{ \widehat{\operatorname{var}}(p'\mid p) }[/math] denote the same, typically larger, variance in the actual population under consideration. The variance effective population size [math]\displaystyle{ N_e^{(v)} }[/math] is defined as the size of an idealized population with the same variance. This is found by substituting [math]\displaystyle{ \widehat{\operatorname{var}}(p'\mid p) }[/math] for [math]\displaystyle{ \operatorname{var}(p'\mid p) }[/math] and solving for [math]\displaystyle{ N }[/math] which gives

[math]\displaystyle{ N_e^{(v)} = {p(1-p) \over 2 \widehat{\operatorname{var}}(p)}. }[/math]

Theoretical examples

In the following examples, one or more of the assumptions of a strictly idealised population are relaxed, while other assumptions are retained. The variance effective population size of the more relaxed population model is then calculated with respect to the strict model.

Variations in population size

Population size varies over time. Suppose there are t non-overlapping generations, then effective population size is given by the harmonic mean of the population sizes:[10]

[math]\displaystyle{ {1 \over N_e} = {1 \over t} \sum_{i=1}^t {1 \over N_i} }[/math]

For example, say the population size was N = 10, 100, 50, 80, 20, 500 for six generations (t = 6). Then the effective population size is the harmonic mean of these, giving:

[math]\displaystyle{ {1 \over N_e} }[/math] [math]\displaystyle{ = {\begin{matrix} \frac{1}{10} \end{matrix} + \begin{matrix} \frac{1}{100} \end{matrix} + \begin{matrix} \frac{1}{50} \end{matrix} + \begin{matrix} \frac{1}{80} \end{matrix} + \begin{matrix} \frac{1}{20} \end{matrix} + \begin{matrix} \frac{1}{500} \end{matrix} \over 6} }[/math]
[math]\displaystyle{ = {0.1945 \over 6} }[/math]
[math]\displaystyle{ = 0.032416667 }[/math]
[math]\displaystyle{ N_e }[/math] [math]\displaystyle{ = 30.8 }[/math]

Note this is less than the arithmetic mean of the population size, which in this example is 126.7. The harmonic mean tends to be dominated by the smallest bottleneck that the population goes through.

Dioeciousness

If a population is dioecious, i.e. there is no self-fertilisation then

[math]\displaystyle{ N_e = N + \begin{matrix} \frac{1}{2} \end{matrix} }[/math]

or more generally,

[math]\displaystyle{ N_e = N + \begin{matrix} \frac{D}{2} \end{matrix} }[/math]

where D represents dioeciousness and may take the value 0 (for not dioecious) or 1 for dioecious.

When N is large, Ne approximately equals N, so this is usually trivial and often ignored:

[math]\displaystyle{ N_e = N + \begin{matrix} \frac{1}{2} \approx N \end{matrix} }[/math]

Variance in reproductive success

If population size is to remain constant, each individual must contribute on average two gametes to the next generation. An idealized population assumes that this follows a Poisson distribution so that the variance of the number of gametes contributed, k is equal to the mean number contributed, i.e. 2:

[math]\displaystyle{ \operatorname{var}(k) = \bar{k} = 2. }[/math]

However, in natural populations the variance is often larger than this. The vast majority of individuals may have no offspring, and the next generation stems only from a small number of individuals, so

[math]\displaystyle{ \operatorname{var}(k) \gt 2. }[/math]

The effective population size is then smaller, and given by:

[math]\displaystyle{ N_e^{(v)} = {4 N - 2D \over 2 + \operatorname{var}(k)} }[/math]

Note that if the variance of k is less than 2, Ne is greater than N. In the extreme case of a population experiencing no variation in family size, in a laboratory population in which the number of offspring is artificially controlled, Vk = 0 and Ne = 2N.

Non-Fisherian sex-ratios

When the sex ratio of a population varies from the Fisherian 1:1 ratio, effective population size is given by:

[math]\displaystyle{ N_e^{(v)} = N_e^{(F)} = {4 N_m N_f \over N_m + N_f} }[/math]

Where Nm is the number of males and Nf the number of females. For example, with 80 males and 20 females (an absolute population size of 100):

[math]\displaystyle{ N_e }[/math] [math]\displaystyle{ = {4 \times 80 \times 20 \over 80 + 20} }[/math]
[math]\displaystyle{ ={6400 \over 100} }[/math]
[math]\displaystyle{ = 64 }[/math]

Again, this results in Ne being less than N.

Inbreeding effective size

Alternatively, the effective population size may be defined by noting how the average inbreeding coefficient changes from one generation to the next, and then defining Ne as the size of the idealized population that has the same change in average inbreeding coefficient as the population under consideration. The presentation follows Kempthorne (1957).[11]

For the idealized population, the inbreeding coefficients follow the recurrence equation

[math]\displaystyle{ F_t = \frac{1}{N}\left(\frac{1+F_{t-2}}{2}\right)+\left(1-\frac{1}{N}\right)F_{t-1}. }[/math]

Using Panmictic Index (1 − F) instead of inbreeding coefficient, we get the approximate recurrence equation

[math]\displaystyle{ 1-F_t = P_t = P_0\left(1-\frac{1}{2N}\right)^t. }[/math]

The difference per generation is

[math]\displaystyle{ \frac{P_{t+1}}{P_t} = 1-\frac{1}{2N}. }[/math]

The inbreeding effective size can be found by solving

[math]\displaystyle{ \frac{P_{t+1}}{P_t} = 1-\frac{1}{2N_e^{(F)}}. }[/math]

This is

[math]\displaystyle{ N_e^{(F)} = \frac{1}{2\left(1-\frac{P_{t+1}}{P_t}\right)} }[/math]

although researchers rarely use this equation directly.

Theoretical example: overlapping generations and age-structured populations

When organisms live longer than one breeding season, effective population sizes have to take into account the life tables for the species.

Haploid

Assume a haploid population with discrete age structure. An example might be an organism that can survive several discrete breeding seasons. Further, define the following age structure characteristics:

[math]\displaystyle{ v_i = }[/math] Fisher's reproductive value for age [math]\displaystyle{ i }[/math],
[math]\displaystyle{ \ell_i = }[/math] The chance an individual will survive to age [math]\displaystyle{ i }[/math], and
[math]\displaystyle{ N_0 = }[/math] The number of newborn individuals per breeding season.

The generation time is calculated as

[math]\displaystyle{ T = \sum_{i=0}^\infty \ell_i v_i = }[/math] average age of a reproducing individual

Then, the inbreeding effective population size is[12]

[math]\displaystyle{ N_e^{(F)} = \frac{N_0T}{1 + \sum_i\ell_{i+1}^2v_{i+1}^2(\frac{1}{\ell_{i+1}}-\frac{1}{\ell_i})}. }[/math]

Diploid

Similarly, the inbreeding effective number can be calculated for a diploid population with discrete age structure. This was first given by Johnson,[13] but the notation more closely resembles Emigh and Pollak.[14]

Assume the same basic parameters for the life table as given for the haploid case, but distinguishing between male and female, such as N0ƒ and N0m for the number of newborn females and males, respectively (notice lower case ƒ for females, compared to upper case F for inbreeding).

The inbreeding effective number is

[math]\displaystyle{ \begin{align} \frac{1}{N_e^{(F)}} = \frac{1}{4T}\left\{\frac{1}{N_0^f}+\frac{1}{N_0^m} + \sum_i\left(\ell_{i+1}^f\right)^2\left(v_{i+1}^f\right)^2\left(\frac{1}{\ell_{i+1}^f}-\frac{1}{\ell_i^f}\right)\right. \,\,\,\,\,\,\,\, & \\ \left. {} + \sum_i\left(\ell_{i+1}^m\right)^2\left(v_{i+1}^m\right)^2\left(\frac{1}{\ell_{i+1}^m}-\frac{1}{\ell_i^m}\right) \right\}. & \end{align} }[/math]

Coalescent effective size

According to the neutral theory of molecular evolution, a neutral allele remains in a population for Ne generations, where Ne is the effective population size. An idealised diploid population will have a pairwise nucleotide diversity equal to 4[math]\displaystyle{ \mu }[/math]Ne, where [math]\displaystyle{ \mu }[/math] is the mutation rate. The sojourn effective population size can therefore be estimated empirically by dividing the nucleotide diversity by the mutation rate.[5]

The coalescent effective size may have little relationship to the number of individuals physically present in a population.[15] Measured coalescent effective population sizes vary between genes in the same population, being low in genome areas of low recombination and high in genome areas of high recombination.<ref>{{cite journal |title=Toward a selection theory of molecular evolution|journal=Evolution|year=2008|volume=62|pages=255–265|doi=10.1111/j.1558-5646.2007.00308.x |author=Hahn, Matthew W.

Selection effective size

In an idealised Wright-Fisher model, the fate of an allele, beginning at an intermediate frequency, is largely determined by selection if the selection coefficient s ≫ 1/N, and largely determined by neutral genetic drift if s ≪ 1/N. In real populations, the cutoff value of s may depend instead on local recombination rates.[6]<ref>{{cite journal

See also

References

  1. "Effective population size". Blackwell Publishing. http://www.blackwellpublishing.com/ridley/a-z/Effective_population_size.asp. 
  2. Wright S (1931). "Evolution in Mendelian populations". Genetics 16 (2): 97–159. doi:10.1093/genetics/16.2.97. PMID 17246615. PMC 1201091. http://www.esp.org/foundations/genetics/classical/holdings/w/sw-31.pdf. 
  3. Wright S (1938). "Size of population and breeding structure in relation to evolution". Science 87 (2263): 430–431. doi:10.1126/science.87.2263.425-a. 
  4. James F. Crow (2010). "Wright and Fisher on Inbreeding and Random Drift". Genetics 184 (3): 609–611. doi:10.1534/genetics.109.110023. PMID 20332416. 
  5. 5.0 5.1 Lynch, M.; Conery, J.S. (2003). "The origins of genome complexity". Science 302 (5649): 1401–1404. doi:10.1126/science.1089370. PMID 14631042. Bibcode2003Sci...302.1401L. 
  6. 6.0 6.1 R.A. Neher; B.I. Shraiman (2011). "Genetic Draft and Quasi-Neutrality in Large Facultatively Sexual Populations". Genetics 188 (4): 975–996. doi:10.1534/genetics.111.128876. PMID 21625002. 
  7. Buri, P (1956). "Gene frequency in small populations of mutant Drosophila". Evolution 10 (4): 367–402. doi:10.2307/2406998. 
  8. R. Frankham (1995). "Effective population size/adult population size ratios in wildlife: a review". Genetics Research 66 (2): 95–107. doi:10.1017/S0016672300034455. 
  9. S. Matsumura; P. Forster (2008). "Generation time and effective population size in Polar Eskimos.". Proc Biol Sci 275 (1642): 1501–1508. doi:10.1098/rspb.2007.1724. PMID 18364314. 
  10. Karlin, Samuel (1968-09-01). "Rates of Approach to Homozygosity for Finite Stochastic Models with Variable Population Size". The American Naturalist 102 (927): 443–455. doi:10.1086/282557. ISSN 0003-0147. 
  11. Kempthorne O (1957). An Introduction to Genetic Statistics. Iowa State University Press. 
  12. Felsenstein J (1971). "Inbreeding and variance effective numbers in populations with overlapping generations". Genetics 68 (4): 581–597. doi:10.1093/genetics/68.4.581. PMID 5166069. 
  13. Johnson DL (1977). "Inbreeding in populations with overlapping generations". Genetics 87 (3): 581–591. doi:10.1093/genetics/87.3.581. PMID 17248780. 
  14. "Fixation probabilities and effective population numbers in diploid populations with overlapping generations". Theoretical Population Biology 15 (1): 86–107. 1979. doi:10.1016/0040-5809(79)90028-5. 
  15. Gillespie, JH (2001). "Is the population size of a species relevant to its evolution?". Evolution 55 (11): 2161–2169. doi:10.1111/j.0014-3820.2001.tb00732.x. PMID 11794777. 

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