Preferential entailment: Difference between revisions

Revision as of 17:46, 9 January 2013

Malecot's coancestry coefficient, $f$ , refers to an indirect measure of genetic similarity of two individuals which was initially devised by the French mathematician Gustave Malécot.

$f$ is defined as the probability that any two alleles, sampled at random (one from each individual), are identical copies of an ancestral allele. In species with well-known lineages (such as domesticated crops), $f$ can be calculated by examining detailed pedigree records. Modernly, $f$ can be estimated using genetic marker data.

Evolution of inbreeding coefficient in finite size populations

In a finite size population, after some generations, all individuals will have a common ancestor : $f \to 1$ . Consider a non-sexual population of fixed size $N$ , and call $f_{i}$ the inbreeding coefficient of generation $i$ . Here, $f$ means the probability that two individuals picked at random will have a common ancestor. At each generation, each individual produces a large number $k ≫ 1$ of descendants, from the pool of which $N$ individual will be chosen at random to form the new generation.

At generation $n$ , the probability that two individuals have a common ancestor is "they have a common parent" OR "they descend from two distinct individuals which have a common ancestor" :

f_{n} = \frac{k - 1}{k N} + \frac{k (N - 1)}{k N} f_{n - 1}

\approx \frac{1}{N} + (1 - \frac{1}{N}) f_{n - 1} .

This is a recurrence relation easily solved. Considering the worst case where at generation zero, no two individuals have a common ancestor,

f_{0} = 0

, we get

f_{n} = 1 - (1 - \frac{1}{N})^{n} .

The scale of the fixation time (average number of generation it takes to homogenize the population) is therefore

\bar{n} = - 1 / \log (1 - 1 / N) \approx N .

This computation trivially extends to the inbreeding coefficients of alleles in a sexual population by changing $N$ to $2 N$ (the number of gametes).

References

Malécot G. Les mathématiques de l'hérédité. Paris: Masson & Cie, 1948.

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+{{underlinked|date=December 2012}}
+'''Malecot's coancestry coefficient''', '''<math>f</math>''', refers to an indirect [[measure]] of genetic [[similarity]] of two individuals which was initially devised by the [[France| French]] mathematician [[Gustave Malécot]].
+<math>f</math> is defined as the probability that any two [[alleles]], [[sample (statistics)|sampled]] at random (one from each individual), are identical copies of an ancestral allele.  In species with well-known lineages (such as domesticated crops), <math>f</math> can be calculated by examining detailed pedigree records.  Modernly, <math>f</math> can be estimated using [[genetic marker]] data.
+== Evolution of inbreeding coefficient in finite size populations ==
+In a finite size [[population]], after some generations, all individuals will have a [[common ancestor]] : <math>f \rightarrow 1 </math>.
+Consider a non-sexual population of fixed size <math>N</math>, and  call <math>f_i</math> the inbreeding coefficient of generation <math>i</math>. Here, <math>f</math> means the probability that two individuals picked at random will have a common ancestor. At each generation, each individual produces a large number <math>k \gg 1</math> of descendants, from the pool of which <math>N</math> individual will be chosen at random to form the new generation.
+At generation <math>n</math>, the probability that two individuals have a common ancestor is "they have a common parent" OR "they descend from two distinct individuals which have a common ancestor" :
+:<math>f_n = \frac{k-1}{kN} + \frac{k(N-1)}{kN}f_{n-1}</math>
+:<math>  \approx  \frac{1}{N}+ (1-\frac{1}{N})f_{n-1}. </math>
+This is a [[recurrence relation]] easily solved. Considering the worst case where at generation zero, no two individuals have a common ancestor,
+:<math>f_0=0</math>, we get
+:<math>f_n = 1 - (1- \frac{1}{N})^n.</math>
+The scale of the fixation time (average number of generation it takes to homogenize the population) is therefore
+:<math> \bar{n}= -1/\log(1-1/N) \approx N. </math>
+This computation trivially extends to the inbreeding coefficients of alleles in a sexual population by changing <math>N</math> to <math>2N</math> (the number of [[gametes]]).
+== References ==
+*Malécot G. ''Les mathématiques de l'hérédité.'' Paris: Masson & Cie, 1948.
+[[Category:Classical genetics]]

Preferential entailment: Difference between revisions

Revision as of 17:46, 9 January 2013

Evolution of inbreeding coefficient in finite size populations

References

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