A Finite-Population Revenue Management Model and a Risk-Ratio Procedure for the Joint Estimation of Population Size and Parameters

Abstract In the past, moment and likelihood methods have been developed to estimate the effective population size (Ne) on the basis of the observed changes of marker allele frequencies over time, and these have been applied to a large variety of species and populations. Such methods invariably make the critical assumption of a single isolated population receiving no immigrants over the study interval. For most populations in the real world, however, migration is not negligible and can substantially bias estimates of Ne if it is not accounted for. Here we extend previous moment and maximum-likelihood methods to allow the joint estimation of Ne and migration rate (m) using genetic samples over space and time. It is shown that, compared to genetic drift acting alone, migration results in changes in allele frequency that are greater in the short term and smaller in the long term, leading to under- and overestimation of Ne, respectively, if it is ignored. Extensive simulations are run to evaluate the newly developed moment and likelihood methods, which yield generally satisfactory estimates of both Ne and m for populations with widely different effective sizes and migration rates and patterns, given a reasonably large sample size and number of markers.

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A note on the diffusion approximation for the variance of the number of generations until fixation of a neutral mutant gene

Genetics Research ◽

10.1017/s0016672300001579 ◽

1970 ◽

Vol 15 (2) ◽

pp. 251-255 ◽

Cited By ~ 12

Author(s):

P. Narain

Keyword(s):

Population Size ◽

General Expression ◽

Diffusion Approximation ◽

Finite Population ◽

Mutant Gene ◽

Matrix Methods ◽

Neutral Gene

SUMMARYA general expression is derived for the variance of time to fixation of a neutral gene in a finite population using a diffusion approximation. The results are compared with exact values derived by matrix methods for a population size of 8.

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POPULATION DYNAMICS OF SEX-DETERMINING ALLELES IN HONEY BEES AND SELF-INCOMPATIBILITY ALLELES IN PLANTS

Genetics ◽

10.1093/genetics/91.3.609 ◽

1979 ◽

Vol 91 (3) ◽

pp. 609-626 ◽

Cited By ~ 1

Author(s):

Shozo Yokoyama ◽

Masatoshi Nei

Keyword(s):

Population Dynamics ◽

Population Size ◽

Honey Bee ◽

Honey Bees ◽

Finite Population ◽

Large Population ◽

Allele Frequencies ◽

Self Incompatibility ◽

Overdominant Selection ◽

Incompatibility Alleles

ABSTRACT Mathematical theories of the population dynamics of sex-determining alleles in honey bees are developed. It is shown that in an infinitely large population the equilibrium frequency of a sex allele is l/n, where n is the number of alleles in the population, and the asymptotic rate of approach to this equilibrium is 2/(3n) per generation. Formulae for the distribution of allele frequencies and the effective and actual numbers of alleles that can be maintained in a finite population are derived by taking into account the population size and mutation rate. It is shown that the allele frequencies in a finite population may deviate considerably from l/n. Using these results, available data on the number of sex alleles in honey bee populations are discussed. It is also shown that the number of self-incompatibility alleles in plants can be studied in a much simpler way by the method used in this paper. A brief discussion about general overdominant selection is presented.

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Coevolution fails to maintain genetic variation in a host–parasite model with constant finite population size

Theoretical Population Biology ◽

10.1016/j.tpb.2020.12.001 ◽

2020 ◽

Author(s):

Ailene MacPherson ◽

Matthew J. Keeling ◽

Sarah P. Otto

Keyword(s):

Genetic Variation ◽

Population Size ◽

Finite Population ◽

Host Parasite

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DIFFUSION OF A POPULATION OF INTERACTING REPLICATORS IN SEQUENCE SPACE

Advances in Complex Systems ◽

10.1142/s0219525902000675 ◽

2002 ◽

Vol 05 (04) ◽

pp. 457-461 ◽

Cited By ~ 5

Author(s):

BÄRBEL M. R. STADLER

Keyword(s):

Simple Model ◽

Population Size ◽

Computer Simulations ◽

Mutation Rate ◽

Sequence Space ◽

Finite Population ◽

Fitness Landscape ◽

Diffusion Constant ◽

Sequence Length

We consider a simple model for catalyzed replication. Computer simulations show that a finite population moves in sequence space by diffusion analogous to the behavior of a quasispecies on a flat fitness landscape. The diffusion constant depends linearly on the per position mutation rate and the ratio of sequence length and population size.

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The supersession of one rumour by another

Journal of Applied Probability ◽

10.2307/3213265 ◽

1977 ◽

Vol 14 (1) ◽

pp. 127-134 ◽

Cited By ~ 22

Author(s):

G. K. Osei ◽

J. W. Thompson

Keyword(s):

Population Size ◽

Finite Population ◽

Closed Population ◽

Asymptotic Case ◽

Distribution Of The Maximum ◽

Maximum Value

A model is considered for a situation in which one rumour suppresses another in a closed population. The distribution of the maximum value attained by the proportion spreading the weaker rumour is obtained in the asymptotic case, and this is compared with some actual distributions for finite population size. Closer approximations to the latter distributions are obtained.

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The role of finite population size and linkage in response to continued truncation selection

Theoretical and Applied Genetics ◽

10.1007/bf01245627 ◽

1968 ◽

Vol 38 (6) ◽

pp. 264-270 ◽

Cited By ~ 3

Author(s):

A. W. Qureshi

Keyword(s):

Population Size ◽

Finite Population ◽

Truncation Selection

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A Monopolistic and Oligopolistic Stochastic Flow Revenue Management Model

Operations Research ◽

10.1287/opre.1060.0336 ◽

2006 ◽

Vol 54 (6) ◽

pp. 1098-1109 ◽

Cited By ~ 38

Author(s):

Xiaowei Xu ◽

Wallace J. Hopp

Keyword(s):

Revenue Management ◽

Management Model ◽

Stochastic Flow

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THE EVOLUTION OF MULTIGENE FAMILIES UNDER INTRACHROMOSOMAL GENE CONVERSION

Genetics ◽

10.1093/genetics/106.3.529 ◽

1984 ◽

Vol 106 (3) ◽

pp. 529-548

Author(s):

Thomas Nagylaki

Keyword(s):

Population Size ◽

Gene Conversion ◽

Finite Population ◽

Convergence Time ◽

Crossing Over ◽

Cubic Equation ◽

Crossover Rate ◽

Monoecious Population ◽

New Alleles ◽

Repeated Genes

ABSTRACT A model for the evolution of the probabilities of genetic identity within and between loci of a multigene family in a finite population is formulated and investigated. Unbiased intrachromosomal gene conversion, equal crossing over between tandemly repeated genes, random genetic drift and mutation to new alleles are incorporated. Generations are discrete and nonoverlapping; the diploid, monoecious population mates at random. Formulas for the equilibrium values of the probabilities of identity and a cubic equation for the rate of convergence are deduced. Numerical examples indicate the following. The amount of homology at equilibrium generally decreases as the mutation rate, the population size and the number of repeats increase; it may increase or decrease with increasing crossover rate. The intralocus homology has an intermediate minimum, whereas the interlocus homology increases, as the rate of gene conversion increases. The intralocus homology decreases, whereas the interlocus homology increases, as the proportion of symmetric heteroduplexes increases. The characteristic convergence time can be sufficiently short to imply that intrachromosomal gene conversion may be an important mechanism for maintaining sequence homogeneity among repeated genes. The convergence time decreases as the conversion rate and the proportion of symmetric heteroduplexes increase; although exceptions occur, it generally increases as the population size and the number of repeats increase; it may increase or decrease with increasing crossover rate.

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Joint Estimation of Pedigrees and Effective Population Size Using Markov Chain Monte Carlo

10.1101/492678 ◽

2018 ◽

Author(s):

Amy Ko ◽

Rasmus Nielsen

Keyword(s):

Monte Carlo ◽

Markov Chain ◽

Markov Chain Monte Carlo ◽

Population Size ◽

Effective Population Size ◽

Simulated Data ◽

Composite Likelihood ◽

Joint Estimation ◽

Pedigree Information ◽

Effective Population

Pedigrees provide a fine resolution of the genealogical relationships among individuals and serve an important function in many areas of genetic studies. One such use of pedigree information is in the estimation of short-term effective population size (Ne), which is of great relevance in fields such as conservation genetics. Despite the usefulness of pedigrees, however, they are often an unknown parameter and must be inferred from genetic data. In this study, we present a Bayesian method to jointly estimate pedigrees and Ne from genetic markers using Markov Chain Monte Carlo. Our method supports analysis of a large number of markers and individuals with the use of composite likelihood, which significantly increases computational efficiency. We show on simulated data that our method is able to jointly estimate relationships up to first cousins and Ne with high accuracy. We also apply the method on a real dataset of house sparrows to reconstruct their previously unreported pedigree.

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