A pseudo-likelihood method for estimating effective population size from temporally spaced samples

JINLIANG WANG

doi:10.1017/S0016672301005286

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

A pseudo maximum likelihood method is proposed to estimate effective population size (Ne) using temporal changes in allele frequencies at multi-allelic loci. The computation is simplified dramatically by (1) approximating the multi-dimensional joint probabilities of all the data by the product of marginal probabilities (hence the name pseudo-likelihood), (2) exploiting the special properties of transition matrix and (3) using a hidden Markov chain algorithm. Simulations show that the pseudo-likelihood method has a similar performance but needs much less computing time and storage compared with the full likelihood method in the case of 3 alleles per locus. Due to computational developments, I was able to assess the performance of the pseudo-likelihood method against the F-statistic method over a wide range of parameters by extensive simulations. It is shown that the pseudo-likelihood method gives more accurate and precise estimates of Ne than the F-statistic method, and the performance difference is mainly due to the presence of rare alleles in the samples. The pseudo-likelihood method is also flexible and can use three or more temporal samples simultaneously to estimate satisfactorily the Nes of each period, or the growth parameters of the population. The accuracy and precision of both methods depend on the ratio of the product of sample size and the number of generations involved to Ne, and the number of independent alleles used. In an application of the pseudo-likelihood method to a large data set of an olive fly population, more precise estimates of Ne are obtained than those from the F-statistic method.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Turner, Thomas F Wares, John P and Gold, John R 2002. Genetic Effective Size Is Three Orders of Magnitude Smaller Than Adult Census Size in an Abundant, Estuarine-Dependent Marine Fish (Sciaenops ocellatus). Genetics, Vol. 162, Issue. 3, p. 1329.

Beaumont, Mark A 2003. Estimation of Population Growth or Decline in Genetically Monitored Populations. Genetics, Vol. 164, Issue. 3, p. 1139.

Wang, Jinliang 2003. Maximum-Likelihood Estimation of Admixture Proportions From Genetic Data. Genetics, Vol. 164, Issue. 2, p. 747.

Beaumont, M.A. 2003. Handbook of Statistical Genetics.

Wang, Jinliang and Whitlock, Michael C 2003. Estimating Effective Population Size and Migration Rates From Genetic Samples Over Space and Time. Genetics, Vol. 163, Issue. 1, p. 429.

Miller, Craig R. and Waits, Lisette P. 2003. The history of effective population size and genetic diversity in the Yellowstone grizzly ( Ursus arctos ): Implications for conservation . Proceedings of the National Academy of Sciences, Vol. 100, Issue. 7, p. 4334.

Goldringer, Isabelle and Bataillon, Thomas 2004. On the Distribution of Temporal Variations in Allele Frequency. Genetics, Vol. 168, Issue. 1, p. 563.

Hill, W. G. and Weir, B. S. 2004. Moment estimation of population diversity and genetic distance from data on recessive markers*. Molecular Ecology, Vol. 13, Issue. 4, p. 895.

Spidle, Adrian P King, Tim L and Letcher, Benjamin H 2004. Comparison of genetic diversity in the recently founded Connecticut River Atlantic salmon population to that of its primary donor stock, Maine's Penobscot River. Aquaculture, Vol. 236, Issue. 1-4, p. 253.

RAMAKRISHNAN, UMA STORZ, JAY F. TAYLOR, BARBARA L. and LANDE, RUSSELL 2004. Estimation of genetically effective breeding numbers using a rejection algorithm approach. Molecular Ecology, Vol. 13, Issue. 11, p. 3283.

Beaumont, M A 2004. Recent developments in genetic data analysis: what can they tell us about human demographic history?. Heredity, Vol. 92, Issue. 5, p. 365.

Hoffman, Eric A. Schueler, Frederick W. and Blouin, Michael S. 2004. EFFECTIVE POPULATION SIZES AND TEMPORAL STABILITY OF GENETIC STRUCTURE IN RANA PIPIENS, THE NORTHERN LEOPARD FROG. Evolution, Vol. 58, Issue. 11, p. 2536.

Tallmon, David A Luikart, Gordon and Beaumont, Mark A 2004. Comparative Evaluation of a New Effective Population Size Estimator Based on Approximate Bayesian Computation. Genetics, Vol. 167, Issue. 2, p. 977.

JOHNSON, JEFF A. BELLINGER, M. RENEE TOEPFER, JOHN E. and DUNN, PETER 2004. Temporal changes in allele frequencies and low effective population size in greater prairie‐chickens. Molecular Ecology, Vol. 13, Issue. 9, p. 2617.

Gold, John R. 2004. Stock Enhancement and Sea Ranching. p. 353.

Trouve, S. Degen, L. and Goudet, J. 2005. Ecological components and evolution of selfing in the freshwater snail Galba truncatula. Journal of Evolutionary Biology, Vol. 18, Issue. 2, p. 358.

Wang, Jinliang 2005. Estimation of effective population sizes from data on genetic markers. Philosophical Transactions of the Royal Society B: Biological Sciences, Vol. 360, Issue. 1459, p. 1395.

LEBERG, PAUL DeYoung and Brennan 2005. GENETIC APPROACHES FOR ESTIMATING THE EFFECTIVE SIZE OF POPULATIONS. Journal of Wildlife Management, Vol. 69, Issue. 4, p. 1385.

Hoarau, Galice Boon, Eva Jongma, Dorris N Ferber, Steven Palsson, Jonbjorn Van der Veer, Henk W Rijnsdorp, Adriaan D Stam, Wytze T and Olsen, Jeanine L 2005. Low effective population size and evidence for inbreeding in an overexploited flatfish, plaice (Pleuronectes platessaL.). Proceedings of the Royal Society B: Biological Sciences, Vol. 272, Issue. 1562, p. 497.

Download full list

Article contents

A pseudo-likelihood method for estimating effective population size from temporally spaced samples

Abstract

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests