The quantitative genetic consequences of pleiotropy under stabilizing and directional selection.

Abstract The independence of two phenotypic characters affected by both pleiotropic and nonpleiotropic mutations is investigated using a generalization of M. Slatkin's stepwise mutation model of 1987. The model is used to determine whether predictions of either the multivariate normal model introduced in 1980 by R. Lande or the house-of-cards model introduced in 1985 by M. Turelli can be regarded as typical of models that are intermediate between them. We found that, under stabilizing selection, the variance of one character at equilibrium may depend on the strength of stabilizing selection on the other character (as in the house-of-cards model) or not (as in the multivariate normal model) depending on the types of mutations that can occur. Similarly, under directional selection, the genetic covariance between two characters may increase substantially (as in the house-of-cards model) or not (as in the multivariate normal model) depending on the kinds of mutations that are assumed to occur. Hence, even for the simple model we consider, neither the house-of-cards nor the multivariate normal model can be used to make predictions, making it unlikely that either could be used to draw general conclusions about more complex and realistic models.

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Quantitative genetic variability maintained by mutation-stabilizing selection balance: sampling variation and response to subsequent directional selection

Genetics Research ◽

10.1017/s0016672300028366 ◽

1989 ◽

Vol 54 (1) ◽

pp. 45-58 ◽

Cited By ~ 17

Author(s):

Peter D. Keightley ◽

William G. Hill

Keyword(s):

Genetic Variance ◽

Directional Selection ◽

Quantitative Character ◽

Stabilizing Selection ◽

Effective Population ◽

Selection Responses ◽

Quantitative Genetic ◽

Before And After ◽

Cage Population ◽

Selection Of

SummaryA model of genetic variation of a quantitative character subject to the simultaneous effects of mutation, selection and drift is investigated. Predictions are obtained for the variance of the genetic variance among independent lines at equilibrium with stabilizing selection. These indicate that the coefficient of variation of the genetic variance among lines is relatively insensitive to the strength of stabilizing selection on the character. The effects on the genetic variance of a change of mode of selection from stabilizing to directional selection are investigated. This is intended to model directional selection of a character in a sample of individuals from a natural or long-established cage population. The pattern of change of variance from directional selection is strongly influenced by the strengths of selection at individual loci in relation to effective population size before and after the change of regime. Patterns of change of variance and selection responses from Monte Carlo simulation are compared to selection responses observed in experiments. These indicate that changes in variance with directional selection are not very different from those due to drift alone in the experiments, and do not necessarily give information on the presence of stabilizing selection or its strength.

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Longitudinal analysis of lung function growth in healthy children and adolescents

Journal of Applied Physiology ◽

10.1152/jappl.1991.70.2.770 ◽

1991 ◽

Vol 70 (2) ◽

pp. 770-777 ◽

Cited By ~ 30

Author(s):

J. L. Hopper ◽

M. E. Hibbert ◽

G. T. Macaskill ◽

P. D. Phelan ◽

L. I. Landau

Keyword(s):

Lung Function ◽

Early Detection ◽

Vital Capacity ◽

Forced Expiratory Volume ◽

Healthy Children ◽

Normal Model ◽

Multivariate Normal ◽

Pronounced Increase ◽

Multivariate Normal Model ◽

Healthy Lung

Lung function and height in 242 8-yr-old and 299 12-yr-old children without known or suspected predisposition to lung disease were measured annually over 6 and 8 yr, respectively. Growth of forced expiratory volume in 1 s (FEV1), vital capacity, and expiratory flow after expiring 50% of vital capacity were statistically modeled by age and height by use of a multivariate normal model for longitudinal data. This method has the flexibility to fit an appropriate (not necessarily linear) mathematical description of average lung function while concurrently modeling the covariance between measures on the same individual. Differences in lung function growth between girls and boys, pre- and post-puberty, showed that girls had a steadier though less pronounced increase in lung function with height. In boys, before puberty there was deficit in lung volume relative to height (not evident in girls), which was compensated for by rapid growth after puberty. The standard error of FEV1 predictions based on current height and age were more than halved when measurements of FEV1, age, and height taken 1 yr before were incorporated. We found evidence for dysanaptic growth in childhood. Fitted models have application to early detection of departures from healthy lung function.

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