Abstract
BackgroundProbabilistic reaction norms (PRNs) are an extension of the concept of reaction norms, developed to account for stochasticity in ontogenetic transitions. However, logistic regression based PRNs are restricted to discrete time intervals, whereas previously proposed models for continuous transitions are demanding in terms of modelling effort and data needed.Methodology/Principal FindingsHere we introduce two alternative approaches for the probabilistic modelling of continuous ontogenetic transitions. The models are simplified in their description of forces underlying transitions, thus being empirical rather than mechanistic by their nature, but therefore applicable to situations where data and prior knowledge of transitions are limited. The models provide continuous time description of the transition pattern, insights into how it is affected by covariates, at the same time allowing for fine scale transition probability predictions. Performance of the models is demonstrated using empirical data on metamorphosis in common frogs (Rana temporaria) reared in a common garden experiment.Conclusions/SignificanceAs being user-friendly and methodologically easily accessible, the models introduced in this study aid the concept of probabilistic reaction norms becoming as general and applicable tool in the studies of life-history variation as the deterministic reaction norms are today.
Highlights
Reaction norms are a common tool for describing phenotypic plasticity in quantitative traits [1,2] as well as for understanding evolutionary processes at the level of life-histories [3]
In practice the estimation of the Probabilistic reaction norms (PRNs) is done through a logistic regression, so that probabilities for ontogenetic life-history transitions are estimated separately for discrete time intervals [7]: logit ðpiÞ~logðpi=ð1{piÞÞ~aizbTi xi ð1Þ
The logistic regression based PRNs model is not able to predict ontogenetic transitions in continuous time or within fine scale time intervals. While this has not been viewed as a problem in the analyses to which PRNs have almost exclusively been applied to, i.e. age and size at maturation of fish stocks with an annual reproductive cycle (e.g. [12,13]), in the case of more rapid developmental processes, such as metamorphoses, obvious limitations arise
Summary
Reaction norms are a common tool for describing phenotypic plasticity in quantitative traits [1,2] as well as for understanding evolutionary processes at the level of life-histories [3]. For any two time points T1#T2 the probability of a transition event within the interval (T1, T2) is (P(T,T2)2P(T,T1))/(12P(T,T1)), where the probabilities are derived from the distribution function of T estimated by the parametric survival model (eqn 2).
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