Performance of the SSI development function compared with 33 other functions applied to 79 arthropod species’ datasets

The development rates of arthropods are temperature-dependent. Studies aiming to predict the dynamics of arachnid, crustacean, and insect populations in nature often require the derivation of development functions representing this phenomenon. A previous study (Quinn, B.K., 2017, J. Therm. Biol. 63,...

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Bibliographic Details
Published in:Journal of thermal biology 2021-12, Vol.102, p.103112-103112, Article 103112
Main Author: Quinn, Brady K.
Format: Article
Language:English
Subjects:
Animals
Arachnida - growth & development
Arthropod
Arthropoda
Arthropods
Crustacea - growth & development
Development
Enzyme thermodynamics
Insecta - growth & development
Models, Biological
Sharpe-Schoolfield-Ikemoto (SSI) function
Species
Temperature
Thermodynamics
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Summary:The development rates of arthropods are temperature-dependent. Studies aiming to predict the dynamics of arachnid, crustacean, and insect populations in nature often require the derivation of development functions representing this phenomenon. A previous study (Quinn, B.K., 2017, J. Therm. Biol. 63, 65–77) identified 33 development functions commonly used in past studies on temperature-dependent development of arthropods, and illustrated that: (1) most of 99 past studies only applied one or few (2–5) development functions to their data without considering others; and (2) most of a subset of 79 studies’ data were not fit with the actual best function for them, resulting in sometimes substantial differences in model performance and predictive ability. However, that study did not test the class of development functions based on theoretical enzyme thermodynamics, including the Sharpe-Schoolfield-Ikemoto (SSI) function. Herein, the meta-analyses done in that previous study were redone, after fitting all 79 reanalyzed datasets with the SSI function. Estimates of the intrinsic optimum temperature (TΦ) for development of each tested species were also derived using the SSI function and compared among taxa. Including the SSI function in analyses did not change the conclusions of the previous study concerning development function usage, choice, and consequences. Notably, the SSI function performed as well as or relatively better than other functions of comparable or lower complexity in terms of R2, AICC-based rankings, ΔAICC values, and prediction errors, which may recommend its more widespread use in future studies. Overall differences in TΦ were found among arthropod subphyla, as well as between most species pairs. Most TΦ estimates produced herein were novel, and could be used to make inferences about or comparisons among arthropod taxa in future studies. •A previous meta-analysis of temperature-dependent development functions was redone.•The thermodynamic Sharpe-Schoolfield-Ikemoto (SSI) function was added to analyses.•Overall conclusions of the past study were not changed by addition of the SSI function.•The SSI function performed well, despite its complexity and generated useful data.•This function estimated 79 arthropods' intrinsic optimum development temperatures.
ISSN:0306-4565
1879-0992
DOI:10.1016/j.jtherbio.2021.103112