Evolution of Developmental Timing as a Driving Force of Brain Diversity

Suárez, Rodrigo; Halley, Andrew C

doi:10.1159/000524334

Cited by 3 publications

(2 citation statements)

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“…Because neurodevelopmental differences are key to generating much of the diversity evident in the brains and bodies of mammals [83], opossums can be a powerful animal model for studying the diversity of extant mammals. Also, because short-tailed opossums are considered to be a relatively evolutionarily conserved mammal that may qualitatively resemble a basal eutherian in both brain and body morphology (for review and caveats, see [84,85]), studying this species can give unique insights into mammalian evolution (e.g., [13,14,[86][87][88]).…”

Section: Discussionmentioning

confidence: 99%

Translating the Timing of Developmental Benchmarks in Short-Tailed Opossums (Monodelphisdomestica) to Facilitate Comparisons with Commonly Used Rodent Models

Bresee,

Litman-Cleper,

Clayton

et al. 2024

Brain Behav Evol

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Introduction: The gray short-tailed opossum, Monodelhis domestica (M. domestica) is a widely used marsupial model species that presents unique advantages for neurodevelopmental studies. Notably their extremely altricial birth allows manipulation of postnatal pups at timepoints equivalent to embryonic stages of placental mammals. A robust literature exists on the development of short-tailed opossums, but many researchers working in the more conventional model species of mice and rats may find it daunting to identify the appropriate age at which to conduct experiments. Methods: Here we present detailed staging diagrams taken from photographic observations of 40 individual pups, in 6 litters, over 25 time points across postnatal development. We also present a comparative neurodevelopmental timeline of short-tailed opossums, the house mouse (Mus musculus), and the laboratory rat (Rattus norvegicus) during embryonic as well as postnatal development, using time points taken from this study and a review of existing literature, and use this dataset to present statistical models comparing the opossum to the rat and mouse. Results: One aim of this research is to aid in testing the generalizability of results found in rodents to other mammalian brains, such as the more distantly related metatherians. However, this broad dataset also allows the identification of potential heterochronies in opossum development compared to rats and mice. In contrast to previous work, we found broad similarity between the pace of opossum neural development with that of rats and mice. We also found that development of some systems was accelerated in the opossum, such as the forelimb motor plant, oral motor control, and some aspects of the olfactory system, while the development of the cortex, some aspects of the retina, and other aspects of the olfactory system are delayed compared to the rat and mouse. Discussion: The pace of opossum development is broadly similar to that of mice and rats, which underscores the usefulness of this species as a compliment to the more commonly used rodents. Many features that differ the most between opossums and rats and mice were either clustered around the day of birth and were features that have functional importance for the pup immediately after or during birth, or were features that have reduced functional importance for the pup until later in postnatal development, given that it is initially attached to the mother.

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Section: Discussionmentioning

confidence: 99%

Translating the Timing of Developmental Benchmarks in Short-Tailed Opossums (Monodelphisdomestica) to Facilitate Comparisons with Commonly Used Rodent Models

Bresee,

Litman-Cleper,

Clayton

et al. 2024

Brain Behav Evol

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“…The model provides insight into further debated questions. Variation in the timing of brain development at molecular, cellular, and histological levels has been proposed to lead to evolution of brain diversity [80][81][82] . Our results are consistent with these views.…”

Section: Discussionmentioning

confidence: 99%

Evo-devo dynamics of hominin brain size

González-Forero

2023

Preprint

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Brain size tripled in the human lineage over four million years, but why this occurred remains uncertain. To advance our understanding of what caused human-brain expansion, we mechanistically replicate it in-silico by modelling the evolutionary and developmental (evo-devo) dynamics of human-brain size. We show that, starting from australopithecine brain and body sizes, the model recovers major patterns of human development and evolution, the evolution of the hominin brain-body allometry, and the evolution of brain and body sizes of six Homo species. Analysis reveals that in this model the brain expands because ecology and seemingly culture make brain and developmentally late reproductive tissue sizes socio-genetically covariant. The direction of brain expansion is nearly orthogonal to the direction favoured by unconstrained selection. In contrast to long-held views, in this model, unconstrained selection that does not favour brain expansion provides a force that developmental constraints divert to cause human-brain expansion.

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