A recent study has upended a long-held assumption in biology: the idea that brain size increases proportionally with body size across all animals. While this relationship has been widely accepted for over a century, new research published in Nature Ecology and Evolution reveals that it is not as straightforward as once believed. The study shows that larger animals do not necessarily have proportionally larger brains, with humans being a significant exception to this rule.
For decades, scientists have worked under the assumption that there was a linear relationship between an animal’s brain size and its body size. This assumption has been foundational to many theories about animal intelligence, social behavior, and evolution. The basic idea was that as animals grew larger, their brains would increase in size at a consistent rate relative to their body.
However, there has been considerable debate about this assumption, particularly when it comes to large animals like elephants and whales, which have brains that seem disproportionately small compared to their massive bodies. The researchers aimed to resolve this controversy by conducting a comprehensive analysis across a wide range of mammalian species. They hoped to determine whether the relationship between brain and body size was indeed linear or if it followed a more complex pattern.
To explore this question, the researchers gathered a vast amount of data on brain and body sizes from over 1,500 species of mammals. This dataset included measurements of both brain mass and body mass, collected from a variety of sources. The researchers were meticulous in their efforts to ensure that the data were accurate and comparable across species. For instance, they prioritized brain mass measurements over brain volume, as mass is a more direct indicator of the amount of neural tissue. Additionally, they aimed to use data where both brain and body sizes were measured from the same individuals to ensure consistency.
With this data in hand, the researchers used advanced statistical models to analyze the relationship between brain and body size. These models allowed them to test whether the relationship was indeed linear or if it followed a different pattern. They also looked for variation in the rate of brain size evolution across different groups of mammals, such as primates, rodents, and carnivores. By doing so, they could identify which species followed the expected trend and which deviated from it.
Rather than finding a simple linear relationship between brain and body size, the researchers discovered that the relationship is actually a curve. This means that as animals become larger, their brains do not increase in size as quickly as their bodies do. In other words, very large animals have smaller brains than would be expected if the relationship were truly linear.
This finding was consistent across all the mammals studied, with some notable exceptions. For example, humans, primates, rodents, and carnivores all showed unique patterns of brain evolution. Humans, in particular, were found to be outliers, with brain sizes that have evolved much faster than those of other mammals. This rapid evolution has resulted in the large brains that characterize our species today.
“For more than a century, scientists have assumed that this relationship was linear – meaning that brain size gets proportionally bigger, the larger an animal is,” explained Chris Venditti, lead author of the study from the University of Reading. “We now know this is not true. The relationship between brain and body size is a curve, essentially meaning very large animals have smaller brains than expected.”
“Our results help resolve the puzzling complexity in the brain-body mass relationship,” added Rob Barton, co-author of the study from Durham University. “Our model has a simplicity that means previously elaborate explanations are no longer necessary – relative brain size can be studied using a single underlying model.”
The researchers also identified that bats, which are among the smaller mammals, have undergone rapid changes in brain size early in their evolution, but their brain sizes have remained relatively stable since then. This suggests that there may be evolutionary constraints related to the demands of flight that limit brain size in bats.
In contrast, the study found that three groups of mammals—primates, rodents, and carnivores—have consistently shown increases in brain size relative to their body size over time. This phenomenon is known as the Marsh-Lartet rule, which posits a trend toward increasing relative brain mass through time. However, this trend was not observed across all mammals, indicating that it is not a universal pattern as previously believed.
One of the most intriguing findings from the study is the identification of what the researchers called a “curious ceiling” in brain size. In the largest animals, there seems to be a limit preventing brains from getting too large. This ceiling might be due to the high energy costs associated with maintaining a large brain, though the exact cause remains unclear. Interestingly, similar patterns were observed in birds, suggesting that this phenomenon may be widespread among animals with very different biological makeups.
“Our results reveal a mystery,” said Joanna Baker, co-author of the study from the University of Reading. “In the largest animals, there is something preventing brains from getting too big. Whether this is because big brains beyond a certain size are simply too costly to maintain remains to be seen. But as we also observe similar curvature in birds, the pattern seems to be a general phenomenon – what causes this ‘curious ceiling’ applies to animals with very different biology.”
The study, “Co-evolutionary dynamics of mammalian brain and body size,” was authored by Chris Venditti, Joanna Baker, and Robert A. Barton.
