Here's how the brain evolved
Washington D.C, Feb 13 : Don't we all, at some point or the other, wonder where does our 'humanness' come from?
A new research, conducted by researchers from the Salk Institute have developed a strategy to more easily study the early development of human neurons compared with the neurons of nonhuman primates.
The study, which appeared in eLife on February 7, 2019, offers scientists a novel tool for fundamental brain research.
Speaking on it, senior author Rusty Gage said, This study provides insights into the developmental organization of the brain and lays the groundwork for further comparative analyses between humans and nonhuman primates.
Two important processes in brain development include neuron maturation and migration. Maturation involves neuron growth as the neurons increase their connections between each other for better communication. Migration is the physical movement of neurons into different parts of the developing brain. The authors sought to compare neuron maturation and migration between humans and nonhuman primates.
To accomplish this task, the Gage lab devised a new method utilising stem cell technology to take skin cells from primates and coax them, via a virus and chemical cocktails, to develop into neural progenitor cells, a cell type that has the ability to become multiple types of cells in the brain, including neurons.
These new primate cell lines can then be perpetually propagated, allowing researchers new avenues to study aspects of neuronal development of live neurons without tissue samples from endangered primates such as chimpanzees and bonobos.
Co-first author Carol Marchetto said, This is a novel strategy to study human evolution.
We are happy to share these primate cell lines with the scientific community, so that researchers from around the world can examine primate brain development without the use of tissue samples. We anticipate this will lead to numerous new findings over the next few years about the brain's evolution, Marchetto added.
The researchers first explored the differences in gene expression related to neuronal movement, comparing human, chimpanzee and bonobo cells. They also investigated the migration properties of the neurons inherent to each species. They found 52 genes related to migration, and, interestingly, chimpanzee and bonobo neurons had periods of rapid migration, while human neurons were slow to move.
The scientists transplanted the neural progenitor cells from both humans and chimpanzees into the brains of rodents, enabling the neurons to thrive and providing additional developmental cues for the neurons to develop.
The researchers then analysed the differences in migration distance, shape and size of the neurons for up to 19 weeks after transplantation. They observed the length, density and quantity of extensions of the neurons called dendrites, as well as the size of the cell bodies, which house the nucleus and DNA.
The chimpanzee neurons migrated a greater distance and covered a 76 per cent greater area than the human neurons after two weeks. Human neurons were slower to develop but reached longer lengths than the chimpanzee neurons. This slower growth pattern may allow humans to reach more developmental milestones than nonhuman primates, which could account for differences in behaviour and cognitive abilities.
In the future, the authors hope to construct an evolutionary tree of multiple primate species, utilising induced pluripotent stem cell lines, to better understand of the evolution of the human brain. In addition, the authors plan to use this platform to study gene regulation differences between primate species that underlie the differences in neuronal maturation and can potentially impact brain organization in humans.
We have limited knowledge about the evolution of the brain, especially when it comes to differences in cellular development between species, says Marchetto. We're excited about the tremendous possibilities this work opens up for the field of neuroscience and brain evolution.