Max Planck Institute of Molecular Cell Biology and Genetics (MPI-CBG), Central Institute for Experimental Animals and Keio University researchers injected the gene ARHGAP11B – the code responsible for directing stem cells in the human brain- into the dark matter of marmoset foetuses. And the scientists discovered the primates’ more basic brains swiftly became more human-like.
They specifically developed significantly advanced neocortexes, areas controlling both cognition and language.
According to images published in the journal Science, the modified monkey brains almost doubled in size after almost 100-days into gestation.
Dr Michael Heide, the study’s lead author, said: “We found indeed that the neocortex of the common marmoset brain was enlarged and the brain surface folded.
“[We also saw] increased numbers of upper-layer neurons, the neuron type that increases in primate evolution.”
This is a cutting-edge technique using embryonic stem cells to contribute to the reproductive cells of a mammal (germ cells) genetically passed to an offspring.
Dr Wieland Huttner at MPI-CBG and study author, said in a statement: “We confined our analyses to marmoset fetuses because we anticipated that the expression of this human-specific gene would affect the neocortex development in the marmoset.
“In light of potential unforeseeable consequences with regard to postnatal brain function, we considered it a prerequisite – and mandatory from an ethical point of view – to first determine the effects of ARHGAP11B on the development of foetal marmoset neocortex.”
ARHGAP11B arose through a partial duplication of the closes-related gene ARHGAP11A approximately five million years ago along the evolutionary lineage leading to Neanderthals, Denisovans, and their modern-day ancestors – us.
Researchers isolated different sub-populations of human brain stem cells and identified which genes are active in which cell type.
Tests at the time on mouse embryos revealed that the gene can have a huge impact on brain development.
ARHGAP11B, when expressed in mice to unphysiologically high levels, causes a vastly expanded neocortex.
Embryos injected with the gene grew larger brain regions and some developed the wrinkled surface that’s characteristic of the human brain.
Dr Marta Florio at MPI-CBG, a fellow lead author, said in a statement: “It is so cool that one tiny gene alone may suffice to affect the phenotype of the stem cells, which contributed the most to the expansion of the neocortex.”