A group of
genes that is found only in humans and arose in our ancestors 3–4 million years
ago may have driven the evolution of our bigger brains.
Why are human brains
so comparatively large?
This revelation — and
the work that led up to it — is the subject of two studies now reported in the
journal Cell.
One study was led by the University of
California (UC) Santa Cruz, and the other was
led by the Université Libre de
Bruxelles in Belgium.
The findings plug a
gap in our knowledge about the changes that drove the evolution of our larger
brains and gave us the ability to think and solve problems.
The genes — named
NOTCH2NL — belong to a very old family called Notch that was first identified
in fruit flies; they got their name because they were linked to genetic faults
that caused the flies to have notched wings.
How NOTCH2NL increases neuron numbers
Notch genes go back
"hundreds of millions of years" and "play important roles in
embryonic development," says David Haussler, who is a professor of
biomolecular engineering at UC Santa Cruz and co-senior author of the first
study paper.
"To find,"
he continues, "that humans have a new member of this family that is
involved in brain development is extremely exciting."
The researchers found
that the human-only NOTCH2NL genes appear to have a key role in the development
of the human cortex, the seat of advanced cognitive abilities such as reasoning
and language.
The genes are strongly
expressed in the neural stem cells of
the cortex and delay their maturation into specific cell types.
This delay results in
the accumulation of a larger pool of stem cells, which, in turn, leads to more
neurons being produced over the course of brain development.
Genes boost signaling during development
NOTCH2NL genes are
located on an area of the human genome — "the long arm of chromosome
1" — that has been linked to several neurodevelopmental disorders such
as autism, microcephaly, macrocephaly, and schizophrenia.
Some of the disorders
are linked to duplication of large sections of DNA, and some are linked to
deletions. They are known by their collective name "1q21.1
deletion/duplication syndromes."
The proteins coded by
the Notch gene family are concerned with signaling inside cells and also
between cells.
Many of these signals
direct the fate of stem cells — for instance, whether to differentiate into
brain cells or heart cells — in many parts of the body.
The researchers found
that the NOTCH2NL genes encode proteins that "enhance" Notch
signaling.
"Notch
signaling," explains co-senior study author Dr. Sofie R. Salama, who is a
research scientist in biomolecular engineering at UC Santa Cruz, "was
already known to be important in the developing nervous system."
"NOTCH2NL seems
to amplify Notch signaling, which leads to increased proliferation of neural
stem cells and delayed neural maturation," she adds.
'DNA copying errors'
However, Dr. Salama
points out that the genes are just part of a much larger process that controls
the development of the human cortex: they do not "act in a vacuum."
They came into play at
a "provocative time in human evolution." She and her colleagues also
found it interesting that the genes are associated with developmental
disorders.
It appears that the
"DNA copying errors" that occurred in our ancestors that gave rise to
the NOTCH2NL genes are of a similar type to those that give rise to
neurological disorders in 1q21.1 deletion/duplication syndrome.
Typically, the errors
happen in locations on chromosomes that have long sequences of DNA that are
"almost identical."
"These long
segments of DNA that are almost identical can confuse the replication machinery
and cause instability in the genome," Prof. Haussler explains.
Paradoxically, it
would appear that the gene duplication process in the chromosome 1 region that
gave us our bigger brains may also be responsible for making us vulnerable to
1q21.1 deletion/duplication syndrome.
Using sequencing
tools, the researchers found eight versions of NOTCH2NL in today's humans, and
they suspect that there are more to be discovered.
Each NOTCH2NL version
varies slightly in the sequencing of its DNA, but to what effect is still a
mystery.
The genes showed
subtle differences when tested in laboratory-grown cells. However, there is
still a "lot more work to do" to find out what these differences
mean, says Dr. Salama.
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