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Written by Peter Frost.
You’ve probably heard that humans and chimpanzees are
genetically 98 to 99% the same. You’ve probably also heard that human
populations are 99.9% the same. The second finding has often been cited, for
example by Hillary Clinton. In a speech to high school graduates, the former
First Lady mentioned “genetic research that shows humans are 99.9 percent the
same”.
The differences in how we look — in our skin color, our
eye color, our height — stem from just one-tenth of 1 percent of our genes.
And the differences among us — our cultures, our religious beliefs, the music
we like — it is all so small a distinction in our sea of common humanity.
Of course, one tenth of one percent is still a lot. In a
post criticizing Clinton’s speech, anthropologist John Hawks observed that
“one-tenth of 1 percent of 3 billion is a heck of a large number — 3 million
nucleotide differences between two random genomes” (Hawks, 2007). He added, “We differ by one-tenth of 1
percent of nucleotides, this is enough to make coding differences in a large fraction of our genes.”
In other words, the 0.1% figure is not the percentage of
genes that are different. It’s the percentage of individual nucleotides that
are different. A single gene is a long chain of nucleotides, often a very long
one, and a single nucleotide mutation can significantly alter how the entire
gene works. In theory, then, each and every human gene could work differently
from one population to another.
Moreover, as Hawks himself showed in a study published the
same year, at least 7% of the human genome has changed over the last 40,000
years — mostly the last 10,000 (Hawks et al., 2007). This was when our ancestors were
spreading over the globe and differentiating into today’s geographic populations. Those populations cannot all share the same 7% change.
Clearly, 0.1% isn’t the fraction of genes that
differ among human populations. The true figure is certainly larger. Again,
each and every gene could differ among human populations by 0.1%, and such a difference could affect how each and every one functions. Also, genes do not
differ solely in nucleotide sequences. They also differ in the way those
sequences are arranged on the chromosomes. The same sequence may be repeated
consecutively or it may be copied and inserted somewhere else. Such
rearrangements can likewise affect how a gene functions. “Structural
variations, such as copy-number variation and deletions, inversions,
insertions and duplications, account for much more human genetic variation
than single nucleotide diversity” (Wikipedia, 2025).
This structural variation became apparent during the first
complete sequencing of a human genome:
Of the 4.1 million variations between chromosome sets, 3.2
million were SNPs, while nearly one million were other kinds of variants,
such as insertion/deletions (“indels”), copy number variants, block
substitutions, and segmental duplications. While the SNPs outnumbered the
non-SNP types of variants, the non-SNP variants involved a larger portion of
the genome. This suggests that human-to-human variation is much greater than
previously thought. (Phys.org, 2007; see also Levy et al., 2007)
If we return to comparing humans and chimpanzees, we can
measure the total genetic difference between them by looking at what the
genes make, i.e., proteins. The two species differ in about 80% of their
proteins — a figure far higher than the 1 to 2% difference in their
nucleotide sequences (Glazko et al., 2005).
Even this 80% figure is not the whole story. Some genes
regulate how other genes are expressed, often thousands of others, and thus
play a key role in growth and development. These “regulator” genes are much
fewer in number than other genes but far greater in their effects. Plus, they
differ much more between humans and chimpanzees than other genes do. Whereas
the two species are almost identical in the nucleotide sequences of their
genes and the amino acid sequences of their proteins, and relatively similar
in the proteins that make up their tissues, they differ radically in the way
their tissues grow and develop, notably the neural tissues of the brain.
This was already clear to two researchers, Mary-Claire
King and A.C. Wilson, when, half a century ago, they discovered the startling
similarity of nucleotide sequences and amino acid sequences between humans
and chimpanzees:
The molecular similarity between chimpanzees and humans is
extraordinary because they differ far more than sibling species in anatomy
and way of life. Although humans and chimpanzees are rather similar in the
structure of the thorax and arms, they differ substantially not only in brain
size but also in the anatomy of the pelvis, foot, and jaws, as well as in
relative lengths of limbs and digits. Humans and chimpanzees also differ
significantly in many other anatomical respects, to the extent that nearly every bone in the body of a chimpanzee is readily distinguishable in shape or
size from its human counterpart. Associated with these anatomical differences
there are, of course, major differences in posture, mode of locomotion,
methods of procuring food, and means of communication. Because of these major
differences in anatomy and way of life, biologists place the two species not
just in separate genera but in separate families …
The contrasts between organismal and molecular evolution
indicate that the two processes are to a large extent independent of one
another. Is it possible, therefore, that species diversity results from
molecular changes other than sequence differences in proteins? … According to
this hypothesis, small differences in the time of activation or in the level
of activity of a single gene could in principle influence considerably the
systems controlling embryonic development. The organismal differences between chimpanzees and humans would then result chiefly from genetic changes in a
few regulatory systems, while amino acid substitutions in general would
rarely be a key factor in major adaptive shifts. (King & Wilson, 1975, pp. 113–114)
Genetic distance between humans and chimpanzees, compared
to genetic distances in other taxa. (King & Wilson, 1975, p. 113)
In this context, the two researchers were thinking not
only about the human-chimpanzee difference but also about the differences
within our species:
[The human-chimpanzee] distance is 25 to 60 times greater
than the genetic distance between human races. In fact, the genetic distance
between Caucasian, Black African, and Japanese populations is less than or
equal to that between morphologically and behaviorally identical populations
of other species. (King & Wilson, 1975, p. 113)
The above paragraph appears in the middle of a discussion
about the human-chimpanzee genetic d istance, and its paradoxical smallness.
In fact, the two researchers highlight this paradox right after:
However, with respect to genetic distances between
species, the human-chimpanzee D value is e xtraordinarily small, corresponding
to the genetic distance between sibling species of Drosophila or mammals. Nonsibling species within a genus … generally differ more from each
other, by e lectrophoretic criteria, than humans and chimpanzees. The genetic
distances among species from different genera are considerably larger than
the human-chimpanzee genetic distance. (King & Wilson, 1975, p. 113)
How should we measure the genetic
distance between two human populations? There is no easy answer because few
species resemble our own. Our species is unusual in that it evolved rapidly
at the very time it was splitting up into populations across different environments
— not only natural environments from the equator to the arctic but also an
ever-wider range of cultural environments. In fact, this entry into so many
environments largely explains the concurrent rapidity of human genetic
evolution. Natural selection has thus shaped human populations in highly
divergent ways (Akbari et al., 2024; Cochran & Harpending, 2009; Frost, 2023a; Hawks et al., 2007; Kuijpers, et al., 2022; Libedinsky et al., 2025; Piffer & Kirkegaard, 2024; Rinaldi, 2017).
In such a situation, differences in selection contribute
much more to genetic diversity between populations than to genetic diversity
within populations. Keep in mind that natural selection causes a population
to diversify only in certain limited cases (e.g., frequency-dependent
selection). In most cases, a population is diversified by stochastic
processes of little adaptive consequence, since everybody is adapting to the
same environment and the same selection pressures.
We thus return to the same paradox: Fst is relatively low
in our species even though human populations differ much more anatomically
than do most sibling species in the animal kingdom. As Charles Darwin noted,
a naturalist would consider some human groups to be “as good species as many
to which he had been in the habit of affixing specific names.” The paradox
exists because humans split rapidly to colonize highly divergent
environments, with the result that genetic diversity between populations is much more consequential than genetic diversity within populations. We are
therefore comparing apples to oranges when we calculate human Fst (Darwin,
1936 [1888], pp. 530-531; King & Wilson, 1975; Frost, 2023b).
What’s more, relatively little of our evolution has been
at the level of nucleotide sequences or amino acid sequences. It has been
largely at a higher level — the duplication, rearrangement and regulation of existing DNA in new ways (Yoo et al., 2025). This point came up in a recent
discussion on X:
The widely cited Chimpanzee-Human 98-99% DNA similarity
figures refer exclusively to nucleotide s equence similarity within alignable
genomic regions, which become misleading when portrayed as the t otal amount
of DNA shared. While this metric is important, as it highlights the strength
of the evolutionary constraints within the protein-coding and non-coding
sequences found in alignable r egions, it ignores the structural and
regulatory differences that are key for shaping the phenotypic differences
between Chimpanzees and Humans. When combining these metrics, total Chimpanzee-Human DNA similarity figures drop to ~84.7% (Origins Unveiled, 2025)
Admittedly, I have no idea how the author combined these
metrics.
I don’t blame Hillary Clinton for drawing the wrong
conclusion from the 99.9% estimate, but I’m less forgiving toward those who
have silently gone along with this fallacy while knowing better. Two decades
ago, John Hawks pointed out its flaws in a post criticizing Hillary’s speech.
The post remained on his website until he deleted it in 2021 — when many
American academics got the memo that Hillary had been right all along… on
this issue and on any other.
“Nice research lab you have there. Pity if anything
happened to it.”
When academics choose the path of silence, and withhold
their objections, they help create a fake consensus that ultimately brings
academia into disrepute.
Peter Frost has a PhD in anthropology from Université
Laval. His main research interest is the role of sexual selection in shaping
highly visible human traits. Find his newsletter here.
References
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M., Perry, A., Zeng, Y., Mittnik, A., Patterson, N., Mah, M., Zhou, X.,
Price, A.L., Lander, E.S., Pinhasi, R., Rohland, N., Mallick, S., &
Reich, D. (2024). Pervasive findings of directional selection realize the
promise of ancient DNA to elucidate human adaptation. bioRxiv. https://doi.org/10.1101/2024.09.14.613021
Anon. (2007). Finding said to show “race isn’t real”
scrapped http://www.world-science.net/othernews/070904_human-variation.htm
Cochran, G. & Harpending, H. (2009). The
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Frost’s Newsletter, July 12.
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