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Decoding the dogma of DNA similarity

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Chimp photo by Kelly Stroud Blue prints
Spot the chimp! (Hint: Chimps don’t use mobile phones.)

The October 2006 issue of Time Magazine asked a critical question about chimpanzees and humans: what makes us different?1 The evolutionary community commonly touts a 98–99% DNA similarity between humans and chimps as incontrovertible proof of a recent common ancestor. This seemingly high percentage of genetic similarity has served to bolster public faith in Darwinian evolution and to put creationists on the defensive. Biblical creationists and intelligent design theorists explain this similarity as due to common design. This an argument from analogy: human designers are observed utilizing common design blueprints to create technology that possesses similar design features, yet having distinct identities and functions. Even evolutionary anthropologist Owen Lovejoy stated, ‘It’s like having the blueprints for two different brick houses. The bricks are the same, but the results are very different.’1 However, there are some, even within the creationist community, that believe this common design argument is insufficient in classifying living creatures and explaining the high level of genetic similarity between humans and chimpanzees.2

This article compares and contrasts chimpanzees and humans, analyzes a number of lesser known genetic studies, discusses relatively unknown aspects of the chimpanzee genome and compares chimpanzees with other animals’ human-like attributes.

Chimp and human similarities

Chimps look more like us than any other animal. In overall anatomy, they are our closest match. They are intelligent animals, capable of solving problems, making and using simple tools, and passing on knowledge to their offspring. They establish complex social relationships, show special concern for their young, and are self-aware. With the benefit of intense human instruction, chimpanzees have learned some basic sign language and have even been taught crude artistic skills (perhaps). They appear to possess the greatest degree of genetic similarity to mankind. At face value, these similarities seem to corroborate evolutionary notions about human origins.

Chimp and human differences

However, there are some extremely significant differences between chimps and humans. Our skeletal anatomy, though bearing some similarity, is very different. Our skulls, necks, spines, limb proportions, pelvis, hands, and feet provide some of the most glaring differences. Our soft tissue arrangements also create a stark contrast in external appearance (e.g., everted lips, nasal bridge, whites of eyes). Some of our protein expression and brain biochemistry are radically different as well.

Perhaps the most profound differences come in areas such as language, art, music, mathematics, technology, philosophy, animal husbandry, agriculture, and a moral and spiritual capacity. This is powerful confirmation of the Genesis account in which human beings alone are created in the image of God. We are not highly evolved apes.

Different studies claim different percentages of DNA similarity

Although we are frequently told that chimps and humans share between 98–99% of their DNA, a number of studies reveal a smaller percentage of similarity. A 2002 study in the Proceedings of the National Academy of Sciences (PNAS) analyzed about one million DNA base pairs and discovered an approximately 95% similarity.3 The human genome is composed of about 3 billion base pairs, so this comparison involved less than 1% of the genome, but it was of sequences already considered to be common to chimps and humans (‘homologous’). A 2003 study, also in the PNAS, compared about 1.9 million base pairs in immunologically critical areas of the chimp and human genomes. This study took into account insertions and deletions (indels) and derived a low 86.7% similarity.4 When the chimpanzee genome was mapped in 2005, scientists announced a 96% similarity.5 Another study, in 2006, revealed a 94% genetic similarity.6 Obviously, these results are all considerably lower than the still widely touted 98–99% statistic. These different studies reveal that the degree of genetic similarity is highly dependent on the particular regions being analyzed, the amount of DNA being compared and the computational techniques used.

The 2006 study claiming a 94% similarity creates a big problem for evolutionary geneticists who just sequenced the Rhesus macaque genome and declared a 93% DNA similarity between these monkeys and human beings.7 It is highly problematic because these monkeys supposedly branched off from our common ancestor about 25 million years ago, while chimpanzees supposedly diverged about 6 million years ago. So we have supposedly diverged from chimps some four times faster than we have diverged from Rhesus monkeys. Simply stated, there should be a more significant gap between humans and the monkeys if evolution and its dating were true.

Many uncertainties surround the recently sequenced chimpanzee genome

In 2005, scientists announced that the entire chimpanzee genome had been successfully sequenced and it had confirmed evolutionary predictions (of course!). However, there are critical flaws to this declaration.8

First, the chimpanzee genome was not built from scratch. In a likely bid to save money and time, it was assembled using the human genome as a scaffold. This also reveals the evolutionary presuppositions of the scientists who started the genome project with the critical assumption that humans and chimps are close evolutionary cousins and would tend to bias the results towards greater similarity.

Second, the chimp genome is about 12% larger than the human genome. At the risk of sounding overly simplistic, this would seem to indicate at most an 88% DNA similarity from the outset. How was this 12% difference taken into account in the overall percentage similarity, or was it ignored?

Third, chimpanzees possess many genes not present in the human genome. They also lack many genes that are present in the human genome. How were these differences included, or were they?

Fourth, by evolutionary reckoning there were millions of ‘rearrangements’ in the chimp genome. How did scientists calculate this dissimilarity?

Finally, there are many unknown regions in the chimpanzee genome. Much of the neglected non-protein-coding regions still need to be carefully studied, since geneticists continue to discover more and more critical functions in so-called ‘junk DNA’. Roles for this DNA are rapidly being discovered. Much of this is now known not to be junk at all, but is involved in such things as orchestrating embryo development.9

These are exciting questions for creationist geneticists to investigate without the constraints of the stifling evolutionary paradigm. It is quite possible that improved technology and further research into these critical areas of the chimpanzee genome will reveal even more substantial differences.

DNA similarity may be grossly overrated

Last year, scientists discovered that bats and horses shared a higher degree of DNA similarity than cows and horses—see Saddle up the horse, it’s off to the bat cave. You could hardly find two more distinct placental mammals than bats and horses, yet in contrast to evolutionary predictions based on comparing anatomy, they shared a greater genetic similarity than did horses and cows. This may have major implications for the chimpanzee-human DNA similarity as well. Despite possessing some common anatomy and a high percentage of DNA, chimpanzees are radically different from human beings in a significant number of ways. They are also rivaled and even surpassed by numerous other animals in human-like attributes such as intelligence, linguistics, emotional and social capacity, and behavioral compatibility with mankind—see Primates spearing primates.

Competition from other animals

Gibbons are considered to be farther removed from humans on the evolutionary tree, yet they are more human-like in their bipedal gait than any other ape.10 This is surprising, since compared to chimps, their skeletal anatomy is even more different from humans. Elephants ‘bury’ their dead with vegetation and pay special attention to the bones and bodies of other long dead elephants—see Jumbo minds. Chimpanzees don’t bury their dead, and they leave once the corpse begins to rot. One elephant has even managed to speak eight human words in a South Korean zoo, and several Thai elephants have been taught to paint in full view of zoo enthusiasts. And elephants have accomplished these feats with a relative brain size that is about one-quarter that of chimpanzees. A couple of parrots have developed a more advanced, human-like linguistic capacity compared to the sign language abilities taught to chimpanzees. New Caledonian crows have proven to be superior tool designers to chimpanzees when hunting for food. Woodpecker finches snap off small pieces of cacti to spear insects, just like chimps that bite off the ends of sticks to make spear-like objects in order to kill bushbabies. In some experiments, pigs have even tested as more intelligent than many chimpanzees, and they can even be trained to herd sheep.11

Despite chimpanzees sharing significant genetic similarity with humans, we rely on a whole host of other animals to perform vital tasks such as searching for mines and bombs, transporting large quantities of cargo and supplies, and aiding the disabled. In addition, chimpanzees have been the recipients of countless hours of intense human training and conditioning, yet they remain quite disappointing in their human-like capacities. All of this contrasts strongly with the claimed high degree of DNA similarity and superficial anatomical similarity.

Published: 6 June 2007

References

  1. Lemonick, M. and Dorfman, A.. What makes us different? Time, http://www.time.com/time/magazine/article/0,9171,1541283,00.html. 1 October 2006. Return to Text.
  2. Wood, Todd. The Chimpanzee Genome and the Problem of Biological Similarity. Occasional Papers of the BSG. Number 7. 20 February 2006. Return to Text.
  3. Brittin, R. Divergence between Samples of Chimpanzee and Human DNA Sequences is 5%, Counting Indels, Proceedings of the National Academy of Sciences, USA 99 (2002): 13633–35. Return to Text.
  4. Tatsuya, A., et al., Comparative Sequencing of Human and Chimpanzee MHC Class I Regions Unveils Insertions/Deletions As the Major Path to Genomic Divergence, Proceedings of the National Academy of Sciences, USA 100 (2003): 7708–13. Return to Text.
  5. Boyle, A., Chimp genetic code opens human frontiers. MSNBC Science & Technology, http://www.msnbc.msn.com/id/9136200/ 01 September 2005. Return to Text.
  6. Minkel, J.R., Human-Chimp Gene Gap Widens from Tally of Duplicate Genes. ScientificAmerican.com, http://www.sciam.com/article.cfm?articleID=9D0DAC2B-E7F2-99DF-3AA795436FEF8039. 19 December 2006. Return to Text.
  7. Choi, C., Monkey DNA points to common human ancestor. Livescience, http://www.livescience.com/humanbiology/070412_rhesus_monkeys.html. 12 April 2007. Return to Text.
  8. E-mail communication with creationist geneticist Dr. Rob Carter. Return to Text.
  9. Batten, D., No joy for junkies, Journal of Creation 19(1):2, 2005. Return to Text.
  10. Sodera, V., One small speck to man. Vij Sodera Productions, UK, 2003, p. 386. Return to Text.
  11. Ref. 10. p. 424. Return to Text.