How similar are you to a chimpanzee?
Chimpanzees and humans turn out to be very similar—if you look at their DNA. When scientists determined the entire genetic code of both humans and chimpanzees, they found that we have over 98% identical DNA.
Arguably, some of the best evidence of evolution comes from examining the molecules and DNA found in all living things.
Beginning in the 1940s, scientists studying molecules and DNA have confirmed conclusions about evolution drawn from other forms of evidence.
are used to determine how closely two species are related by calculating the number of differences between the species' DNA sequences or amino acid sequences. These clocks are sometimes called gene clocks or evolutionary clocks. The fewer the differences, the less time since the species split from each other and began to evolve into different species (
). For example, a chicken and a gorilla will have more differences between their DNA and amino acid sequences than a gorilla and an orangutan. That means the chicken and gorilla had a common ancestor a very long time ago, while the gorilla and orangutan shared a more recent common ancestor. This provides additional evidence that the gorilla and orangutan are more closely related than the gorilla and the chicken.
Almost all organisms are made from DNA with the same building blocks. The genomes (all of the genes in an organism) of all mammals are almost identical.
, or all the genes of an organism, have been determined for many different organisms. The comparison of genomes provides new information about the relationships among species and how evolution occurs (
Molecular evidence for evolution also includes:
The same biochemical building blocks, such as amino acids and nucleotides, are found in all organisms, from bacteria to plants and animals.
DNA and RNA determine the development of all organisms.
The similarities and differences between the genomes confirm patterns of evolution.
This is a map of the genes on just one of the 46 human chromosomes. Similarities and differences between the genomes (the genetic makeup) of different organisms reveal the relationships between the species.
: All the genes of an organism.
: Procedure used to determine how closely two species are related by calculating the number of differences between the species' DNA sequences or amino acid sequences.
Molecular clocks are used to determine how closely two species are related by calculating the number of differences between the species' DNA sequences or amino acid sequences.
Molecular evidence for evolution includes that all living things share the same biochemical building blocks.
Use the resources below to answer the questions that follow.
How is the genetic sequence of an organism like a blueprint of that organism?
If two organisms have almost identical sequences for the same gene, are they considered closely related? Why or why not?
What type of animal have scientists long thought was basal to all other animals? How has genetic analysis affected this view?
How has genetic analysis become quicker than it once was? How has that greatly helped with the search for a basal organism?
What is a regulatory gene? How might they explain differences between organisms?
What are "hox genes"? What phase of development are they a part of? What organisms have hox genes?
If you find a fly with a leg coming out of its head and can identify what happened genetically to cause this, what have you discovered?
How old do scientists think hox genes are?
Explain how scientists use a molecular clock to determine relationships between species.
What is some of the molecular evidence for evolution?