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The theory of evolution was and continues to be a highly controversial topic because it challenges so many spiritual beliefs. We will review the definition of evolution, then discuss different lines of evidence supporting the theory of evolution. We will also discuss what fossils and archaeological evidence tell us about human evolution.
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Jetzt kostenlos anmeldenThe theory of evolution was and continues to be a highly controversial topic because it challenges so many spiritual beliefs. We will review the definition of evolution, then discuss different lines of evidence supporting the theory of evolution. We will also discuss what fossils and archaeological evidence tell us about human evolution.
Evolution is a gradual and cumulative change in the heritable traits of a population of organisms.
It is mainly driven by natural selection, a process where individuals with traits that help them survive in their environment are able to reproduce more because of those traits. This change takes place over the course of many generations.
The theory of evolution is supported by a wide range of evidence including fossils, homology, molecular biology, biogeography, and direct observations. In this section, we will discuss each line of evidence and provide examples.
Fossils are preserved remnants or traces of organisms from a past geologic age. Fossils provide evidence that life forms have changed over time and resulted in the diversity in life forms that we see today. Fossils show how organisms evolved, how new groups of organisms emerged, and how some species became extinct (Fig. 1).
Fossils show patterns in the changes caused by evolution in different groups of organisms. For example, the pelvic bone in fossil stickleback fish consistently became smaller over time. The consistent shrinking of the pelvic bone is a pattern that suggests natural selection was the driving force behind the change.
Fossils also show how new groups of organisms emerge. For example, fossils provide evidence that cetaceans (an order of marine mammals that includes whales, dolphins, and porpoises) evolved from terrestrial mammals like hippopotamuses, pigs, and cows (Figs. 2-3). This is because fossils show that the pelvis and hind limb bones of extinct cetacean ancestors became smaller over time, eventually disappearing completely and developing into flukes and flippers.
Figures 2-3. Fossils show that the hippopotamus (left) is the closest living relative of the whale (right). Source (left): Diego Delso, CC BY-SA 4.0, via Wikimedia Commons. Source (right): Gabriel Barathieu, CC BY-SA 2.0, via Wikimedia Commons.
Similarities in the structure or development of different life forms (known as homology) also provide evidence of evolution because these show:
How different species with similar structures can be traced back to common ancestors (divergent evolution)
How different species with similar structures but no recent common ancestors were subjected to common selection pressures (convergent evolution)
Divergent evolution is the type of evolution where a species changes over time and branches off into new distinct species.
Species that share a recent common ancestor can have homologous structures: similar structures shared by closely related species. Homologous structures appear similar but serve different functions (Fig. 4).
For example, vertebrates like pigs, birds, and whales have forelimbs with the same basic composition that came from a common ancestor. Their forelimbs changed over time to serve different purposes that suit their present environment.
On the other hand, species that are not closely related have also evolved with similar physical characteristics due to common selection pressures. This process is called convergent evolution. For example, birds, bats, and pterodactyls all have wings that can be used for flight even though they are not closely related (Fig. 5).
All life forms share the same genetic material. From bacteria to humans, all life forms have DNA, as well as its mechanism for replication and expression (Figs. 6-7). This suggests that all species came from a very distant common ancestor.
Figure 6-7. Bacteria (left) and humans (right) have DNA as their genetic material. Source (left): Mark Amend - NOAA Photo Library, Public domain, via Wikimedia Commons. Source (right): Reinhold Möller, CC BY-SA 4.0, via Wikimedia Commons.
We can also observe patterns in the geographic distribution of life forms on Earth (a branch of biology called biogeography). These patterns can be explained by evolution alongside the movement of tectonic plates.
For example, members of the plant family Proteaceae are found in Australia, southern Africa, and South America, which are all distant from each other. The presence of Proteaceae in these areas can be explained by their descent from a common ancestor that existed in the supercontinent Gondwana before it broke up into different landmasses (Fig. 8).
Evolution can also explain why islands tend to have many endemic plant and animal species. Endemic species are native to a specific geographical area and do not occur naturally elsewhere. Darwin proposed that species from the nearest mainland colonized islands and eventually evolved into new species as they adapt to their environments. The finches on the Galapagos Islands are an example of this.
Evidence of evolution can also be observed directly in species with fast reproductive cycles, such as bacteria.
For example, when bacteria are exposed to antibiotics, individuals with no resistance quickly die off. Individuals with resistance to the antibiotic are able to survive and reproduce. Then, resistant traits are passed on to more individuals in the population. Eventually, the population becomes more resistant to antibiotic treatment.
Evolution by natural selection can also be observed in species that evolve as a response to introduced species in their environment. An example of this is the different beak lengths of the soapberry bug which evolved according to the available food source. In Southern Florida, soapberry bugs feed on the seeds of the native balloon vine. In Central Florida, balloon vines (Fig. 9) have become rare, so soapberry bugs shifted to the seeds of the golden rain tree (Fig. 10)–an introduced species—as their food source.
Figures 9-10. The seeds of the balloon vine fruit are farther from the surface than the seeds of the golden rain tree fruit (right). Source (left): H. Zell, CC BY-SA 3.0, via Wikimedia Commons. Source (right): Art Davis, CC BY-SA 4.0, via Wikimedia Commons.
Soapberry bugs can feed more effectively when their beak is long enough to reach the seeds within a fruit. Because seeds of the golden rain tree fruit are closer to the surface than the seeds of the balloon vine, soapberry bugs that feed on the seeds of the golden rain tree have shorter beaks. In Louisiana, Oklahoma, and Australia, soapberry bug populations feed on introduced plants that have fruits larger than those of the balloon vine. In these areas, soapberry bugs evolved to have longer beaks.
Humans are Homo sapiens, a primate species that walks upright and has a large, complex brain with a capacity for the use of tools, language, symbolic expression, and culture. Fossilized bones revealed the physical appearance of early humans and how they changed over time. On the other hand, tools, pottery, jewelry, and other archaeological evidence show the activities of early humans.
Evidence shows that humans first emerged in Africa. Bipedalism in humans evolved over 4 million years ago, while other traits like the use of tools and symbolic expression emerged only tens of thousands of years ago.
Homo sapiens is the last living species of the zoological tribe Hominini. Fossils show that our species once existed alongside another species of Homo, the Neanderthals (Fig. 11). Fossils and genetics also show that we and other species of Homo are closely related to and share a common ancestor with other Great Apes, like chimpanzees and gorillas.
What are fossils?
Fossils are preserved remnants or traces of organisms from a past geologic age.
How do fossils provide evidence of evolution?
Fossils provide evidence that life forms have changed over time and resulted in the diversity in life forms that we see today. Fossils show how organisms evolved, how new groups of organisms emerged, and how some species became extinct.
What is homology?
Homology refers to similarities in the structure or development of different life forms.
What do homologous structures imply?
Different species with homologous structures can be traced back to common ancestors.
Vertebrates like pigs, birds, and whales have forelimbs with the same basic composition. What does this tell us about evolution?
Due to evolution, the forelimbs of vertebrates have changed over time to serve different purposes that suit their present environment.
Why do some distantly related species have similar physical characteristics?
Different species with similar structures but no recent common ancestors were likely subjected to common selection pressures.
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