When Evolution Runs Backwards - IELTS Reading Answers & Explanations
From Cambridge IELTS 10 Academic Reading Test 4 · Part 3 · Questions 27–40
Reading Passage
When evolution runs backwards
Evolution isn’t supposed to run backwards – yet an increasing number of examples show that it does and that it can sometimes represent the future of a species.
The description of any animal as an ‘evolutionary throwback’ is controversial. For the better part of a century, most biologists have been reluctant to use those words, mindful of a principle of evolution that says ‘evolution cannot run backwards. But as more and more examples come to light and modern genetics enters the scene, that principle is having to be rewritten. Not only are evolutionary throwbacks possible, they sometimes play an important role in the forward march of evolution.
The technical term for an evolutionary throwback is an ‘atavism’, from the Latin atavus, meaning forefather. The word has ugly connotations thanks largely to Cesare Lombroso, a 19th-century Italian medic who argued that criminals were born not made and could be identified by certain physical features that were throwbacks to a primitive, sub-human state.
While Lombroso was measuring criminals, a Belgian palaeontologist called Louis Dollo was studying fossil records and coming to the opposite conclusion. In 1890 he proposed that evolution was irreversible: that ‘an organism is unable to return, even partially, to a previous stage already realised in the ranks of its ancestors. Early 20th-century biologists came to a similar conclusion, though they qualified it in terms of probability, stating that there is no reason why evolution cannot run backwards -it is just very unlikely. And so the idea of irreversibility in evolution stuck and came to be known as ‘Dollo’s law.
If Dollo’s law is right, atavisms should occur only very rarely, if at all. Yet almost since the idea took root, exceptions have been cropping up. In 1919, for example, a humpback whale with a pair of leglike appendages over a metre long, complete with a full set of limb bones, was caught off Vancouver Island in Canada. Explorer Roy Chapman Andrews argued at the time that the whale must be a throwback to a land-living ancestor. ‘I can see no other explanation,’ he wrote in 1921.
Since then, so many other examples have been discovered that it no longer makes sense to say that evolution is as good as irreversible. And this poses a puzzle: how can characteristics that disappeared millions of years ago suddenly reappear?
In 1994, Rudolf Raff and colleagues at Indiana University in the USA decided to use genetics to put a number on the probability of evolution going into reverse. They reasoned that while some evolutionary changes involve the loss of genes and are therefore irreversible, others may be the result of genes being switched off. If these silent genes are somehow switched back on, they argued, long-lost traits could reappear.
Raff’s team went on to calculate the likelihood of it happening. Silent genes accumulate random mutations, they reasoned, eventually rendering them useless. So how long can a gene survive in a species if it is no longer used? The team calculated that there is a good chance of silent genes surviving for up to 6 million years in at least a few individuals in a population, and that some might survive as long as 10 million years. In other words, throwbacks are possible, but only to the relatively recent evolutionary past.
As a possible example, the team pointed to the mole salamanders of Mexico and California. Like most amphibians these begin life in a juvenile ‘tadpole’ state, then metamorphose into the adult form – except for one species, the axolotl, which famously lives its entire life as a juvenile. The simplest explanation for this is that the axolotl lineage alone lost the ability to metamorphose, while others retained it. From a detailed analysis of the salamanders’ family tree, however, it is clear that the other lineages evolved from an ancestor that itself had lost the ability to metamorphose. In other words, metamorphosis in mole salamanders is an atavism. The salamander example fits with Raff’s 10million-year time frame.
More recently, however, examples have been reported that break the time limit, suggesting that silent genes may not be the whole story. In a paper published last year, biologist Gunter Wagner of Yale University reported some work on the evolutionary history of a group of South American lizards called Bachia. Many of these have minuscule limbs; some look more like snakes than lizards and a few have completely lost the toes on their hind limbs. Other species, however, sport up to four toes on their hind legs. The simplest explanation is that the toed lineages never lost their toes, but Wagner begs to differ. According to his analysis of the Bachia family tree, the toed species re-evolved toes from toeless ancestors and, what is more, digit loss and gain has occurred on more than one occasion over tens of millions of years.
So what’s going on? One possibility is that these traits are lost and then simply reappear, in much the same way that similar structures can independently arise in unrelated species, such as the dorsal fins of sharks and killer whales. Another more intriguing possibility is that the genetic information needed to make toes somehow survived for tens or perhaps hundreds of millions of years in the lizards and was reactivated. These atavistic traits provided an advantage and spread through the population, effectively reversing evolution.
But if silent genes degrade within 6 to million years, how can long-lost traits be reactivated over longer timescales? The answer may lie in the womb. Early embryos of many species develop ancestral features. Snake embryos, for example, sprout hind limb buds. Later in development these features disappear thanks to developmental programs that say ‘lose the leg’. If for any reason this does not happen, the ancestral feature may not disappear, leading to an atavism.
Questions
Questions 27–31 Multiple Choice (One Answer)
Choose the correct letter, A, B, C or D.
Write the correct letter in boxes on your answer sheet.
Questions 32–36 Matching Sentence Endings
Complete each sentence with the correct ending, A-G, below.
Write the correct letter, A-G, in boxes on your answer sheet.
A the question of how certain long-lost traits could reappear.
B the occurrence of a particular feature in different species.
C parallels drawn between behaviour and appearance.
D the continued existence of certain genetic information.
E the doubts felt about evolutionary throwbacks.
F the possibility of evolution being reversible.
G Dollo’s findings and the convictions held by Lombroso.
Questions 37–40 Yes / No / Not Given
Do the following statements agree with the claims of the writer in the Reading Passage?
In boxes on your answer sheet, write
YES if the statement agrees with the claims of the writer
NO if the statement contradicts the claims of the writer
NOT GIVEN if it is impossible to say what the writer thinks about this
Answers & Explanations Summary
| # | Answer | Evidence | Explanation |
|---|---|---|---|
| Q27 | C | Early 20th-century biologists came to a similar conclusion, though they qualified it in terms of probability, stating that there is no reason why evolution cannot run backwards -it is just very unlikely. | Excerpt/Passage Explanation: The passage talks about how biologists in the early 20th century concluded that evolution could potentially go backward, though it is not likely to happen. Answer Explanation: The answer choice 'C' suggests that Dollo's theory was modified by biologists in the early twentieth century. Reason For Correctness: The correct answer reflects the information in the excerpt as it mentions that biologists in the early 20th century qualified Dollo's theory in terms of probability, indicating that it was modified as stated in answer choice C. |
| Q28 | D | Explorer Roy Chapman Andrews argued at the time that the whale must be a throwback to a land-living ancestor. | Excerpt/Passage Explanation: The passage talks about a person, Roy Chapman Andrews, saying that the whale must be similar to its ancestor that lived on land. Answer Explanation: The answer refers to the reason given for the unusual features of the humpback whale caught off Vancouver Island. Reason For Correctness: The correct answer is 'D' because the passage mentions Roy Chapman Andrews suggesting that the whale's unusual features are due to it being a throwback to a land-living ancestor. This directly aligns with the 'reason given for its unusual features' as stated in option D. |
| Q29 | C | If these silent genes are somehow switched back on, they argued, long-lost traits could reappear. | Excerpt/Passage Explanation: The passage talks about how if genes that are currently inactive (silent) get turned back on, old characteristics that were not seen for a long time could appear again. Answer Explanation: The answer states that silent genes could lead to the re-emergence of certain characteristics. Reason For Correctness: The correct answer is 'C' because it directly matches the idea presented in the excerpt. It is mentioned in the passage that if these silent genes are activated, old traits could come back. This aligns with the concept that silent genes could lead to the re-emergence of certain characteristics. |
| Q30 | B | As a possible example, the team pointed to the mole salamanders of Mexico and California. | Excerpt/Passage Explanation: The passage mentions a type of salamander called mole salamanders from Mexico and California. Answer Explanation: The answer suggests that Raff's theory is correct based on the mole salamander mentioned in the passage. Reason For Correctness: The correct answer is not 'B,' as this answer choice doesn't align with the information provided in the excerpt. The correct answer is 'A' because the passage does not explicitly state that the mole salamander exemplifies Raff's theory or that Raff's theory is correct based on the salamander mentioned. Instead, the mention of the mole salamanders serves as a possible example related to the development of most amphibians, which is in line with answer choice 'A.' |
| Q31 | A | According to his analysis of the Bachia family tree, the toed species re-evolved toes from toeless ancestors and, what is more, digit loss and gain has occurred on more than one occasion over tens of millions of years. | Excerpt/Passage Explanation: The passage discusses how certain species of Bachia lizards have evolved to have toes even though their ancestors did not. It also mentions that these lizards have experienced losing and gaining digits multiple times over millions of years. Answer Explanation: The answer suggests that Wagner claims members of the Bachia lizard family have lost and regained certain features multiple times. Reason For Correctness: The correct answer is supported by the excerpt where it is mentioned that the Bachia lizards re-evolved toes from toeless ancestors and experienced digit loss and gain on more than one occasion over a long period of time, confirming Wagner's claim as stated in answer choice A. |
| Q32 | F | For the better part of a century, most biologists have been reluctant to use those words, mindful of a principle of evolution that says ‘evolution cannot run backwards. | Excerpt/Passage Explanation: The passage explains that for a long time, most biologists did not agree with the idea that evolution can reverse back or 'run backwards.' They were hesitant to accept this concept. Answer Explanation: The answer indicates the idea that some biologists questioned or rejected the concept of evolution being reversible. Reason For Correctness: The correct answer is 'F' because it aligns with the reluctance described in the passage where biologists were hesitant to believe in evolution being reversible or running backwards. This matches the doubts mentioned in the excerpt about evolution reversing, making answer choice F the most suitable. |
| Q33 | G | While Lombroso was measuring criminals, a Belgian palaeontologist called Louis Dollo was studying fossil records and coming to the opposite conclusion. | Excerpt/Passage Explanation: The passage talks about a comparison between Lombroso, who was studying criminals, and Dollo, who was analyzing fossil records. Answer Explanation: The answer refers to the connection between Dollo's findings related to fossils and Lombroso's beliefs. Reason For Correctness: The correct answer 'G' aligns with the content of the passage because it highlights the juxtaposition between Dollo's research in paleontology and Lombroso's beliefs regarding criminals, showcasing opposing viewpoints on the topic of evolutionary throwbacks. |
| Q34 | A | Since then, so many other examples have been discovered that it no longer makes sense to say that evolution is as good as irreversible. And this poses a puzzle: how can characteristics that disappeared millions of years ago suddenly reappear? | Excerpt/Passage Explanation: The passage talks about how characteristics that had disappeared long ago are now reappearing, creating a puzzle for scientists to understand. Answer Explanation: The answer suggests that these examples have led to a question about how certain long-lost traits could reappear. Reason For Correctness: The correct answer 'A' aligns with the idea that the discovery of evolutionary throwbacks has raised questions about how traits that vanished long ago could return, as mentioned in the excerpt where it questions the reemergence of characteristics after millions of years. |
| Q35 | B | in much the same way that similar structures can independently arise in unrelated species, such as the dorsal fins of sharks and killer whales. | Excerpt/Passage Explanation: The passage mentions that similar structures, like the dorsal fins of sharks and killer whales, can appear in different species even if they are not closely related. Answer Explanation: The answer choice 'B' refers to the occurrence of a particular feature in different species, which is exemplified by the example of the dorsal fins in sharks and killer whales. Reason For Correctness: The correct answer is 'B' because the passage specifically discusses how similar features can independently appear in unrelated species, highlighting the occurrence of a particular feature in different species, such as the dorsal fins seen in both sharks and killer whales. |
| Q36 | D | Another more intriguing possibility is that the genetic information needed to make toes somehow survived for tens or perhaps hundreds of millions of years in the lizards and was reactivated. | Excerpt/Passage Explanation: The passage talks about the survival of genetic information over a long period and how it got activated in lizards. Answer Explanation: The answer suggests that one explanation for Wagner's research findings involves the continued existence of certain genetic information. Reason For Correctness: The correct answer 'D' fits with the passage's mention of genetic information surviving over time and being reactivated in the lizards, aligning with the concept of continued existence of certain genetic information. |
| Q37 | NOT GIVEN | In a paper published last year, biologist Gunter Wagner of Yale University reported some work on the evolutionary history of a group of South American lizards called Bachia. | Excerpt/Passage Explanation: The passage talks about biologist Gunter Wagner from Yale University conducting research on a group of South American lizards called Bachia. Answer Explanation: The answer means it's not clear from the passage whether Wagner was the first person to research South American lizards. Reason For Correctness: The correct answer is 'NOT GIVEN' because the passage only mentions Gunter Wagner's research on South American lizards but does not state that he was the first person to do such research. Therefore, it is impossible to determine if Wagner was the first person to study South American lizards based on the provided information. |
| Q38 | YES | According to his analysis of the Bachia family tree, the toed species re-evolved toes from toeless ancestors | Excerpt/Passage Explanation: The passage says that, based on the family tree of Bachia lizards, species that have toes evolved toes again from ancestors that did not have toes. Answer Explanation: The answer indicates that Wagner does believe that Bachia lizards with toes had ancestors without toes. Reason For Correctness: The correct answer is 'YES' because the passage explicitly states that the toed Bachia lizards re-evolved toes from ancestors that were toeless. Therefore, the statement aligns with Wagner's belief as presented in the passage. |
| Q39 | NO | Early embryos of many species develop ancestral features. | Excerpt/Passage Explanation: The passage tells us that in the early stages of development, embryos of many species show features that are similar to those of their ancestors. Answer Explanation: The answer suggests that the temporary occurrence of long-lost traits in embryos is not rare. Reason For Correctness: The correct answer is NO because the statement implies that the occurrence of long-lost traits in embryos is not rare, which aligns with the idea that early embryos of many species display ancestral characteristics according to the excerpt. |
| Q40 | YES | If for any reason this does not happen, the ancestral feature may not disappear, leading to an atavism. | Excerpt/Passage Explanation: The passage explains that if a particular feature from ancestors doesn't disappear during development in the womb, it can result in an atavism, which is an evolutionary throwback. Answer Explanation: The answer means that yes, developmental problems in the womb can cause evolutionary throwbacks, as indicated in the passage. Reason For Correctness: The correct answer is 'YES' because the passage clearly states that if a developmental process doesn't happen as expected in the womb, ancestral features may persist, leading to atavisms, which are evolutionary throwbacks. |