Fatal Attraction - IELTS Reading Answers & Explanations
From Official Cambridge Guide to IELTS Academic Reading Test 7 · Part 2 · Questions 14–26
Reading Passage
You should spend about 20 minutes on Questions 14–26, which are based on Reading Passage 2 below.
Fatal Attraction
Evolutionist Charles Darwin first marvelled at flesh-eating plants in the mid-19th century. Today, biologists, using 21st-century tools to study cells and DNA, are beginning to understand how these plants hunt, eat and digest – and how such bizarre adaptations arose in the first place.
A The leaves of the Venus flytrap plant are covered in hairs. When an insect brushes against them, this triggers a tiny electric charge, which travels down tunnels in the leaf and opens up pores in the leaf's cell membranes. Water surges from the cells on the inside of the leaf to those on the outside, causing the leaf to rapidly flip in shape from convex to concave, like a soft contact lens. As the leaves flip, they snap together, trapping the insect in their sharp-toothed jaws.
B The bladderwort has an equally sophisticated way of setting its underwater trap. It pumps water out of tiny bag-like bladders, making a vacuum inside. When small creatures swim past, they bend the hairs on the bladder, causing a flap to open. The low pressure sucks water in, carrying the animal along with it. In one five-hundredth of a second, the door swings shut again. The Drosera sundew, meanwhile, has a thick, sweet liquid oozing from its leaves, which first attracts insects, then holds them fast before the leaves snap shut. Pitcher plants use yet another strategy, growing long tube-shaped leaves to imprison their prey. Raffles' pitcher plant, from the jungles of Borneo, produces nectar that both lures insects and forms a slick surface on which they can't get a grip. Insects that land on the rim of the pitcher slide on the liquid and tumble in.
C Many carnivorous plants secrete enzymes to penetrate the hard exoskeleton of insects so they can absorb nutrients from inside their prey. But the purple pitcher plant, which lives in bogs and infertile sandy soils in North America, enlists other organisms to process its food. It is home to an intricate food web of mosquito larvae, midges and bacteria, many of which can survive only in this unique habitat. These animals shred the prey that fall into the pitcher, and the smaller organisms feed on the debris. Finally, the plant absorbs the nutrients released.
D While such plants clearly thrive on being carnivorous, the benefits of eating flesh are not the ones you might expect. Carnivorous animals such as ourselves use the carbon in protein and the fat in meat to build muscles and store energy. Carnivorous plants instead draw nitrogen, phosphorus, and other critical nutrients from their prey in order to build light-harvesting enzymes. Eating animals, in other words, lets carnivorous plants do what all plants do: carry out photosynthesis, that is, grow by harnessing energy directly from the sun.
E Carnivorous plants are, in fact, very inefficient at converting sunlight into tissue. This is because of all the energy they expend to make the equipment to catch animals - the enzymes, the pumps, and so on. A pitcher or a flytrap cannot carry out much photosynthesis because, unlike plants with ordinary leaves, they do not have flat solar panels that can grab lots of sunlight. There are, however, some special conditions in which the benefits of being carnivorous do outweigh the costs. The poor soil of bogs, for example, offers little nitrogen and phosphorus, so carnivorous plants enjoy an advantage over plants that obtain these nutrients by more conventional means. Bogs are also flooded with sunshine, so even an inefficient carnivorous plant can photosynthesise enough light to survive.
F Evolution has repeatedly made this trade-off. By comparing the DNA of carnivorous plants with other species, scientists have found that they evolved independently on at least six separate occasions. Some carnivorous plants that look nearly identical turn out to be only distantly related. The two kinds of pitcher plants – the tropical genus Nepenthes and the North American Sarracenia – have, surprisingly, evolved from different ancestors, although both grow deep pitcher-shaped leaves and employ the same strategy for capturing prey.
G In several cases, scientists can see how complex carnivorous plants evolved from simpler ones. Venus flytraps, for example, share an ancestor with Portuguese sundews, which only catch prey passively, via ‘flypaper' glands on their stems. They share a more recent ancestor with Drosera sundews, which can also curl their leaves over their prey. Venus flytraps appear to have evolved an even more elaborate version of this kind of trap, complete with jaw-like leaves.
H Unfortunately, the adaptations that enable carnivorous plants to thrive in marginal habitats also make them exquisitely sensitive. Agricultural run-off and pollution from power plants are adding extra nitrogen to many bogs in North America. Carnivorous plants are so finely tuned to low levels of nitrogen that this extra fertilizer is overloading their systems, and they eventually burn themselves out and die.
I Humans also threaten carnivorous plants in other ways. The black market trade in exotic carnivorous plants is so vigorous now that botanists are keeping the location of some rare species a secret. But even if the poaching of carnivorous plants can be halted, they will continue to suffer from other assaults. In the pine savannah of North Carolina, the increasing suppression of fires is allowing other plants to grow too quickly and outcompete the flytraps in their native environment. Good news, perhaps, for flies. But a loss for all who, like Darwin, delight in the sheer inventiveness of evolution.
Questions
Questions 14–18 Note Completion
Complete the notes below.
Choose NO MORE THAN TWO WORDS from the passage for each answer.
How a Venus flytrap traps an insect
- insect touches 14 on leaf of plant
- small 15 passes through leaf
- 16 in cell membrane open
- outside cells of leaves fill with 17
- leaves change so that they have a 18 shape and snap shut
Questions 19–22 Matching Features
Look at the following statements and the list of plants.
Match each statement with the correct plant, A, B, C, D or E.
A. Venus flytrap
B. bladderwort
C. Drosera sundew
D. Raffles' pitcher plant
E. purple pitcher plant
Questions 23–26 Matching Information
Reading Passage 2 has nine paragraphs, A–I.
Which paragraph contains the following information?
Answers & Explanations Summary
| # | Answer | Evidence | Explanation |
|---|---|---|---|
| Q14 | the hairs / hairs | The leaves of the Venus flytrap plant are covered in hairs. When an insect brushes against them, this triggers a tiny electric charge | Excerpt/Passage Explanation: The passage says that Venus flytrap leaves have hairs. If an insect touches (brushes against) these hairs, it starts an electric charge that makes the trap close. Answer Explanation: The answer refers to the thin, thread-like parts on the surface of the plant's leaves. Reason For Correctness: The correct answer is '(the) hairs' because the passage describes how a Venus flytrap begins to capture an insect. It states that the leaves are covered in hairs and that the process starts when an insect 'brushes against them'. In this context, 'brushes against' means the same thing as 'touches'. |
| Q15 | electric charge / charge | When an insect brushes against them, this triggers a tiny electric charge, which travels down tunnels in the leaf and opens up pores in the leaf's cell membranes | Excerpt/Passage Explanation: The passage says that when an insect touches the plant's hairs, it starts a very small piece of electricity that moves through the leaf and lets it open up. Answer Explanation: The answer is the bit of electricity that moves inside the plant after an insect touches it. Reason For Correctness: The correct answer is "(electric) charge" because Paragraph A describes the specific steps of how a Venus flytrap captures prey. It states that when an insect brushes the hairs, it triggers a "tiny electric charge". This charge then "travels down tunnels in the leaf". In the provided notes, the word "small" is a synonym for "tiny", and the phrase "passes through" matches the description of the charge traveling through the tunnels within the leaf. |
| Q16 | pores | When an insect brushes against them, this triggers a tiny electric charge, which travels down tunnels in the leaf and opens up pores in the leaf's cell membranes | Excerpt/Passage Explanation: The passage explains that when an insect touches the plant’s hairs, a small electric signal moves through the leaf and causes small holes, known as pores, in the cells to open. Answer Explanation: The answer is the plural noun for tiny holes or openings in a surface. Reason For Correctness: The correct answer is identified in Paragraph A, which describes the step-by-step physical process of how a Venus flytrap works. After an insect touches the plant and an electric charge moves through the leaf, it causes specific openings, called 'pores', in the cell membranes to unlock. This is a key step that allows water to move and the trap to close. Key phrases to look for include 'opens up' and 'cell membranes'. |
| Q17 | water | Water surges from the cells on the inside of the leaf to those on the outside, causing the leaf to rapidly flip in shape from convex to concave, like a soft contact lens | Excerpt/Passage Explanation: The passage explains that liquid moves quickly from the inner part of the leaf to the outer part. This movement makes the leaf change its shape and close around the bug. Answer Explanation: The answer is the liquid that goes into the outer part of the plant's leaf. Reason For Correctness: The correct answer is 'water' because the text explains the physical process of how the Venus flytrap closes its trap. When the plant is triggered, liquid moves from the inner cells to the outer cells. This movement of 'water' is what causes the leaf to change its shape quickly and shut tight on the insect. The word 'surges' suggests a fast movement into the 'outside' cells. |
| Q18 | concave | Water surges from the cells on the inside of the leaf to those on the outside, causing the leaf to rapidly flip in shape from convex to concave, like a soft contact lens | Excerpt/Passage Explanation: The passage describes how water moving inside the leaf makes it suddenly change its shape from curving out to curving in (concave), which is how it traps insects. Answer Explanation: The answer means that the surface of the leaf curves inward, like the inside of a bowl. Reason For Correctness: The correct answer is 'concave' because paragraph A explains how the Venus flytrap changes its physical form to catch prey. The text says the leaves 'flip in shape' from being curved outward (convex) to being curved inward (concave). This movement happens very quickly and allows the two sides of the leaf to come together or 'snap shut' around an insect. |
| Q19 | E | But the purple pitcher plant, which lives in bogs and infertile sandy soils in North America, enlists other organisms to process its food | Excerpt/Passage Explanation: The passage explains that this specific plant gets help from other small living things to prepare its food so it can be used by the plant. Answer Explanation: The answer E means the purple pitcher plant is the plant that uses other living things to help it break down the insects it catches. Reason For Correctness: The correct answer is E because the text explains that the purple pitcher plant does not break down its food alone. Instead, it creates a home for tiny animals and bacteria like mosquito larvae and midges. These other living things shred and eat the insects that fall into the plant, which releases the nutrients the plant needs to grow. The word 'enlists' means to get help from others, and 'organisms' refers to the other creatures that live inside it. |
| Q20 | D | Raffles' pitcher plant, from the jungles of Borneo, produces nectar that both lures insects and forms a slick surface on which they can't get a grip. Insects that land on the rim of the pitcher slide on the liquid and tumble in | Excerpt/Passage Explanation: The passage explains that this specific plant makes a sweet juice (nectar) that is also very smooth and slippery. Because it is so slippery, bugs cannot stand on it and they fall right into the plant's trap. Answer Explanation: The answer is D, which refers to the Raffles' pitcher plant. Reason For Correctness: The correct answer is Raffles' pitcher plant because the text describes how it creates a liquid that is very slippery (a slick surface). This makes it impossible for insects to hold on, so they slide and fall into the plant. The word 'slick' is a synonym for 'slippery', and 'tumble in' means to 'fall inside'. |
| Q21 | B | It pumps water out of tiny bag-like bladders, making a vacuum inside. When small creatures swim past, they bend the hairs on the bladder, causing a flap to open. The low pressure sucks water in, carrying the animal along with it | Excerpt/Passage Explanation: The passage explains that the bladderwort pulls water out of its small bags to make an empty space inside. When an animal touches it, a door opens, and the pressure difference pulls (sucks) the animal and water into the bag. Answer Explanation: The answer B refers to the bladderwort, an underwater plant that captures prey by pulling them into a container. Reason For Correctness: The correct answer is B because the passage describes the bladderwort as a plant that creates a 'vacuum' (which means an empty space) by pumping water out if its bladders. This vacuum creates 'low pressure,' which acts like a suction force. When a small animal or insect triggers the trap, it is 'sucked' inside along with the water very quickly. |
| Q22 | C | The Drosera sundew, meanwhile, has a thick, sweet liquid oozing from its leaves, which first attracts insects, then holds them fast before the leaves snap shut | Excerpt/Passage Explanation: The passage explains that the Drosera sundew has a thick, sugary liquid on its leaves. This liquid brings insects close and then sticks to them so they are caught. Answer Explanation: The answer is the Drosera sundew, labeled as C in the list. Reason For Correctness: The correct answer is C because the passage describes the Drosera sundew as having a 'thick, sweet liquid' coming out of its leaves. This liquid acts as a sticky substance that 'holds fast' or traps insects on the leaf's surface so they cannot fly away before the plant closes. Other plants mentioned use different methods, like the Venus flytrap's snapping jaws or the Raffles' pitcher plant's slippery (slick) surface. |
| Q23 | E | A pitcher or a flytrap cannot carry out much photosynthesis because, unlike plants with ordinary leaves, they do not have flat solar panels that can grab lots of sunlight | Excerpt/Passage Explanation: The passage says that because these plants have traps instead of flat leaves, they cannot catch enough light to make food as well as normal plants do. Answer Explanation: The answer is Paragraph E. Reason For Correctness: The correct answer is Paragraph E because it explains how the specific shapes of carnivorous plants—like the pitcher or the flytrap—are less effective at capturing sunlight compared to regular flat leaves. This is a disadvantage because it makes them 'inefficient' at photosynthesis, meaning they cannot easily turn sunlight into growth. Key terms such as 'cannot carry out much photosynthesis' and 'do not have flat solar panels' highlight the problem caused by their unique leaf shapes. |
| Q24 | I | The black market trade in exotic carnivorous plants is so vigorous now that botanists are keeping the location of some rare species a secret | Excerpt/Passage Explanation: The passage explains that scientists who study plants are keeping the places where rare plants live a secret so that people who sell plants illegally cannot find and take them. Answer Explanation: The answer identifies paragraph I as the section that talks about a specific action taken to keep meat-eating plants safe from people who want to steal them. Reason For Correctness: The correct answer is I because it describes a way people are trying to protect these plants. Specifically, it mentions that scientists (botanists) are hiding the information about exactly where rare plants live. This effort is made to stop people from taking the plants to sell them illegally on the 'black market.' |
| Q25 | F | The two kinds of pitcher plants – the tropical genus Nepenthes and the North American Sarracenia – have, surprisingly, evolved from different ancestors, although both grow deep pitcher-shaped leaves and employ the same strategy for capturing prey | Excerpt/Passage Explanation: The passage explains that even though these two plants look like they should be the same because they have similar leaf shapes and ways of catching food, they actually started from different ancient plants. This was a surprise to researchers. Answer Explanation: The answer is paragraph F, which explains that some plants that seem to be the same actually have different beginnings. Reason For Correctness: The correct answer is paragraph F because it shares a surprising fact about the history of certain plants. While we might think plants that look the same come from the same family, the text uses the word 'surprisingly' to describe how two types of pitcher plants come from different 'ancestors' (the plants they started from a long time ago). This is the 'unexpected information' about their 'origins' mentioned in the question. |
| Q26 | H | Agricultural run-off and pollution from power plants are adding extra nitrogen to many bogs in North America. Carnivorous plants are so finely tuned to low levels of nitrogen that this extra fertilizer is overloading their systems, and they eventually burn themselves out and die | Excerpt/Passage Explanation: The passage explains that pollution and farm waste change the chemistry of the areas where these plants live. Because the plants are very sensitive, this change is too much for them to handle, and it causes them to die. Answer Explanation: The answer is Paragraph H because it describes how specific changes in the environment cause meat-eating plants to die early. Reason For Correctness: The correct answer is Paragraph H because it mentions environmental changes like agricultural run-off and pollution from power plants. These changes add too much nitrogen to the soil. The text explains that this extra nitrogen acts like too much fertilizer, which is bad for the plants. As a result, they 'burn themselves out and die,' which means their life cycles are shortened. Pay attention to keywords like 'pollution' (an environmental change) and 'die' (the end of a life cycle). |