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Why don’t carnivorous plants just use photosynthesis? part 2

Plants have many ways of getting the nutrients they need, explain our readers

E7MK5Y Insectivorous plant Venus fly trap (Dionaea muscipula) digesting a captured mosquito. Plant house, Galveston, Texas, USA.

Why do Venus flytraps and pitcher plants trap and digest insects if they are fully capable of photosynthesis? If this is an adaptation to ensure there is always food, then why don’tÌýother plants do the same? (continued)

David Muir
Edinburgh, UK

Plants require 17 essential nutrients. Through photosynthesis, carbon and oxygen are derived from carbon dioxide in the air, and hydrogen comes from water. The other 14 elements: nitrogen, phosphorus, potassium, calcium, magnesium, sulphur, iron, zinc, copper, boron, nickel, molybdenum, manganese and chlorine, would normally come from the soil for land plants. Aquatic plants get their nutrients directly from the water they live in, or from the substrate in which they are fixed. For these land and aquatic plants, the benefits ofÌýevolving insect-trapping mechanisms isn’t worth the cost.

Evolution can bring about adaptations thatÌýare beneficial, butÌýonly if the advantages outweigh the disadvantages

Carnivorous plants generally grow in boggy places, often sunny, where they can photosynthesise. But such environments are nutrient-poor. To catch animal sources of essential elements, suchÌýplants have evolved adaptations: snap traps (Venus flytrap), bladder traps that useÌýaÌývacuum to suck in prey (bladderworts), flypaper traps thatÌýuse a glue (sundew), lobster-pot traps that use angled hairs toÌýdirect prey one-way to their demiseÌý(corkscrew plants) and pitfall traps that send prey downÌýinto a swimming poolÌýof digestive enzymes (pitcherÌýplants). For these plants, the benefits of evolving insect-trapping features isÌýwell worth theÌýcost.

Under Mother Nature’sÌý cost-benefit analysis of naturalÌýselection, evolution canÌýbring about adaptations thatÌýare beneficial, but only ifÌýtheÌýadvantages outweigh theÌýdisadvantages.

Ìý

Rob Leah
London, UK

Most carnivorous plants live inÌýacidic, boggy soils, which areÌýnotoriously poor in various nutrients – particularly nitrogen needed to make proteins. TheyÌýtherefore evolved to trap andÌýdigest insects, to provide theÌýnutrients that weren’t availableÌýfrom the soil.

A surprising number of plants are weakly carnivorous (such as tomatoes, which have stems covered in sticky hairs that can capture small insects and absorb the nutrients from their decomposition), but presumably, the evolutionary cost of being actively carnivorous only makes sense in very specific environments.

Ìý

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