3.3.2 Gas exchange: Adaptations in Plants

The primary function of stomata in dicotyledonous plants is gas exchange. They allow carbon dioxide to enter for photosynthesis and oxygen to exit, playing a crucial role in the plant's respiratory process.

The mesophyll is the leaf tissue where most photosynthesis occurs, containing chloroplasts that capture light energy. In contrast, stomata facilitate gas exchange, the epidermis provides protection, and the cuticle reduces water loss.

Terrestrial insects minimize water loss by closing their spiracles, which are openings for gas exchange. This action reduces water evaporation while still allowing for necessary oxygen intake.

Sunken stomata are an adaptation in xerophytic plants that help reduce water loss by creating a microenvironment with higher humidity around the stomata, minimizing evaporation. This is more effective than large leaves or high stomatal density.

A large surface area in leaves enhances gas exchange by maximizing the area available for carbon dioxide uptake and oxygen release, making it a key structural adaptation. The other options do not directly facilitate gas exchange.

Terrestrial insects face the challenge of balancing gas exchange and water conservation. Open spiracles allow oxygen intake but increase water loss, while closed spiracles prevent dehydration but limit gas exchange. Thus, they must find a compromise.

Xerophytic plants typically have adaptations to conserve water, such as a thick cuticle, reduced leaf size, and CAM photosynthesis. High stomatal density is not a feature, as it would increase water loss.

Guard cells regulate the opening and closing of stomata, which are small pores on the leaf surface. This function is crucial for gas exchange and transpiration, making 'They open and close the stomata' the correct answer.

Both terrestrial insects and xerophytic plants have a thick cuticle to reduce water loss. This adaptation helps them survive in dry environments, making it a common feature between the two.

Mesophyll cells facilitate gas exchange in leaves by allowing the diffusion of carbon dioxide and oxygen through their intercellular spaces, which is essential for photosynthesis and respiration.