8.5 Stomatal Conductance and Leaves

Leaves are the main sites for photosynthesis: the process by which plants synthesize food. Most leaves are usually green, due to the presence of chlorophyll in the leaf cells. The thickness, shape, and size of leaves are adapted to the environment. Each variation helps a plant species maximize its chances of survival in a particular habitat. For example, the leaves of plants growing in tropical rainforests usually have larger surface areas than those of plants growing in deserts or very cold conditions (which are likely to have a smaller surface area to minimize water loss).

The Stomata

The dermal tissue of the stem consists primarily of epidermis, a single layer of cells covering and protecting the underlying tissue. The epidermis, or dermal tissue, of a leaf contains openings known as stomata, through which the exchange of gases takes place (Figure 8.4.1). Two cells, known as guard cells, surround each leaf stoma, controlling its opening and closing and thus regulating the uptake of carbon dioxide and the release of oxygen and water vapor.

Stomatal Conductance

Regulation of transpiration is achieved primarily through the opening and closing of stomata on the leaf surface. Guard cells work to control stomatal conductance via opening and closing in response to environmental cues such as light intensity and quality, leaf water status, and carbon dioxide concentrations. Stomata must open to allow air containing carbon dioxide and oxygen to diffuse into the leaf for photosynthesis and respiration. When stomata are open, however, water vapor is lost to the external environment, increasing the rate of transpiration. Stomatal conductance is dependent on the density of stomata, the size of the stomatal opening, and the size of the stomata.

A Battle Between Needs

There is a constant tension between opening a plant’s stomata to take in carbon dioxide (CO₂) for photosynthesis and the risk of losing water through the same openings via transpiration. When stomata open, CO₂ diffuses into the leaf, enabling sugar production. This is essential for plant processes and growth. But, when this occurs, water vapor escapes into the atmosphere. To balance exchange, plants regulate stomatal opening based on environmental conditions. For example, plants might close their stomata to conserve water during drought, even if it limits photosynthesis.

Figure Descriptions

Figure 8.5.1. The image is divided into three parts, labeled (a), (b), and (c). (a) On the left is a colorized scanning electron micrograph of a closed stoma on a dicot leaf. The stoma appears as an oval-shaped indentation flanked by two kidney-shaped guard cells. The surface is textured and appears rough, with a glossy green coloration. The scale bar at the bottom right indicates 20 micrometers. (b) In the top right are two gray-scale images showing an open and a closed stoma. The left image features an open stoma, displaying the bean-shaped guard cells with a clear gap between them. The right image shows a closed stoma where the guard cells meet without any visible gap. Both images have a scale bar of 20 micrometers and include labeled arrows pointing to “Guard cells,” “Open stoma,” and “Closed stoma.” (c) The bottom right illustrates an anatomical diagram showing a cross-section of leaf tissue. It highlights the position of guard cells around the stomatal pore, embedded in the epidermal cells. The guard cells are drawn in a distinct green shade, while squares representing epidermal cells encompass them. Arrows label “Guard cells,” “Stomatal pore,” and “Epidermal cells.” [Return to Figure 8.5.1]

Licenses and Attributions

“8.5 Stomatal Conductance and Leaves” is adapted from “30.2 Stems” by Mary Ann Clark, Matthew Douglas, and Jung Choi for OpenStax Biology 2e under CC-BY 4.0. “8.5 Stomatal Conductance and Leaves” is licensed under CC-BY-NC 4.0.