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Crassulacean Acid Metabolism (CAM) is a carbon fixation pathway in some photosynthetic plants. CAM is usually found in plants living under arid conditions, including those found in the desert (for example, cacti or pineapple). It is named after the plant family it was first discovered in, the Crassulaceae.

[edit] Synopsis

Plants that are adapted to dry climates are called xerophytes. Some of these plants have small, thick leaves with a reduced surface area. They may also have a thickened cuticle to protect themselves from the environment. The stomata may be sunken into pits. Some xerophytes shed their leaves during the driest seasons and others can store water such as cacti, orchids and bromeliads. CAM plants take up CO2 at night and store it in the vacuoles, as malic acid that can be broken down during the day for sugars.

These plants close their stomata (tiny pores used for gas exchange) during the day in order to conserve water. Normally, they wouldn't be able to carry out photosynthesis during day because during day stomata of the CAM plants is closed to reduce transpiration and hence reduce water loss, since carbon dioxide from the air wouldn't be available. Therefore, their stomata are open during the night, and it is then that they take in carbon dioxide. They store it as malate and other, simple organic compounds. Malate in particular is easily broken down into pyruvate and CO₂, the former being phosphorylated into phosphoenolpyruvate (PEP) and then be recycled to fix more carbon. In the daytime, the malic acid is removed from the vacuoles and cleaved to produce CO₂ so that it can be re-fixed by RuBisCO and made into sugars.

Crassulacean acid metabolism allows plants to close their stomata (tiny pores used for gas exchange) during the day in order to conserve water and carry out photosynthesis with CO₂ that is taken up during the cool, humid night. CAM metabolism allows plants to grow in environments that would otherwise be far too dry for plant growth or subject to severe droughts. When an environment is too dry for even CAM plants to grow, they can stay alive by re-fixing the same carbon over and over without ever opening their stomata.

In some ways, CAM resembles C₄ metabolism, except that CAM plants contain no bundle sheaths around their veins, and C₄ metabolism is continuous (as long as there is light), while CAM occurs only at night. C₄ metabolism physically separates CO₂ fixation from the Calvin cycle, while CAM metabolism temporally separates CO₂ fixation from the Calvin cycle.

CAM plants are very good at retaining water, and are very efficient with nitrogen. The drawback is that they are slow growing.da:CAM-plante de:CAM-Pflanze es:Metabolismo ácido de las Crassulaceae fr:Métabolisme acide crassulacéen ko:CAM 식물 he:צמחי CAM ja:CAM型光合成 pl:Fotosynteza CAM zh:景天酸代謝植物