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Leaves Function and structure The principal function of leaves is to absorb sunlight needed to manufacture plant sugars through a process called photosynthesis. Leaf surfaces are flattened to present a large area for efficient light absorption. The blade is the expanded thin structure on either buds. They may be either active or dormant. Under the right conditions, they will develop into stems or leaves. A leaf blade is composed of several layers. On the top and bottom is a layer of thick, tough cells called the epidermis. Its primary function is to protect the other layers of leaf tissue. The arrangement of epidermal cells determines the leaf’s surface texture. Some leaves, such as those of African violets, have hairs (pubescence), which are extensions of epidermal cells that make the leaves feel like velvet. The cuticle is part of the epidermis. It produces a waxy layer called cutin, which protects the leaf from dehydration and disease. The amount of cutin on a leaf increases with increasing light intensity. For this reason, when moving plants from shade into full sunlight, do so gradually over a period of a few weeks. This gradual exposure to sunlight is referred to as hardening off. It allows the cutin layer to build up and protect the leaves from rapid water loss or sunscald. Transplants produced indoors should be hardened off before planting outdoors. The waxy cutin also repels water. For this reason, many pesticides contain a spray additive (sticker, spreader, etc.) to help the product adhere to, or penetrate, the cutin layer. Special epidermal cells called guard cells open and close in response to environmental stimuli such as changes in weather and light. They regulate the passage of water, oxygen and carbon dioxide into and out of the leaf through tiny openings called stomata. In most species, the majority of the stomata are located on the undersides of leaves. Conditions that would cause plants to lose a lot of water (high temperature, low humidity) stimulate guard cells to close. In mild weather, they remain open. Guard cells also close in the absence of light. Located between the upper and lower epidermis is the mesophyll. It is divided into a dense upper layer (palisade mesophyll) and a lower layer that contains lots of air space (spongy mesophyll). Located within the mesophyll cells are chloroplasts, where photosynthesis takes place. Leaf parts There are many terms to describe parts of a leaf, but these are enough to get started with plant identification. Blade (lamina): The flat or expanded part of a leaf. The blade is the entire leaf unit. Sometimes this is made up of several smaller leaflets (in case of compound leaf). Leaflet: An individual blade of a compound leaf. Margin: The edge of the leaf is known as the leaf margin. Looking at the margin of the leaf can be an important in identifying the leaf. Leaf margins may be described as entire, toothed, or lobed. Vein (Midrib): The central or main vein of a leaf Leaf Apex: The Apex is the tip of the leaf. Leaf Base: Base is the name given to the part of the blade that is closest to the stem. Nodes: Point of attachment to the stem. Axilary bud: Lateral bud located at the base of a leaf petiole. Petiole: The Petiole is the thin stalk that connects the leaf blade to the stem. Stipule: Stipules are tiny leaf-like structures that may or may not be present at the base of the petiole. Venation The vascular bundles of xylem and phloem extend from the stem, through the petiole and into the leaf blade as veins. The term venation refers to how veins are distributed in the blade. There are two principal types of venation: parallel-veined and net-veined or reticulate. In parallel-veined leaves, numerous veins run parallel to each other and are connected laterally by minute, straight veinlets. Parallel-veined leaves occur most often on monocotyledonous plants. The most common type of parallel veining is found in plants of the grass family, whose veins run from the leaf’s base to its apex. Another type of parallel venation is found in plants such as banana, calla and pickerelweed. In net-veined leaves (also called reticulate-veined), veins branch from the main rib or ribs and subdivide into finer veinlets. These veinlets then unite in a complicated network. This system of enmeshed veins makes the leaf more resistant to tearing than does a parallel vein structure. Net-veined leaves occur on dicotyledonous plants. Net venation may be either pinnate or palmate. In pinnate venation, the veins extend laterally from the midrib to the edge (e.g., apples, cherries and peaches). In palmate venation, the principal veins extend outward, like the ribs of a fan, from the base of the leaf blade (e.g., grapes and maples). There are two types of leaves: simple and compound. In simple leaves, the leaf blade is a single, continuous unit. Compound leaves are composed of several separate leaflets arising from the same petiole. Some leaves are doubly compound. Leaf type can be confusing because a deeply lobed simple leaf may look like a compound leaf. There are four types of leaf arrangement: Opposite leaves are positioned across the stem from each other, with two leaves at each node. Alternate (spiral) leaves are arranged in alternate steps along the stem, with only one leaf at each node. Whorled leaves are arranged in circles along the stem.